src/HOL/Transcendental.thy
author wenzelm
Fri, 13 May 2011 23:58:40 +0200
changeset 42795 66fcc9882784
parent 41970 47d6e13d1710
child 43335 9f8766a8ebe0
permissions -rw-r--r--
clarified map_simpset versus Simplifier.map_simpset_global;
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(*  Title:      HOL/Transcendental.thy
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    Author:     Jacques D. Fleuriot, University of Cambridge, University of Edinburgh
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    Author:     Lawrence C Paulson
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*)
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header{*Power Series, Transcendental Functions etc.*}
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theory Transcendental
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imports Fact Series Deriv NthRoot
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begin
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subsection {* Properties of Power Series *}
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lemma lemma_realpow_diff:
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  fixes y :: "'a::monoid_mult"
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  shows "p \<le> n \<Longrightarrow> y ^ (Suc n - p) = (y ^ (n - p)) * y"
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proof -
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  assume "p \<le> n"
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  hence "Suc n - p = Suc (n - p)" by (rule Suc_diff_le)
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  thus ?thesis by (simp add: power_commutes)
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qed
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lemma lemma_realpow_diff_sumr:
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  fixes y :: "'a::{comm_semiring_0,monoid_mult}" shows
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     "(\<Sum>p=0..<Suc n. (x ^ p) * y ^ (Suc n - p)) =
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      y * (\<Sum>p=0..<Suc n. (x ^ p) * y ^ (n - p))"
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by (simp add: setsum_right_distrib lemma_realpow_diff mult_ac
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         del: setsum_op_ivl_Suc)
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lemma lemma_realpow_diff_sumr2:
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  fixes y :: "'a::{comm_ring,monoid_mult}" shows
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     "x ^ (Suc n) - y ^ (Suc n) =
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      (x - y) * (\<Sum>p=0..<Suc n. (x ^ p) * y ^ (n - p))"
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apply (induct n, simp)
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apply (simp del: setsum_op_ivl_Suc)
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apply (subst setsum_op_ivl_Suc)
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apply (subst lemma_realpow_diff_sumr)
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apply (simp add: right_distrib del: setsum_op_ivl_Suc)
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apply (subst mult_left_commute [of "x - y"])
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apply (erule subst)
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apply (simp add: algebra_simps)
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done
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lemma lemma_realpow_rev_sumr:
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     "(\<Sum>p=0..<Suc n. (x ^ p) * (y ^ (n - p))) =
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      (\<Sum>p=0..<Suc n. (x ^ (n - p)) * (y ^ p))"
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apply (rule setsum_reindex_cong [where f="\<lambda>i. n - i"])
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apply (rule inj_onI, simp)
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apply auto
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apply (rule_tac x="n - x" in image_eqI, simp, simp)
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done
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text{*Power series has a `circle` of convergence, i.e. if it sums for @{term
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x}, then it sums absolutely for @{term z} with @{term "\<bar>z\<bar> < \<bar>x\<bar>"}.*}
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lemma powser_insidea:
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  fixes x z :: "'a::{real_normed_field,banach}"
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  assumes 1: "summable (\<lambda>n. f n * x ^ n)"
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  assumes 2: "norm z < norm x"
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  shows "summable (\<lambda>n. norm (f n * z ^ n))"
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proof -
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  from 2 have x_neq_0: "x \<noteq> 0" by clarsimp
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  from 1 have "(\<lambda>n. f n * x ^ n) ----> 0"
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    by (rule summable_LIMSEQ_zero)
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  hence "convergent (\<lambda>n. f n * x ^ n)"
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    by (rule convergentI)
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  hence "Cauchy (\<lambda>n. f n * x ^ n)"
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    by (simp add: Cauchy_convergent_iff)
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  hence "Bseq (\<lambda>n. f n * x ^ n)"
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    by (rule Cauchy_Bseq)
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  then obtain K where 3: "0 < K" and 4: "\<forall>n. norm (f n * x ^ n) \<le> K"
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    by (simp add: Bseq_def, safe)
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  have "\<exists>N. \<forall>n\<ge>N. norm (norm (f n * z ^ n)) \<le>
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                   K * norm (z ^ n) * inverse (norm (x ^ n))"
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  proof (intro exI allI impI)
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    fix n::nat assume "0 \<le> n"
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    have "norm (norm (f n * z ^ n)) * norm (x ^ n) =
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          norm (f n * x ^ n) * norm (z ^ n)"
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      by (simp add: norm_mult abs_mult)
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    also have "\<dots> \<le> K * norm (z ^ n)"
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      by (simp only: mult_right_mono 4 norm_ge_zero)
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    also have "\<dots> = K * norm (z ^ n) * (inverse (norm (x ^ n)) * norm (x ^ n))"
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      by (simp add: x_neq_0)
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    also have "\<dots> = K * norm (z ^ n) * inverse (norm (x ^ n)) * norm (x ^ n)"
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      by (simp only: mult_assoc)
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    finally show "norm (norm (f n * z ^ n)) \<le>
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                  K * norm (z ^ n) * inverse (norm (x ^ n))"
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      by (simp add: mult_le_cancel_right x_neq_0)
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  qed
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  moreover have "summable (\<lambda>n. K * norm (z ^ n) * inverse (norm (x ^ n)))"
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  proof -
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    from 2 have "norm (norm (z * inverse x)) < 1"
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      using x_neq_0
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      by (simp add: nonzero_norm_divide divide_inverse [symmetric])
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    hence "summable (\<lambda>n. norm (z * inverse x) ^ n)"
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      by (rule summable_geometric)
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    hence "summable (\<lambda>n. K * norm (z * inverse x) ^ n)"
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      by (rule summable_mult)
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    thus "summable (\<lambda>n. K * norm (z ^ n) * inverse (norm (x ^ n)))"
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      using x_neq_0
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      by (simp add: norm_mult nonzero_norm_inverse power_mult_distrib
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                    power_inverse norm_power mult_assoc)
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  qed
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  ultimately show "summable (\<lambda>n. norm (f n * z ^ n))"
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    by (rule summable_comparison_test)
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qed
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lemma powser_inside:
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  fixes f :: "nat \<Rightarrow> 'a::{real_normed_field,banach}" shows
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     "[| summable (%n. f(n) * (x ^ n)); norm z < norm x |]
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      ==> summable (%n. f(n) * (z ^ n))"
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by (rule powser_insidea [THEN summable_norm_cancel])
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lemma sum_split_even_odd: fixes f :: "nat \<Rightarrow> real" shows
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  "(\<Sum> i = 0 ..< 2 * n. if even i then f i else g i) =
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   (\<Sum> i = 0 ..< n. f (2 * i)) + (\<Sum> i = 0 ..< n. g (2 * i + 1))"
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proof (induct n)
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  case (Suc n)
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  have "(\<Sum> i = 0 ..< 2 * Suc n. if even i then f i else g i) =
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        (\<Sum> i = 0 ..< n. f (2 * i)) + (\<Sum> i = 0 ..< n. g (2 * i + 1)) + (f (2 * n) + g (2 * n + 1))"
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    using Suc.hyps unfolding One_nat_def by auto
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  also have "\<dots> = (\<Sum> i = 0 ..< Suc n. f (2 * i)) + (\<Sum> i = 0 ..< Suc n. g (2 * i + 1))" by auto
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  finally show ?case .
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qed auto
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lemma sums_if': fixes g :: "nat \<Rightarrow> real" assumes "g sums x"
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  shows "(\<lambda> n. if even n then 0 else g ((n - 1) div 2)) sums x"
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  unfolding sums_def
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proof (rule LIMSEQ_I)
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  fix r :: real assume "0 < r"
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  from `g sums x`[unfolded sums_def, THEN LIMSEQ_D, OF this]
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  obtain no where no_eq: "\<And> n. n \<ge> no \<Longrightarrow> (norm (setsum g { 0..<n } - x) < r)" by blast
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hoelzl
parents: 29695
diff changeset
   133
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   134
  let ?SUM = "\<lambda> m. \<Sum> i = 0 ..< m. if even i then 0 else g ((i - 1) div 2)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   135
  { fix m assume "m \<ge> 2 * no" hence "m div 2 \<ge> no" by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   136
    have sum_eq: "?SUM (2 * (m div 2)) = setsum g { 0 ..< m div 2 }"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   137
      using sum_split_even_odd by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   138
    hence "(norm (?SUM (2 * (m div 2)) - x) < r)" using no_eq unfolding sum_eq using `m div 2 \<ge> no` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   139
    moreover
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   140
    have "?SUM (2 * (m div 2)) = ?SUM m"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   141
    proof (cases "even m")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   142
      case True show ?thesis unfolding even_nat_div_two_times_two[OF True, unfolded numeral_2_eq_2[symmetric]] ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   143
    next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   144
      case False hence "even (Suc m)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   145
      from even_nat_div_two_times_two[OF this, unfolded numeral_2_eq_2[symmetric]] odd_nat_plus_one_div_two[OF False, unfolded numeral_2_eq_2[symmetric]]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   146
      have eq: "Suc (2 * (m div 2)) = m" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   147
      hence "even (2 * (m div 2))" using `odd m` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   148
      have "?SUM m = ?SUM (Suc (2 * (m div 2)))" unfolding eq ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   149
      also have "\<dots> = ?SUM (2 * (m div 2))" using `even (2 * (m div 2))` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   150
      finally show ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   151
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   152
    ultimately have "(norm (?SUM m - x) < r)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   153
  }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   154
  thus "\<exists> no. \<forall> m \<ge> no. norm (?SUM m - x) < r" by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   155
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   156
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   157
lemma sums_if: fixes g :: "nat \<Rightarrow> real" assumes "g sums x" and "f sums y"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   158
  shows "(\<lambda> n. if even n then f (n div 2) else g ((n - 1) div 2)) sums (x + y)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   159
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   160
  let ?s = "\<lambda> n. if even n then 0 else f ((n - 1) div 2)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   161
  { fix B T E have "(if B then (0 :: real) else E) + (if B then T else 0) = (if B then T else E)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   162
      by (cases B) auto } note if_sum = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   163
  have g_sums: "(\<lambda> n. if even n then 0 else g ((n - 1) div 2)) sums x" using sums_if'[OF `g sums x`] .
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   164
  {
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   165
    have "?s 0 = 0" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   166
    have Suc_m1: "\<And> n. Suc n - 1 = n" by auto
41550
efa734d9b221 eliminated global prems;
wenzelm
parents: 38642
diff changeset
   167
    have if_eq: "\<And>B T E. (if \<not> B then T else E) = (if B then E else T)" by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   168
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   169
    have "?s sums y" using sums_if'[OF `f sums y`] .
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   170
    from this[unfolded sums_def, THEN LIMSEQ_Suc]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   171
    have "(\<lambda> n. if even n then f (n div 2) else 0) sums y"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   172
      unfolding sums_def setsum_shift_lb_Suc0_0_upt[where f="?s", OF `?s 0 = 0`, symmetric]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   173
                image_Suc_atLeastLessThan[symmetric] setsum_reindex[OF inj_Suc, unfolded comp_def]
31148
7ba7c1f8bc22 Cleaned up Parity a little
nipkow
parents: 31017
diff changeset
   174
                even_Suc Suc_m1 if_eq .
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   175
  } from sums_add[OF g_sums this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   176
  show ?thesis unfolding if_sum .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   177
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   178
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   179
subsection {* Alternating series test / Leibniz formula *}
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   180
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   181
lemma sums_alternating_upper_lower:
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   182
  fixes a :: "nat \<Rightarrow> real"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   183
  assumes mono: "\<And>n. a (Suc n) \<le> a n" and a_pos: "\<And>n. 0 \<le> a n" and "a ----> 0"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   184
  shows "\<exists>l. ((\<forall>n. (\<Sum>i=0..<2*n. -1^i*a i) \<le> l) \<and> (\<lambda> n. \<Sum>i=0..<2*n. -1^i*a i) ----> l) \<and>
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   185
             ((\<forall>n. l \<le> (\<Sum>i=0..<2*n + 1. -1^i*a i)) \<and> (\<lambda> n. \<Sum>i=0..<2*n + 1. -1^i*a i) ----> l)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   186
  (is "\<exists>l. ((\<forall>n. ?f n \<le> l) \<and> _) \<and> ((\<forall>n. l \<le> ?g n) \<and> _)")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   187
proof -
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
   188
  have fg_diff: "\<And>n. ?f n - ?g n = - a (2 * n)" unfolding One_nat_def by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   189
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   190
  have "\<forall> n. ?f n \<le> ?f (Suc n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   191
  proof fix n show "?f n \<le> ?f (Suc n)" using mono[of "2*n"] by auto qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   192
  moreover
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   193
  have "\<forall> n. ?g (Suc n) \<le> ?g n"
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
   194
  proof fix n show "?g (Suc n) \<le> ?g n" using mono[of "Suc (2*n)"]
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
   195
    unfolding One_nat_def by auto qed
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   196
  moreover
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   197
  have "\<forall> n. ?f n \<le> ?g n"
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
   198
  proof fix n show "?f n \<le> ?g n" using fg_diff a_pos
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
   199
    unfolding One_nat_def by auto qed
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   200
  moreover
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   201
  have "(\<lambda> n. ?f n - ?g n) ----> 0" unfolding fg_diff
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   202
  proof (rule LIMSEQ_I)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   203
    fix r :: real assume "0 < r"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   204
    with `a ----> 0`[THEN LIMSEQ_D]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   205
    obtain N where "\<And> n. n \<ge> N \<Longrightarrow> norm (a n - 0) < r" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   206
    hence "\<forall> n \<ge> N. norm (- a (2 * n) - 0) < r" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   207
    thus "\<exists> N. \<forall> n \<ge> N. norm (- a (2 * n) - 0) < r" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   208
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   209
  ultimately
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   210
  show ?thesis by (rule lemma_nest_unique)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   211
qed
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   212
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   213
lemma summable_Leibniz': fixes a :: "nat \<Rightarrow> real"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   214
  assumes a_zero: "a ----> 0" and a_pos: "\<And> n. 0 \<le> a n"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   215
  and a_monotone: "\<And> n. a (Suc n) \<le> a n"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   216
  shows summable: "summable (\<lambda> n. (-1)^n * a n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   217
  and "\<And>n. (\<Sum>i=0..<2*n. (-1)^i*a i) \<le> (\<Sum>i. (-1)^i*a i)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   218
  and "(\<lambda>n. \<Sum>i=0..<2*n. (-1)^i*a i) ----> (\<Sum>i. (-1)^i*a i)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   219
  and "\<And>n. (\<Sum>i. (-1)^i*a i) \<le> (\<Sum>i=0..<2*n+1. (-1)^i*a i)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   220
  and "(\<lambda>n. \<Sum>i=0..<2*n+1. (-1)^i*a i) ----> (\<Sum>i. (-1)^i*a i)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   221
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   222
  let "?S n" = "(-1)^n * a n"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   223
  let "?P n" = "\<Sum>i=0..<n. ?S i"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   224
  let "?f n" = "?P (2 * n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   225
  let "?g n" = "?P (2 * n + 1)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   226
  obtain l :: real where below_l: "\<forall> n. ?f n \<le> l" and "?f ----> l" and above_l: "\<forall> n. l \<le> ?g n" and "?g ----> l"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   227
    using sums_alternating_upper_lower[OF a_monotone a_pos a_zero] by blast
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   228
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   229
  let ?Sa = "\<lambda> m. \<Sum> n = 0..<m. ?S n"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   230
  have "?Sa ----> l"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   231
  proof (rule LIMSEQ_I)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   232
    fix r :: real assume "0 < r"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   233
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   234
    with `?f ----> l`[THEN LIMSEQ_D]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   235
    obtain f_no where f: "\<And> n. n \<ge> f_no \<Longrightarrow> norm (?f n - l) < r" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   236
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   237
    from `0 < r` `?g ----> l`[THEN LIMSEQ_D]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   238
    obtain g_no where g: "\<And> n. n \<ge> g_no \<Longrightarrow> norm (?g n - l) < r" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   239
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   240
    { fix n :: nat
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   241
      assume "n \<ge> (max (2 * f_no) (2 * g_no))" hence "n \<ge> 2 * f_no" and "n \<ge> 2 * g_no" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   242
      have "norm (?Sa n - l) < r"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   243
      proof (cases "even n")
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   244
        case True from even_nat_div_two_times_two[OF this]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   245
        have n_eq: "2 * (n div 2) = n" unfolding numeral_2_eq_2[symmetric] by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   246
        with `n \<ge> 2 * f_no` have "n div 2 \<ge> f_no" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   247
        from f[OF this]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   248
        show ?thesis unfolding n_eq atLeastLessThanSuc_atLeastAtMost .
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   249
      next
35213
b9866ad4e3be fix looping call to simplifier
huffman
parents: 35038
diff changeset
   250
        case False hence "even (n - 1)" by simp
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   251
        from even_nat_div_two_times_two[OF this]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   252
        have n_eq: "2 * ((n - 1) div 2) = n - 1" unfolding numeral_2_eq_2[symmetric] by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   253
        hence range_eq: "n - 1 + 1 = n" using odd_pos[OF False] by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   254
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   255
        from n_eq `n \<ge> 2 * g_no` have "(n - 1) div 2 \<ge> g_no" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   256
        from g[OF this]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   257
        show ?thesis unfolding n_eq atLeastLessThanSuc_atLeastAtMost range_eq .
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   258
      qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   259
    }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   260
    thus "\<exists> no. \<forall> n \<ge> no. norm (?Sa n - l) < r" by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   261
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   262
  hence sums_l: "(\<lambda>i. (-1)^i * a i) sums l" unfolding sums_def atLeastLessThanSuc_atLeastAtMost[symmetric] .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   263
  thus "summable ?S" using summable_def by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   264
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   265
  have "l = suminf ?S" using sums_unique[OF sums_l] .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   266
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   267
  { fix n show "suminf ?S \<le> ?g n" unfolding sums_unique[OF sums_l, symmetric] using above_l by auto }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   268
  { fix n show "?f n \<le> suminf ?S" unfolding sums_unique[OF sums_l, symmetric] using below_l by auto }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   269
  show "?g ----> suminf ?S" using `?g ----> l` `l = suminf ?S` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   270
  show "?f ----> suminf ?S" using `?f ----> l` `l = suminf ?S` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   271
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   272
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   273
theorem summable_Leibniz: fixes a :: "nat \<Rightarrow> real"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   274
  assumes a_zero: "a ----> 0" and "monoseq a"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   275
  shows "summable (\<lambda> n. (-1)^n * a n)" (is "?summable")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   276
  and "0 < a 0 \<longrightarrow> (\<forall>n. (\<Sum>i. -1^i*a i) \<in> { \<Sum>i=0..<2*n. -1^i * a i .. \<Sum>i=0..<2*n+1. -1^i * a i})" (is "?pos")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   277
  and "a 0 < 0 \<longrightarrow> (\<forall>n. (\<Sum>i. -1^i*a i) \<in> { \<Sum>i=0..<2*n+1. -1^i * a i .. \<Sum>i=0..<2*n. -1^i * a i})" (is "?neg")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   278
  and "(\<lambda>n. \<Sum>i=0..<2*n. -1^i*a i) ----> (\<Sum>i. -1^i*a i)" (is "?f")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   279
  and "(\<lambda>n. \<Sum>i=0..<2*n+1. -1^i*a i) ----> (\<Sum>i. -1^i*a i)" (is "?g")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   280
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   281
  have "?summable \<and> ?pos \<and> ?neg \<and> ?f \<and> ?g"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   282
  proof (cases "(\<forall> n. 0 \<le> a n) \<and> (\<forall>m. \<forall>n\<ge>m. a n \<le> a m)")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   283
    case True
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   284
    hence ord: "\<And>n m. m \<le> n \<Longrightarrow> a n \<le> a m" and ge0: "\<And> n. 0 \<le> a n" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   285
    { fix n have "a (Suc n) \<le> a n" using ord[where n="Suc n" and m=n] by auto }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   286
    note leibniz = summable_Leibniz'[OF `a ----> 0` ge0] and mono = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   287
    from leibniz[OF mono]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   288
    show ?thesis using `0 \<le> a 0` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   289
  next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   290
    let ?a = "\<lambda> n. - a n"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   291
    case False
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   292
    with monoseq_le[OF `monoseq a` `a ----> 0`]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   293
    have "(\<forall> n. a n \<le> 0) \<and> (\<forall>m. \<forall>n\<ge>m. a m \<le> a n)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   294
    hence ord: "\<And>n m. m \<le> n \<Longrightarrow> ?a n \<le> ?a m" and ge0: "\<And> n. 0 \<le> ?a n" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   295
    { fix n have "?a (Suc n) \<le> ?a n" using ord[where n="Suc n" and m=n] by auto }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   296
    note monotone = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   297
    note leibniz = summable_Leibniz'[OF _ ge0, of "\<lambda>x. x", OF LIMSEQ_minus[OF `a ----> 0`, unfolded minus_zero] monotone]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   298
    have "summable (\<lambda> n. (-1)^n * ?a n)" using leibniz(1) by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   299
    then obtain l where "(\<lambda> n. (-1)^n * ?a n) sums l" unfolding summable_def by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   300
    from this[THEN sums_minus]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   301
    have "(\<lambda> n. (-1)^n * a n) sums -l" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   302
    hence ?summable unfolding summable_def by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   303
    moreover
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   304
    have "\<And> a b :: real. \<bar> - a - - b \<bar> = \<bar>a - b\<bar>" unfolding minus_diff_minus by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   305
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   306
    from suminf_minus[OF leibniz(1), unfolded mult_minus_right minus_minus]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   307
    have move_minus: "(\<Sum>n. - (-1 ^ n * a n)) = - (\<Sum>n. -1 ^ n * a n)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   308
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   309
    have ?pos using `0 \<le> ?a 0` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   310
    moreover have ?neg using leibniz(2,4) unfolding mult_minus_right setsum_negf move_minus neg_le_iff_le by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   311
    moreover have ?f and ?g using leibniz(3,5)[unfolded mult_minus_right setsum_negf move_minus, THEN LIMSEQ_minus_cancel] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   312
    ultimately show ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   313
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   314
  from this[THEN conjunct1] this[THEN conjunct2, THEN conjunct1] this[THEN conjunct2, THEN conjunct2, THEN conjunct1] this[THEN conjunct2, THEN conjunct2, THEN conjunct2, THEN conjunct1]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   315
       this[THEN conjunct2, THEN conjunct2, THEN conjunct2, THEN conjunct2]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   316
  show ?summable and ?pos and ?neg and ?f and ?g .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   317
qed
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   318
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
   319
subsection {* Term-by-Term Differentiability of Power Series *}
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   320
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   321
definition
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   322
  diffs :: "(nat => 'a::ring_1) => nat => 'a" where
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   323
  "diffs c = (%n. of_nat (Suc n) * c(Suc n))"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   324
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   325
text{*Lemma about distributing negation over it*}
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   326
lemma diffs_minus: "diffs (%n. - c n) = (%n. - diffs c n)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   327
by (simp add: diffs_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   328
29163
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   329
lemma sums_Suc_imp:
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   330
  assumes f: "f 0 = 0"
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   331
  shows "(\<lambda>n. f (Suc n)) sums s \<Longrightarrow> (\<lambda>n. f n) sums s"
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   332
unfolding sums_def
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   333
apply (rule LIMSEQ_imp_Suc)
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   334
apply (subst setsum_shift_lb_Suc0_0_upt [where f=f, OF f, symmetric])
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   335
apply (simp only: setsum_shift_bounds_Suc_ivl)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   336
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   337
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
   338
lemma diffs_equiv:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   339
  fixes x :: "'a::{real_normed_vector, ring_1}"
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   340
  shows "summable (%n. (diffs c)(n) * (x ^ n)) ==>
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   341
      (%n. of_nat n * c(n) * (x ^ (n - Suc 0))) sums
15546
5188ce7316b7 suminf -> \<Sum>
nipkow
parents: 15544
diff changeset
   342
         (\<Sum>n. (diffs c)(n) * (x ^ n))"
29163
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   343
unfolding diffs_def
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   344
apply (drule summable_sums)
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   345
apply (rule sums_Suc_imp, simp_all)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   346
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   347
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   348
lemma lemma_termdiff1:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   349
  fixes z :: "'a :: {monoid_mult,comm_ring}" shows
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   350
  "(\<Sum>p=0..<m. (((z + h) ^ (m - p)) * (z ^ p)) - (z ^ m)) =
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   351
   (\<Sum>p=0..<m. (z ^ p) * (((z + h) ^ (m - p)) - (z ^ (m - p))))"
41550
efa734d9b221 eliminated global prems;
wenzelm
parents: 38642
diff changeset
   352
by(auto simp add: algebra_simps power_add [symmetric])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   353
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   354
lemma sumr_diff_mult_const2:
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   355
  "setsum f {0..<n} - of_nat n * (r::'a::ring_1) = (\<Sum>i = 0..<n. f i - r)"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   356
by (simp add: setsum_subtractf)
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   357
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
   358
lemma lemma_termdiff2:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   359
  fixes h :: "'a :: {field}"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   360
  assumes h: "h \<noteq> 0" shows
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   361
  "((z + h) ^ n - z ^ n) / h - of_nat n * z ^ (n - Suc 0) =
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   362
   h * (\<Sum>p=0..< n - Suc 0. \<Sum>q=0..< n - Suc 0 - p.
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   363
        (z + h) ^ q * z ^ (n - 2 - q))" (is "?lhs = ?rhs")
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   364
apply (subgoal_tac "h * ?lhs = h * ?rhs", simp add: h)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   365
apply (simp add: right_diff_distrib diff_divide_distrib h)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   366
apply (simp add: mult_assoc [symmetric])
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   367
apply (cases "n", simp)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   368
apply (simp add: lemma_realpow_diff_sumr2 h
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   369
                 right_diff_distrib [symmetric] mult_assoc
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
   370
            del: power_Suc setsum_op_ivl_Suc of_nat_Suc)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   371
apply (subst lemma_realpow_rev_sumr)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   372
apply (subst sumr_diff_mult_const2)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   373
apply simp
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   374
apply (simp only: lemma_termdiff1 setsum_right_distrib)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   375
apply (rule setsum_cong [OF refl])
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
   376
apply (simp add: diff_minus [symmetric] less_iff_Suc_add)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   377
apply (clarify)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   378
apply (simp add: setsum_right_distrib lemma_realpow_diff_sumr2 mult_ac
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
   379
            del: setsum_op_ivl_Suc power_Suc)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   380
apply (subst mult_assoc [symmetric], subst power_add [symmetric])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   381
apply (simp add: mult_ac)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   382
done
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   383
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   384
lemma real_setsum_nat_ivl_bounded2:
35028
108662d50512 more consistent naming of type classes involving orderings (and lattices) -- c.f. NEWS
haftmann
parents: 34974
diff changeset
   385
  fixes K :: "'a::linordered_semidom"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   386
  assumes f: "\<And>p::nat. p < n \<Longrightarrow> f p \<le> K"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   387
  assumes K: "0 \<le> K"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   388
  shows "setsum f {0..<n-k} \<le> of_nat n * K"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   389
apply (rule order_trans [OF setsum_mono])
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   390
apply (rule f, simp)
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   391
apply (simp add: mult_right_mono K)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   392
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   393
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
   394
lemma lemma_termdiff3:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   395
  fixes h z :: "'a::{real_normed_field}"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   396
  assumes 1: "h \<noteq> 0"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   397
  assumes 2: "norm z \<le> K"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   398
  assumes 3: "norm (z + h) \<le> K"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   399
  shows "norm (((z + h) ^ n - z ^ n) / h - of_nat n * z ^ (n - Suc 0))
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   400
          \<le> of_nat n * of_nat (n - Suc 0) * K ^ (n - 2) * norm h"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   401
proof -
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   402
  have "norm (((z + h) ^ n - z ^ n) / h - of_nat n * z ^ (n - Suc 0)) =
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   403
        norm (\<Sum>p = 0..<n - Suc 0. \<Sum>q = 0..<n - Suc 0 - p.
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   404
          (z + h) ^ q * z ^ (n - 2 - q)) * norm h"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   405
    apply (subst lemma_termdiff2 [OF 1])
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   406
    apply (subst norm_mult)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   407
    apply (rule mult_commute)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   408
    done
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   409
  also have "\<dots> \<le> of_nat n * (of_nat (n - Suc 0) * K ^ (n - 2)) * norm h"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   410
  proof (rule mult_right_mono [OF _ norm_ge_zero])
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   411
    from norm_ge_zero 2 have K: "0 \<le> K" by (rule order_trans)
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   412
    have le_Kn: "\<And>i j n. i + j = n \<Longrightarrow> norm ((z + h) ^ i * z ^ j) \<le> K ^ n"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   413
      apply (erule subst)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   414
      apply (simp only: norm_mult norm_power power_add)
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   415
      apply (intro mult_mono power_mono 2 3 norm_ge_zero zero_le_power K)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   416
      done
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   417
    show "norm (\<Sum>p = 0..<n - Suc 0. \<Sum>q = 0..<n - Suc 0 - p.
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   418
              (z + h) ^ q * z ^ (n - 2 - q))
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   419
          \<le> of_nat n * (of_nat (n - Suc 0) * K ^ (n - 2))"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   420
      apply (intro
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   421
         order_trans [OF norm_setsum]
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   422
         real_setsum_nat_ivl_bounded2
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   423
         mult_nonneg_nonneg
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   424
         zero_le_imp_of_nat
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   425
         zero_le_power K)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   426
      apply (rule le_Kn, simp)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   427
      done
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   428
  qed
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   429
  also have "\<dots> = of_nat n * of_nat (n - Suc 0) * K ^ (n - 2) * norm h"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   430
    by (simp only: mult_assoc)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   431
  finally show ?thesis .
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   432
qed
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   433
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   434
lemma lemma_termdiff4:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   435
  fixes f :: "'a::{real_normed_field} \<Rightarrow>
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   436
              'b::real_normed_vector"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   437
  assumes k: "0 < (k::real)"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   438
  assumes le: "\<And>h. \<lbrakk>h \<noteq> 0; norm h < k\<rbrakk> \<Longrightarrow> norm (f h) \<le> K * norm h"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   439
  shows "f -- 0 --> 0"
31338
d41a8ba25b67 generalize constants from Lim.thy to class metric_space
huffman
parents: 31271
diff changeset
   440
unfolding LIM_eq diff_0_right
29163
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   441
proof (safe)
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   442
  let ?h = "of_real (k / 2)::'a"
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   443
  have "?h \<noteq> 0" and "norm ?h < k" using k by simp_all
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   444
  hence "norm (f ?h) \<le> K * norm ?h" by (rule le)
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   445
  hence "0 \<le> K * norm ?h" by (rule order_trans [OF norm_ge_zero])
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   446
  hence zero_le_K: "0 \<le> K" using k by (simp add: zero_le_mult_iff)
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   447
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   448
  fix r::real assume r: "0 < r"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   449
  show "\<exists>s. 0 < s \<and> (\<forall>x. x \<noteq> 0 \<and> norm x < s \<longrightarrow> norm (f x) < r)"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   450
  proof (cases)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   451
    assume "K = 0"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   452
    with k r le have "0 < k \<and> (\<forall>x. x \<noteq> 0 \<and> norm x < k \<longrightarrow> norm (f x) < r)"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   453
      by simp
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   454
    thus "\<exists>s. 0 < s \<and> (\<forall>x. x \<noteq> 0 \<and> norm x < s \<longrightarrow> norm (f x) < r)" ..
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   455
  next
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   456
    assume K_neq_zero: "K \<noteq> 0"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   457
    with zero_le_K have K: "0 < K" by simp
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   458
    show "\<exists>s. 0 < s \<and> (\<forall>x. x \<noteq> 0 \<and> norm x < s \<longrightarrow> norm (f x) < r)"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   459
    proof (rule exI, safe)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   460
      from k r K show "0 < min k (r * inverse K / 2)"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   461
        by (simp add: mult_pos_pos positive_imp_inverse_positive)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   462
    next
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   463
      fix x::'a
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   464
      assume x1: "x \<noteq> 0" and x2: "norm x < min k (r * inverse K / 2)"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   465
      from x2 have x3: "norm x < k" and x4: "norm x < r * inverse K / 2"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   466
        by simp_all
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   467
      from x1 x3 le have "norm (f x) \<le> K * norm x" by simp
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   468
      also from x4 K have "K * norm x < K * (r * inverse K / 2)"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   469
        by (rule mult_strict_left_mono)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   470
      also have "\<dots> = r / 2"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   471
        using K_neq_zero by simp
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   472
      also have "r / 2 < r"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   473
        using r by simp
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   474
      finally show "norm (f x) < r" .
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   475
    qed
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   476
  qed
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   477
qed
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   478
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
   479
lemma lemma_termdiff5:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   480
  fixes g :: "'a::{real_normed_field} \<Rightarrow>
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   481
              nat \<Rightarrow> 'b::banach"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   482
  assumes k: "0 < (k::real)"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   483
  assumes f: "summable f"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   484
  assumes le: "\<And>h n. \<lbrakk>h \<noteq> 0; norm h < k\<rbrakk> \<Longrightarrow> norm (g h n) \<le> f n * norm h"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   485
  shows "(\<lambda>h. suminf (g h)) -- 0 --> 0"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   486
proof (rule lemma_termdiff4 [OF k])
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   487
  fix h::'a assume "h \<noteq> 0" and "norm h < k"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   488
  hence A: "\<forall>n. norm (g h n) \<le> f n * norm h"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   489
    by (simp add: le)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   490
  hence "\<exists>N. \<forall>n\<ge>N. norm (norm (g h n)) \<le> f n * norm h"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   491
    by simp
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   492
  moreover from f have B: "summable (\<lambda>n. f n * norm h)"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   493
    by (rule summable_mult2)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   494
  ultimately have C: "summable (\<lambda>n. norm (g h n))"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   495
    by (rule summable_comparison_test)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   496
  hence "norm (suminf (g h)) \<le> (\<Sum>n. norm (g h n))"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   497
    by (rule summable_norm)
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   498
  also from A C B have "(\<Sum>n. norm (g h n)) \<le> (\<Sum>n. f n * norm h)"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   499
    by (rule summable_le)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   500
  also from f have "(\<Sum>n. f n * norm h) = suminf f * norm h"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   501
    by (rule suminf_mult2 [symmetric])
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   502
  finally show "norm (suminf (g h)) \<le> suminf f * norm h" .
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   503
qed
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   504
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   505
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   506
text{* FIXME: Long proofs*}
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   507
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   508
lemma termdiffs_aux:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   509
  fixes x :: "'a::{real_normed_field,banach}"
20849
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   510
  assumes 1: "summable (\<lambda>n. diffs (diffs c) n * K ^ n)"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   511
  assumes 2: "norm x < norm K"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   512
  shows "(\<lambda>h. \<Sum>n. c n * (((x + h) ^ n - x ^ n) / h
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   513
             - of_nat n * x ^ (n - Suc 0))) -- 0 --> 0"
20849
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   514
proof -
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   515
  from dense [OF 2]
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   516
  obtain r where r1: "norm x < r" and r2: "r < norm K" by fast
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   517
  from norm_ge_zero r1 have r: "0 < r"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   518
    by (rule order_le_less_trans)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   519
  hence r_neq_0: "r \<noteq> 0" by simp
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   520
  show ?thesis
20849
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   521
  proof (rule lemma_termdiff5)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   522
    show "0 < r - norm x" using r1 by simp
20849
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   523
  next
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   524
    from r r2 have "norm (of_real r::'a) < norm K"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   525
      by simp
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   526
    with 1 have "summable (\<lambda>n. norm (diffs (diffs c) n * (of_real r ^ n)))"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   527
      by (rule powser_insidea)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   528
    hence "summable (\<lambda>n. diffs (diffs (\<lambda>n. norm (c n))) n * r ^ n)"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   529
      using r
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   530
      by (simp add: diffs_def norm_mult norm_power del: of_nat_Suc)
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   531
    hence "summable (\<lambda>n. of_nat n * diffs (\<lambda>n. norm (c n)) n * r ^ (n - Suc 0))"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   532
      by (rule diffs_equiv [THEN sums_summable])
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   533
    also have "(\<lambda>n. of_nat n * diffs (\<lambda>n. norm (c n)) n * r ^ (n - Suc 0))
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   534
      = (\<lambda>n. diffs (%m. of_nat (m - Suc 0) * norm (c m) * inverse r) n * (r ^ n))"
20849
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   535
      apply (rule ext)
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   536
      apply (simp add: diffs_def)
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   537
      apply (case_tac n, simp_all add: r_neq_0)
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   538
      done
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   539
    finally have "summable
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   540
      (\<lambda>n. of_nat n * (of_nat (n - Suc 0) * norm (c n) * inverse r) * r ^ (n - Suc 0))"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   541
      by (rule diffs_equiv [THEN sums_summable])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   542
    also have
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   543
      "(\<lambda>n. of_nat n * (of_nat (n - Suc 0) * norm (c n) * inverse r) *
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   544
           r ^ (n - Suc 0)) =
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   545
       (\<lambda>n. norm (c n) * of_nat n * of_nat (n - Suc 0) * r ^ (n - 2))"
20849
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   546
      apply (rule ext)
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   547
      apply (case_tac "n", simp)
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   548
      apply (case_tac "nat", simp)
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   549
      apply (simp add: r_neq_0)
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   550
      done
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   551
    finally show
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   552
      "summable (\<lambda>n. norm (c n) * of_nat n * of_nat (n - Suc 0) * r ^ (n - 2))" .
20849
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   553
  next
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   554
    fix h::'a and n::nat
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   555
    assume h: "h \<noteq> 0"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   556
    assume "norm h < r - norm x"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   557
    hence "norm x + norm h < r" by simp
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   558
    with norm_triangle_ineq have xh: "norm (x + h) < r"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   559
      by (rule order_le_less_trans)
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   560
    show "norm (c n * (((x + h) ^ n - x ^ n) / h - of_nat n * x ^ (n - Suc 0)))
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   561
          \<le> norm (c n) * of_nat n * of_nat (n - Suc 0) * r ^ (n - 2) * norm h"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   562
      apply (simp only: norm_mult mult_assoc)
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   563
      apply (rule mult_left_mono [OF _ norm_ge_zero])
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   564
      apply (simp (no_asm) add: mult_assoc [symmetric])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   565
      apply (rule lemma_termdiff3)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   566
      apply (rule h)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   567
      apply (rule r1 [THEN order_less_imp_le])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   568
      apply (rule xh [THEN order_less_imp_le])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   569
      done
20849
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   570
  qed
389cd9c8cfe1 rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents: 20692
diff changeset
   571
qed
20217
25b068a99d2b linear arithmetic splits certain operators (e.g. min, max, abs)
webertj
parents: 19765
diff changeset
   572
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   573
lemma termdiffs:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   574
  fixes K x :: "'a::{real_normed_field,banach}"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   575
  assumes 1: "summable (\<lambda>n. c n * K ^ n)"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   576
  assumes 2: "summable (\<lambda>n. (diffs c) n * K ^ n)"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   577
  assumes 3: "summable (\<lambda>n. (diffs (diffs c)) n * K ^ n)"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   578
  assumes 4: "norm x < norm K"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   579
  shows "DERIV (\<lambda>x. \<Sum>n. c n * x ^ n) x :> (\<Sum>n. (diffs c) n * x ^ n)"
29163
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   580
unfolding deriv_def
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   581
proof (rule LIM_zero_cancel)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   582
  show "(\<lambda>h. (suminf (\<lambda>n. c n * (x + h) ^ n) - suminf (\<lambda>n. c n * x ^ n)) / h
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   583
            - suminf (\<lambda>n. diffs c n * x ^ n)) -- 0 --> 0"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   584
  proof (rule LIM_equal2)
29163
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   585
    show "0 < norm K - norm x" using 4 by (simp add: less_diff_eq)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   586
  next
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   587
    fix h :: 'a
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   588
    assume "h \<noteq> 0"
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   589
    assume "norm (h - 0) < norm K - norm x"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   590
    hence "norm x + norm h < norm K" by simp
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   591
    hence 5: "norm (x + h) < norm K"
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   592
      by (rule norm_triangle_ineq [THEN order_le_less_trans])
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   593
    have A: "summable (\<lambda>n. c n * x ^ n)"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   594
      by (rule powser_inside [OF 1 4])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   595
    have B: "summable (\<lambda>n. c n * (x + h) ^ n)"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   596
      by (rule powser_inside [OF 1 5])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   597
    have C: "summable (\<lambda>n. diffs c n * x ^ n)"
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   598
      by (rule powser_inside [OF 2 4])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   599
    show "((\<Sum>n. c n * (x + h) ^ n) - (\<Sum>n. c n * x ^ n)) / h
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   600
             - (\<Sum>n. diffs c n * x ^ n) =
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   601
          (\<Sum>n. c n * (((x + h) ^ n - x ^ n) / h - of_nat n * x ^ (n - Suc 0)))"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   602
      apply (subst sums_unique [OF diffs_equiv [OF C]])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   603
      apply (subst suminf_diff [OF B A])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   604
      apply (subst suminf_divide [symmetric])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   605
      apply (rule summable_diff [OF B A])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   606
      apply (subst suminf_diff)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   607
      apply (rule summable_divide)
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   608
      apply (rule summable_diff [OF B A])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   609
      apply (rule sums_summable [OF diffs_equiv [OF C]])
29163
e72d07a878f8 clean up some proofs; remove unused lemmas
huffman
parents: 28952
diff changeset
   610
      apply (rule arg_cong [where f="suminf"], rule ext)
29667
53103fc8ffa3 Replaced group_ and ring_simps by algebra_simps;
nipkow
parents: 29171
diff changeset
   611
      apply (simp add: algebra_simps)
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   612
      done
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   613
  next
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   614
    show "(\<lambda>h. \<Sum>n. c n * (((x + h) ^ n - x ^ n) / h -
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   615
               of_nat n * x ^ (n - Suc 0))) -- 0 --> 0"
20860
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   616
        by (rule termdiffs_aux [OF 3 4])
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   617
  qed
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   618
qed
1a8efd618190 reorganize and speed up termdiffs proofs
huffman
parents: 20849
diff changeset
   619
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   620
29695
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   621
subsection{* Some properties of factorials *}
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   622
32036
8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged.
avigad
parents: 31881
diff changeset
   623
lemma real_of_nat_fact_not_zero [simp]: "real (fact (n::nat)) \<noteq> 0"
29695
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   624
by auto
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   625
32036
8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged.
avigad
parents: 31881
diff changeset
   626
lemma real_of_nat_fact_gt_zero [simp]: "0 < real(fact (n::nat))"
29695
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   627
by auto
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   628
32036
8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged.
avigad
parents: 31881
diff changeset
   629
lemma real_of_nat_fact_ge_zero [simp]: "0 \<le> real(fact (n::nat))"
29695
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   630
by simp
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   631
32036
8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged.
avigad
parents: 31881
diff changeset
   632
lemma inv_real_of_nat_fact_gt_zero [simp]: "0 < inverse (real (fact (n::nat)))"
29695
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   633
by (auto simp add: positive_imp_inverse_positive)
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   634
32036
8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged.
avigad
parents: 31881
diff changeset
   635
lemma inv_real_of_nat_fact_ge_zero [simp]: "0 \<le> inverse (real (fact (n::nat)))"
29695
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   636
by (auto intro: order_less_imp_le)
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   637
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   638
subsection {* Derivability of power series *}
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   639
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   640
lemma DERIV_series': fixes f :: "real \<Rightarrow> nat \<Rightarrow> real"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   641
  assumes DERIV_f: "\<And> n. DERIV (\<lambda> x. f x n) x0 :> (f' x0 n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   642
  and allf_summable: "\<And> x. x \<in> {a <..< b} \<Longrightarrow> summable (f x)" and x0_in_I: "x0 \<in> {a <..< b}"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   643
  and "summable (f' x0)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   644
  and "summable L" and L_def: "\<And> n x y. \<lbrakk> x \<in> { a <..< b} ; y \<in> { a <..< b} \<rbrakk> \<Longrightarrow> \<bar> f x n - f y n \<bar> \<le> L n * \<bar> x - y \<bar>"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   645
  shows "DERIV (\<lambda> x. suminf (f x)) x0 :> (suminf (f' x0))"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   646
  unfolding deriv_def
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   647
proof (rule LIM_I)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   648
  fix r :: real assume "0 < r" hence "0 < r/3" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   649
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   650
  obtain N_L where N_L: "\<And> n. N_L \<le> n \<Longrightarrow> \<bar> \<Sum> i. L (i + n) \<bar> < r/3"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   651
    using suminf_exist_split[OF `0 < r/3` `summable L`] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   652
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   653
  obtain N_f' where N_f': "\<And> n. N_f' \<le> n \<Longrightarrow> \<bar> \<Sum> i. f' x0 (i + n) \<bar> < r/3"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   654
    using suminf_exist_split[OF `0 < r/3` `summable (f' x0)`] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   655
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   656
  let ?N = "Suc (max N_L N_f')"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   657
  have "\<bar> \<Sum> i. f' x0 (i + ?N) \<bar> < r/3" (is "?f'_part < r/3") and
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   658
    L_estimate: "\<bar> \<Sum> i. L (i + ?N) \<bar> < r/3" using N_L[of "?N"] and N_f' [of "?N"] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   659
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   660
  let "?diff i x" = "(f (x0 + x) i - f x0 i) / x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   661
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   662
  let ?r = "r / (3 * real ?N)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   663
  have "0 < 3 * real ?N" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   664
  from divide_pos_pos[OF `0 < r` this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   665
  have "0 < ?r" .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   666
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   667
  let "?s n" = "SOME s. 0 < s \<and> (\<forall> x. x \<noteq> 0 \<and> \<bar> x \<bar> < s \<longrightarrow> \<bar> ?diff n x - f' x0 n \<bar> < ?r)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   668
  def S' \<equiv> "Min (?s ` { 0 ..< ?N })"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   669
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   670
  have "0 < S'" unfolding S'_def
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   671
  proof (rule iffD2[OF Min_gr_iff])
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   672
    show "\<forall> x \<in> (?s ` { 0 ..< ?N }). 0 < x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   673
    proof (rule ballI)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   674
      fix x assume "x \<in> ?s ` {0..<?N}"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   675
      then obtain n where "x = ?s n" and "n \<in> {0..<?N}" using image_iff[THEN iffD1] by blast
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   676
      from DERIV_D[OF DERIV_f[where n=n], THEN LIM_D, OF `0 < ?r`, unfolded real_norm_def]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   677
      obtain s where s_bound: "0 < s \<and> (\<forall>x. x \<noteq> 0 \<and> \<bar>x\<bar> < s \<longrightarrow> \<bar>?diff n x - f' x0 n\<bar> < ?r)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   678
      have "0 < ?s n" by (rule someI2[where a=s], auto simp add: s_bound)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   679
      thus "0 < x" unfolding `x = ?s n` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   680
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   681
  qed auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   682
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   683
  def S \<equiv> "min (min (x0 - a) (b - x0)) S'"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   684
  hence "0 < S" and S_a: "S \<le> x0 - a" and S_b: "S \<le> b - x0" and "S \<le> S'" using x0_in_I and `0 < S'`
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   685
    by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   686
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   687
  { fix x assume "x \<noteq> 0" and "\<bar> x \<bar> < S"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   688
    hence x_in_I: "x0 + x \<in> { a <..< b }" using S_a S_b by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   689
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   690
    note diff_smbl = summable_diff[OF allf_summable[OF x_in_I] allf_summable[OF x0_in_I]]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   691
    note div_smbl = summable_divide[OF diff_smbl]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   692
    note all_smbl = summable_diff[OF div_smbl `summable (f' x0)`]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   693
    note ign = summable_ignore_initial_segment[where k="?N"]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   694
    note diff_shft_smbl = summable_diff[OF ign[OF allf_summable[OF x_in_I]] ign[OF allf_summable[OF x0_in_I]]]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   695
    note div_shft_smbl = summable_divide[OF diff_shft_smbl]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   696
    note all_shft_smbl = summable_diff[OF div_smbl ign[OF `summable (f' x0)`]]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   697
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   698
    { fix n
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   699
      have "\<bar> ?diff (n + ?N) x \<bar> \<le> L (n + ?N) * \<bar> (x0 + x) - x0 \<bar> / \<bar> x \<bar>"
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   700
        using divide_right_mono[OF L_def[OF x_in_I x0_in_I] abs_ge_zero] unfolding abs_divide .
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   701
      hence "\<bar> ( \<bar> ?diff (n + ?N) x \<bar>) \<bar> \<le> L (n + ?N)" using `x \<noteq> 0` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   702
    } note L_ge = summable_le2[OF allI[OF this] ign[OF `summable L`]]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   703
    from order_trans[OF summable_rabs[OF conjunct1[OF L_ge]] L_ge[THEN conjunct2]]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   704
    have "\<bar> \<Sum> i. ?diff (i + ?N) x \<bar> \<le> (\<Sum> i. L (i + ?N))" .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   705
    hence "\<bar> \<Sum> i. ?diff (i + ?N) x \<bar> \<le> r / 3" (is "?L_part \<le> r/3") using L_estimate by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   706
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   707
    have "\<bar>\<Sum>n \<in> { 0 ..< ?N}. ?diff n x - f' x0 n \<bar> \<le> (\<Sum>n \<in> { 0 ..< ?N}. \<bar>?diff n x - f' x0 n \<bar>)" ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   708
    also have "\<dots> < (\<Sum>n \<in> { 0 ..< ?N}. ?r)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   709
    proof (rule setsum_strict_mono)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   710
      fix n assume "n \<in> { 0 ..< ?N}"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   711
      have "\<bar> x \<bar> < S" using `\<bar> x \<bar> < S` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   712
      also have "S \<le> S'" using `S \<le> S'` .
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   713
      also have "S' \<le> ?s n" unfolding S'_def
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   714
      proof (rule Min_le_iff[THEN iffD2])
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   715
        have "?s n \<in> (?s ` {0..<?N}) \<and> ?s n \<le> ?s n" using `n \<in> { 0 ..< ?N}` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   716
        thus "\<exists> a \<in> (?s ` {0..<?N}). a \<le> ?s n" by blast
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   717
      qed auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   718
      finally have "\<bar> x \<bar> < ?s n" .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   719
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   720
      from DERIV_D[OF DERIV_f[where n=n], THEN LIM_D, OF `0 < ?r`, unfolded real_norm_def diff_0_right, unfolded some_eq_ex[symmetric], THEN conjunct2]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   721
      have "\<forall>x. x \<noteq> 0 \<and> \<bar>x\<bar> < ?s n \<longrightarrow> \<bar>?diff n x - f' x0 n\<bar> < ?r" .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   722
      with `x \<noteq> 0` and `\<bar>x\<bar> < ?s n`
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   723
      show "\<bar>?diff n x - f' x0 n\<bar> < ?r" by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   724
    qed auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   725
    also have "\<dots> = of_nat (card {0 ..< ?N}) * ?r" by (rule setsum_constant)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   726
    also have "\<dots> = real ?N * ?r" unfolding real_eq_of_nat by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   727
    also have "\<dots> = r/3" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   728
    finally have "\<bar>\<Sum>n \<in> { 0 ..< ?N}. ?diff n x - f' x0 n \<bar> < r / 3" (is "?diff_part < r / 3") .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   729
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   730
    from suminf_diff[OF allf_summable[OF x_in_I] allf_summable[OF x0_in_I]]
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   731
    have "\<bar> (suminf (f (x0 + x)) - (suminf (f x0))) / x - suminf (f' x0) \<bar> =
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   732
                    \<bar> \<Sum>n. ?diff n x - f' x0 n \<bar>" unfolding suminf_diff[OF div_smbl `summable (f' x0)`, symmetric] using suminf_divide[OF diff_smbl, symmetric] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   733
    also have "\<dots> \<le> ?diff_part + \<bar> (\<Sum>n. ?diff (n + ?N) x) - (\<Sum> n. f' x0 (n + ?N)) \<bar>" unfolding suminf_split_initial_segment[OF all_smbl, where k="?N"] unfolding suminf_diff[OF div_shft_smbl ign[OF `summable (f' x0)`]] by (rule abs_triangle_ineq)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   734
    also have "\<dots> \<le> ?diff_part + ?L_part + ?f'_part" using abs_triangle_ineq4 by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   735
    also have "\<dots> < r /3 + r/3 + r/3"
36842
99745a4b9cc9 fix some linarith_split_limit warnings
huffman
parents: 36824
diff changeset
   736
      using `?diff_part < r/3` `?L_part \<le> r/3` and `?f'_part < r/3`
99745a4b9cc9 fix some linarith_split_limit warnings
huffman
parents: 36824
diff changeset
   737
      by (rule add_strict_mono [OF add_less_le_mono])
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   738
    finally have "\<bar> (suminf (f (x0 + x)) - (suminf (f x0))) / x - suminf (f' x0) \<bar> < r"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   739
      by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   740
  } thus "\<exists> s > 0. \<forall> x. x \<noteq> 0 \<and> norm (x - 0) < s \<longrightarrow>
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   741
      norm (((\<Sum>n. f (x0 + x) n) - (\<Sum>n. f x0 n)) / x - (\<Sum>n. f' x0 n)) < r" using `0 < S`
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   742
    unfolding real_norm_def diff_0_right by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   743
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   744
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   745
lemma DERIV_power_series': fixes f :: "nat \<Rightarrow> real"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   746
  assumes converges: "\<And> x. x \<in> {-R <..< R} \<Longrightarrow> summable (\<lambda> n. f n * real (Suc n) * x^n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   747
  and x0_in_I: "x0 \<in> {-R <..< R}" and "0 < R"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   748
  shows "DERIV (\<lambda> x. (\<Sum> n. f n * x^(Suc n))) x0 :> (\<Sum> n. f n * real (Suc n) * x0^n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   749
  (is "DERIV (\<lambda> x. (suminf (?f x))) x0 :> (suminf (?f' x0))")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   750
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   751
  { fix R' assume "0 < R'" and "R' < R" and "-R' < x0" and "x0 < R'"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   752
    hence "x0 \<in> {-R' <..< R'}" and "R' \<in> {-R <..< R}" and "x0 \<in> {-R <..< R}" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   753
    have "DERIV (\<lambda> x. (suminf (?f x))) x0 :> (suminf (?f' x0))"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   754
    proof (rule DERIV_series')
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   755
      show "summable (\<lambda> n. \<bar>f n * real (Suc n) * R'^n\<bar>)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   756
      proof -
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   757
        have "(R' + R) / 2 < R" and "0 < (R' + R) / 2" using `0 < R'` `0 < R` `R' < R` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   758
        hence in_Rball: "(R' + R) / 2 \<in> {-R <..< R}" using `R' < R` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   759
        have "norm R' < norm ((R' + R) / 2)" using `0 < R'` `0 < R` `R' < R` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   760
        from powser_insidea[OF converges[OF in_Rball] this] show ?thesis by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   761
      qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   762
      { fix n x y assume "x \<in> {-R' <..< R'}" and "y \<in> {-R' <..< R'}"
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   763
        show "\<bar>?f x n - ?f y n\<bar> \<le> \<bar>f n * real (Suc n) * R'^n\<bar> * \<bar>x-y\<bar>"
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   764
        proof -
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   765
          have "\<bar>f n * x ^ (Suc n) - f n * y ^ (Suc n)\<bar> = (\<bar>f n\<bar> * \<bar>x-y\<bar>) * \<bar>\<Sum>p = 0..<Suc n. x ^ p * y ^ (n - p)\<bar>"
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   766
            unfolding right_diff_distrib[symmetric] lemma_realpow_diff_sumr2 abs_mult by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   767
          also have "\<dots> \<le> (\<bar>f n\<bar> * \<bar>x-y\<bar>) * (\<bar>real (Suc n)\<bar> * \<bar>R' ^ n\<bar>)"
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   768
          proof (rule mult_left_mono)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   769
            have "\<bar>\<Sum>p = 0..<Suc n. x ^ p * y ^ (n - p)\<bar> \<le> (\<Sum>p = 0..<Suc n. \<bar>x ^ p * y ^ (n - p)\<bar>)" by (rule setsum_abs)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   770
            also have "\<dots> \<le> (\<Sum>p = 0..<Suc n. R' ^ n)"
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   771
            proof (rule setsum_mono)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   772
              fix p assume "p \<in> {0..<Suc n}" hence "p \<le> n" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   773
              { fix n fix x :: real assume "x \<in> {-R'<..<R'}"
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   774
                hence "\<bar>x\<bar> \<le> R'"  by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   775
                hence "\<bar>x^n\<bar> \<le> R'^n" unfolding power_abs by (rule power_mono, auto)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   776
              } from mult_mono[OF this[OF `x \<in> {-R'<..<R'}`, of p] this[OF `y \<in> {-R'<..<R'}`, of "n-p"]] `0 < R'`
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   777
              have "\<bar>x^p * y^(n-p)\<bar> \<le> R'^p * R'^(n-p)" unfolding abs_mult by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   778
              thus "\<bar>x^p * y^(n-p)\<bar> \<le> R'^n" unfolding power_add[symmetric] using `p \<le> n` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   779
            qed
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   780
            also have "\<dots> = real (Suc n) * R' ^ n" unfolding setsum_constant card_atLeastLessThan real_of_nat_def by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   781
            finally show "\<bar>\<Sum>p = 0..<Suc n. x ^ p * y ^ (n - p)\<bar> \<le> \<bar>real (Suc n)\<bar> * \<bar>R' ^ n\<bar>" unfolding abs_real_of_nat_cancel abs_of_nonneg[OF zero_le_power[OF less_imp_le[OF `0 < R'`]]] .
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   782
            show "0 \<le> \<bar>f n\<bar> * \<bar>x - y\<bar>" unfolding abs_mult[symmetric] by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   783
          qed
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
   784
          also have "\<dots> = \<bar>f n * real (Suc n) * R' ^ n\<bar> * \<bar>x - y\<bar>" unfolding abs_mult mult_assoc[symmetric] by algebra
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   785
          finally show ?thesis .
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   786
        qed }
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
   787
      { fix n show "DERIV (\<lambda> x. ?f x n) x0 :> (?f' x0 n)"
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   788
          by (auto intro!: DERIV_intros simp del: power_Suc) }
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   789
      { fix x assume "x \<in> {-R' <..< R'}" hence "R' \<in> {-R <..< R}" and "norm x < norm R'" using assms `R' < R` by auto
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   790
        have "summable (\<lambda> n. f n * x^n)"
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   791
        proof (rule summable_le2[THEN conjunct1, OF _ powser_insidea[OF converges[OF `R' \<in> {-R <..< R}`] `norm x < norm R'`]], rule allI)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   792
          fix n
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   793
          have le: "\<bar>f n\<bar> * 1 \<le> \<bar>f n\<bar> * real (Suc n)" by (rule mult_left_mono, auto)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   794
          show "\<bar>f n * x ^ n\<bar> \<le> norm (f n * real (Suc n) * x ^ n)" unfolding real_norm_def abs_mult
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   795
            by (rule mult_right_mono, auto simp add: le[unfolded mult_1_right])
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   796
        qed
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
   797
        from this[THEN summable_mult2[where c=x], unfolded mult_assoc, unfolded mult_commute]
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
   798
        show "summable (?f x)" by auto }
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   799
      show "summable (?f' x0)" using converges[OF `x0 \<in> {-R <..< R}`] .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   800
      show "x0 \<in> {-R' <..< R'}" using `x0 \<in> {-R' <..< R'}` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   801
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   802
  } note for_subinterval = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   803
  let ?R = "(R + \<bar>x0\<bar>) / 2"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   804
  have "\<bar>x0\<bar> < ?R" using assms by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   805
  hence "- ?R < x0"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   806
  proof (cases "x0 < 0")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   807
    case True
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   808
    hence "- x0 < ?R" using `\<bar>x0\<bar> < ?R` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   809
    thus ?thesis unfolding neg_less_iff_less[symmetric, of "- x0"] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   810
  next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   811
    case False
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   812
    have "- ?R < 0" using assms by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   813
    also have "\<dots> \<le> x0" using False by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   814
    finally show ?thesis .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   815
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   816
  hence "0 < ?R" "?R < R" "- ?R < x0" and "x0 < ?R" using assms by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   817
  from for_subinterval[OF this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   818
  show ?thesis .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
   819
qed
29695
171146a93106 Added real related theorems from Fact.thy
chaieb
parents: 29667
diff changeset
   820
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
   821
subsection {* Exponential Function *}
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   822
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   823
definition
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   824
  exp :: "'a \<Rightarrow> 'a::{real_normed_field,banach}" where
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   825
  "exp x = (\<Sum>n. x ^ n /\<^sub>R real (fact n))"
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   826
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   827
lemma summable_exp_generic:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   828
  fixes x :: "'a::{real_normed_algebra_1,banach}"
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   829
  defines S_def: "S \<equiv> \<lambda>n. x ^ n /\<^sub>R real (fact n)"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   830
  shows "summable S"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   831
proof -
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   832
  have S_Suc: "\<And>n. S (Suc n) = (x * S n) /\<^sub>R real (Suc n)"
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
   833
    unfolding S_def by (simp del: mult_Suc)
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   834
  obtain r :: real where r0: "0 < r" and r1: "r < 1"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   835
    using dense [OF zero_less_one] by fast
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   836
  obtain N :: nat where N: "norm x < real N * r"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   837
    using reals_Archimedean3 [OF r0] by fast
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   838
  from r1 show ?thesis
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   839
  proof (rule ratio_test [rule_format])
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   840
    fix n :: nat
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   841
    assume n: "N \<le> n"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   842
    have "norm x \<le> real N * r"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   843
      using N by (rule order_less_imp_le)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   844
    also have "real N * r \<le> real (Suc n) * r"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   845
      using r0 n by (simp add: mult_right_mono)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   846
    finally have "norm x * norm (S n) \<le> real (Suc n) * r * norm (S n)"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   847
      using norm_ge_zero by (rule mult_right_mono)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   848
    hence "norm (x * S n) \<le> real (Suc n) * r * norm (S n)"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   849
      by (rule order_trans [OF norm_mult_ineq])
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   850
    hence "norm (x * S n) / real (Suc n) \<le> r * norm (S n)"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   851
      by (simp add: pos_divide_le_eq mult_ac)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   852
    thus "norm (S (Suc n)) \<le> r * norm (S n)"
35216
7641e8d831d2 get rid of many duplicate simp rule warnings
huffman
parents: 35213
diff changeset
   853
      by (simp add: S_Suc inverse_eq_divide)
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   854
  qed
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   855
qed
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   856
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   857
lemma summable_norm_exp:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   858
  fixes x :: "'a::{real_normed_algebra_1,banach}"
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   859
  shows "summable (\<lambda>n. norm (x ^ n /\<^sub>R real (fact n)))"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   860
proof (rule summable_norm_comparison_test [OF exI, rule_format])
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   861
  show "summable (\<lambda>n. norm x ^ n /\<^sub>R real (fact n))"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   862
    by (rule summable_exp_generic)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   863
next
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   864
  fix n show "norm (x ^ n /\<^sub>R real (fact n)) \<le> norm x ^ n /\<^sub>R real (fact n)"
35216
7641e8d831d2 get rid of many duplicate simp rule warnings
huffman
parents: 35213
diff changeset
   865
    by (simp add: norm_power_ineq)
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   866
qed
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   867
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   868
lemma summable_exp: "summable (%n. inverse (real (fact n)) * x ^ n)"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   869
by (insert summable_exp_generic [where x=x], simp)
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   870
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   871
lemma exp_converges: "(\<lambda>n. x ^ n /\<^sub>R real (fact n)) sums exp x"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   872
unfolding exp_def by (rule summable_exp_generic [THEN summable_sums])
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   873
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
   874
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
   875
lemma exp_fdiffs:
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   876
      "diffs (%n. inverse(real (fact n))) = (%n. inverse(real (fact n)))"
23431
25ca91279a9b change simp rules for of_nat to work like int did previously (reorient of_nat_Suc, remove of_nat_mult [simp]); preserve original variable names in legacy int theorems
huffman
parents: 23413
diff changeset
   877
by (simp add: diffs_def mult_assoc [symmetric] real_of_nat_def of_nat_mult
23082
ffef77eed382 generalize powerseries and termdiffs lemmas using axclasses
huffman
parents: 23069
diff changeset
   878
         del: mult_Suc of_nat_Suc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   879
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   880
lemma diffs_of_real: "diffs (\<lambda>n. of_real (f n)) = (\<lambda>n. of_real (diffs f n))"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   881
by (simp add: diffs_def)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   882
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   883
lemma lemma_exp_ext: "exp = (\<lambda>x. \<Sum>n. x ^ n /\<^sub>R real (fact n))"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   884
by (auto intro!: ext simp add: exp_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   885
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   886
lemma DERIV_exp [simp]: "DERIV exp x :> exp(x)"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
   887
apply (simp add: exp_def)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   888
apply (subst lemma_exp_ext)
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   889
apply (subgoal_tac "DERIV (\<lambda>u. \<Sum>n. of_real (inverse (real (fact n))) * u ^ n) x :> (\<Sum>n. diffs (\<lambda>n. of_real (inverse (real (fact n)))) n * x ^ n)")
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   890
apply (rule_tac [2] K = "of_real (1 + norm x)" in termdiffs)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   891
apply (simp_all only: diffs_of_real scaleR_conv_of_real exp_fdiffs)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   892
apply (rule exp_converges [THEN sums_summable, unfolded scaleR_conv_of_real])+
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   893
apply (simp del: of_real_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   894
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   895
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
   896
lemma isCont_exp [simp]: "isCont exp x"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
   897
by (rule DERIV_exp [THEN DERIV_isCont])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
   898
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
   899
29167
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
   900
subsubsection {* Properties of the Exponential Function *}
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   901
23278
375335bf619f clean up proofs of exp_zero, sin_zero, cos_zero
huffman
parents: 23255
diff changeset
   902
lemma powser_zero:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   903
  fixes f :: "nat \<Rightarrow> 'a::{real_normed_algebra_1}"
23278
375335bf619f clean up proofs of exp_zero, sin_zero, cos_zero
huffman
parents: 23255
diff changeset
   904
  shows "(\<Sum>n. f n * 0 ^ n) = f 0"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   905
proof -
23278
375335bf619f clean up proofs of exp_zero, sin_zero, cos_zero
huffman
parents: 23255
diff changeset
   906
  have "(\<Sum>n = 0..<1. f n * 0 ^ n) = (\<Sum>n. f n * 0 ^ n)"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   907
    by (rule sums_unique [OF series_zero], simp add: power_0_left)
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
   908
  thus ?thesis unfolding One_nat_def by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   909
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   910
23278
375335bf619f clean up proofs of exp_zero, sin_zero, cos_zero
huffman
parents: 23255
diff changeset
   911
lemma exp_zero [simp]: "exp 0 = 1"
375335bf619f clean up proofs of exp_zero, sin_zero, cos_zero
huffman
parents: 23255
diff changeset
   912
unfolding exp_def by (simp add: scaleR_conv_of_real powser_zero)
375335bf619f clean up proofs of exp_zero, sin_zero, cos_zero
huffman
parents: 23255
diff changeset
   913
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   914
lemma setsum_cl_ivl_Suc2:
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   915
  "(\<Sum>i=m..Suc n. f i) = (if Suc n < m then 0 else f m + (\<Sum>i=m..n. f (Suc i)))"
28069
ba4de3022862 moved lemma into SetInterval where it belongs
nipkow
parents: 27483
diff changeset
   916
by (simp add: setsum_head_Suc setsum_shift_bounds_cl_Suc_ivl
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   917
         del: setsum_cl_ivl_Suc)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   918
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   919
lemma exp_series_add:
31017
2c227493ea56 stripped class recpower further
haftmann
parents: 30273
diff changeset
   920
  fixes x y :: "'a::{real_field}"
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   921
  defines S_def: "S \<equiv> \<lambda>x n. x ^ n /\<^sub>R real (fact n)"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   922
  shows "S (x + y) n = (\<Sum>i=0..n. S x i * S y (n - i))"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   923
proof (induct n)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   924
  case 0
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   925
  show ?case
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   926
    unfolding S_def by simp
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   927
next
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   928
  case (Suc n)
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   929
  have S_Suc: "\<And>x n. S x (Suc n) = (x * S x n) /\<^sub>R real (Suc n)"
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
   930
    unfolding S_def by (simp del: mult_Suc)
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   931
  hence times_S: "\<And>x n. x * S x n = real (Suc n) *\<^sub>R S x (Suc n)"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   932
    by simp
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   933
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   934
  have "real (Suc n) *\<^sub>R S (x + y) (Suc n) = (x + y) * S (x + y) n"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   935
    by (simp only: times_S)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   936
  also have "\<dots> = (x + y) * (\<Sum>i=0..n. S x i * S y (n-i))"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   937
    by (simp only: Suc)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   938
  also have "\<dots> = x * (\<Sum>i=0..n. S x i * S y (n-i))
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   939
                + y * (\<Sum>i=0..n. S x i * S y (n-i))"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   940
    by (rule left_distrib)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   941
  also have "\<dots> = (\<Sum>i=0..n. (x * S x i) * S y (n-i))
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   942
                + (\<Sum>i=0..n. S x i * (y * S y (n-i)))"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   943
    by (simp only: setsum_right_distrib mult_ac)
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   944
  also have "\<dots> = (\<Sum>i=0..n. real (Suc i) *\<^sub>R (S x (Suc i) * S y (n-i)))
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   945
                + (\<Sum>i=0..n. real (Suc n-i) *\<^sub>R (S x i * S y (Suc n-i)))"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   946
    by (simp add: times_S Suc_diff_le)
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   947
  also have "(\<Sum>i=0..n. real (Suc i) *\<^sub>R (S x (Suc i) * S y (n-i))) =
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   948
             (\<Sum>i=0..Suc n. real i *\<^sub>R (S x i * S y (Suc n-i)))"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   949
    by (subst setsum_cl_ivl_Suc2, simp)
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   950
  also have "(\<Sum>i=0..n. real (Suc n-i) *\<^sub>R (S x i * S y (Suc n-i))) =
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   951
             (\<Sum>i=0..Suc n. real (Suc n-i) *\<^sub>R (S x i * S y (Suc n-i)))"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   952
    by (subst setsum_cl_ivl_Suc, simp)
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   953
  also have "(\<Sum>i=0..Suc n. real i *\<^sub>R (S x i * S y (Suc n-i))) +
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   954
             (\<Sum>i=0..Suc n. real (Suc n-i) *\<^sub>R (S x i * S y (Suc n-i))) =
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   955
             (\<Sum>i=0..Suc n. real (Suc n) *\<^sub>R (S x i * S y (Suc n-i)))"
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   956
    by (simp only: setsum_addf [symmetric] scaleR_left_distrib [symmetric]
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   957
              real_of_nat_add [symmetric], simp)
25062
af5ef0d4d655 global class syntax
haftmann
parents: 23477
diff changeset
   958
  also have "\<dots> = real (Suc n) *\<^sub>R (\<Sum>i=0..Suc n. S x i * S y (Suc n-i))"
23127
56ee8105c002 simplify names of locale interpretations
huffman
parents: 23115
diff changeset
   959
    by (simp only: scaleR_right.setsum)
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   960
  finally show
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   961
    "S (x + y) (Suc n) = (\<Sum>i=0..Suc n. S x i * S y (Suc n - i))"
35216
7641e8d831d2 get rid of many duplicate simp rule warnings
huffman
parents: 35213
diff changeset
   962
    by (simp del: setsum_cl_ivl_Suc)
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   963
qed
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   964
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   965
lemma exp_add: "exp (x + y) = exp x * exp y"
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   966
unfolding exp_def
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   967
by (simp only: Cauchy_product summable_norm_exp exp_series_add)
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
   968
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   969
lemma mult_exp_exp: "exp x * exp y = exp (x + y)"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   970
by (rule exp_add [symmetric])
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   971
23241
5f12b40a95bf add lemma exp_of_real
huffman
parents: 23177
diff changeset
   972
lemma exp_of_real: "exp (of_real x) = of_real (exp x)"
5f12b40a95bf add lemma exp_of_real
huffman
parents: 23177
diff changeset
   973
unfolding exp_def
5f12b40a95bf add lemma exp_of_real
huffman
parents: 23177
diff changeset
   974
apply (subst of_real.suminf)
5f12b40a95bf add lemma exp_of_real
huffman
parents: 23177
diff changeset
   975
apply (rule summable_exp_generic)
5f12b40a95bf add lemma exp_of_real
huffman
parents: 23177
diff changeset
   976
apply (simp add: scaleR_conv_of_real)
5f12b40a95bf add lemma exp_of_real
huffman
parents: 23177
diff changeset
   977
done
5f12b40a95bf add lemma exp_of_real
huffman
parents: 23177
diff changeset
   978
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   979
lemma exp_not_eq_zero [simp]: "exp x \<noteq> 0"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   980
proof
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   981
  have "exp x * exp (- x) = 1" by (simp add: mult_exp_exp)
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   982
  also assume "exp x = 0"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   983
  finally show "False" by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   984
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   985
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   986
lemma exp_minus: "exp (- x) = inverse (exp x)"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   987
by (rule inverse_unique [symmetric], simp add: mult_exp_exp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   988
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   989
lemma exp_diff: "exp (x - y) = exp x / exp y"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   990
  unfolding diff_minus divide_inverse
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   991
  by (simp add: exp_add exp_minus)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
   992
29167
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
   993
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
   994
subsubsection {* Properties of the Exponential Function on Reals *}
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
   995
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
   996
text {* Comparisons of @{term "exp x"} with zero. *}
29167
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
   997
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
   998
text{*Proof: because every exponential can be seen as a square.*}
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
   999
lemma exp_ge_zero [simp]: "0 \<le> exp (x::real)"
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
  1000
proof -
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
  1001
  have "0 \<le> exp (x/2) * exp (x/2)" by simp
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
  1002
  thus ?thesis by (simp add: exp_add [symmetric])
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
  1003
qed
37a952bb9ebc rearranged subsections; cleaned up some proofs
huffman
parents: 29166
diff changeset
  1004
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
  1005
lemma exp_gt_zero [simp]: "0 < exp (x::real)"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1006
by (simp add: order_less_le)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1007
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1008
lemma not_exp_less_zero [simp]: "\<not> exp (x::real) < 0"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1009
by (simp add: not_less)
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1010
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1011
lemma not_exp_le_zero [simp]: "\<not> exp (x::real) \<le> 0"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1012
by (simp add: not_le)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1013
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
  1014
lemma abs_exp_cancel [simp]: "\<bar>exp x::real\<bar> = exp x"
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1015
by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1016
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1017
lemma exp_real_of_nat_mult: "exp(real n * x) = exp(x) ^ n"
15251
bb6f072c8d10 converted some induct_tac to induct
paulson
parents: 15241
diff changeset
  1018
apply (induct "n")
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1019
apply (auto simp add: real_of_nat_Suc right_distrib exp_add mult_commute)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1020
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1021
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1022
text {* Strict monotonicity of exponential. *}
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1023
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1024
lemma exp_ge_add_one_self_aux: "0 \<le> (x::real) ==> (1 + x) \<le> exp(x)"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1025
apply (drule order_le_imp_less_or_eq, auto)
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1026
apply (simp add: exp_def)
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  1027
apply (rule order_trans)
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1028
apply (rule_tac [2] n = 2 and f = "(%n. inverse (real (fact n)) * x ^ n)" in series_pos_le)
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1029
apply (auto intro: summable_exp simp add: numeral_2_eq_2 zero_le_mult_iff)
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1030
done
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1031
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1032
lemma exp_gt_one: "0 < (x::real) \<Longrightarrow> 1 < exp x"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1033
proof -
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1034
  assume x: "0 < x"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1035
  hence "1 < 1 + x" by simp
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1036
  also from x have "1 + x \<le> exp x"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1037
    by (simp add: exp_ge_add_one_self_aux)
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1038
  finally show ?thesis .
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1039
qed
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1040
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1041
lemma exp_less_mono:
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
  1042
  fixes x y :: real
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1043
  assumes "x < y" shows "exp x < exp y"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1044
proof -
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1045
  from `x < y` have "0 < y - x" by simp
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1046
  hence "1 < exp (y - x)" by (rule exp_gt_one)
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1047
  hence "1 < exp y / exp x" by (simp only: exp_diff)
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1048
  thus "exp x < exp y" by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1049
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1050
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
  1051
lemma exp_less_cancel: "exp (x::real) < exp y ==> x < y"
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1052
apply (simp add: linorder_not_le [symmetric])
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1053
apply (auto simp add: order_le_less exp_less_mono)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1054
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1055
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1056
lemma exp_less_cancel_iff [iff]: "exp (x::real) < exp y \<longleftrightarrow> x < y"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1057
by (auto intro: exp_less_mono exp_less_cancel)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1058
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1059
lemma exp_le_cancel_iff [iff]: "exp (x::real) \<le> exp y \<longleftrightarrow> x \<le> y"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1060
by (auto simp add: linorder_not_less [symmetric])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1061
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1062
lemma exp_inj_iff [iff]: "exp (x::real) = exp y \<longleftrightarrow> x = y"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1063
by (simp add: order_eq_iff)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1064
29170
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1065
text {* Comparisons of @{term "exp x"} with one. *}
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1066
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1067
lemma one_less_exp_iff [simp]: "1 < exp (x::real) \<longleftrightarrow> 0 < x"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1068
  using exp_less_cancel_iff [where x=0 and y=x] by simp
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1069
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1070
lemma exp_less_one_iff [simp]: "exp (x::real) < 1 \<longleftrightarrow> x < 0"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1071
  using exp_less_cancel_iff [where x=x and y=0] by simp
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1072
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1073
lemma one_le_exp_iff [simp]: "1 \<le> exp (x::real) \<longleftrightarrow> 0 \<le> x"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1074
  using exp_le_cancel_iff [where x=0 and y=x] by simp
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1075
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1076
lemma exp_le_one_iff [simp]: "exp (x::real) \<le> 1 \<longleftrightarrow> x \<le> 0"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1077
  using exp_le_cancel_iff [where x=x and y=0] by simp
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1078
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1079
lemma exp_eq_one_iff [simp]: "exp (x::real) = 1 \<longleftrightarrow> x = 0"
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1080
  using exp_inj_iff [where x=x and y=0] by simp
dad3933c88dd clean up lemmas about exp
huffman
parents: 29167
diff changeset
  1081
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
  1082
lemma lemma_exp_total: "1 \<le> y ==> \<exists>x. 0 \<le> x & x \<le> y - 1 & exp(x::real) = y"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1083
apply (rule IVT)
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1084
apply (auto intro: isCont_exp simp add: le_diff_eq)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1085
apply (subgoal_tac "1 + (y - 1) \<le> exp (y - 1)")
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1086
apply simp
17014
ad5ceb90877d renamed exp_ge_add_one_self to exp_ge_add_one_self_aux
avigad
parents: 16924
diff changeset
  1087
apply (rule exp_ge_add_one_self_aux, simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1088
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1089
23115
4615b2078592 generalized exp to work over any complete field; new proof of exp_add
huffman
parents: 23112
diff changeset
  1090
lemma exp_total: "0 < (y::real) ==> \<exists>x. exp x = y"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1091
apply (rule_tac x = 1 and y = y in linorder_cases)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1092
apply (drule order_less_imp_le [THEN lemma_exp_total])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1093
apply (rule_tac [2] x = 0 in exI)
36776
c137ae7673d3 remove a couple of redundant lemmas; simplify some proofs
huffman
parents: 35216
diff changeset
  1094
apply (frule_tac [3] one_less_inverse)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1095
apply (drule_tac [4] order_less_imp_le [THEN lemma_exp_total], auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1096
apply (rule_tac x = "-x" in exI)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1097
apply (simp add: exp_minus)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1098
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1099
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1100
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1101
subsection {* Natural Logarithm *}
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1102
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  1103
definition
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  1104
  ln :: "real => real" where
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  1105
  "ln x = (THE u. exp u = x)"
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  1106
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  1107
lemma ln_exp [simp]: "ln (exp x) = x"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1108
by (simp add: ln_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1109
22654
c2b6b5a9e136 new simp rule exp_ln; new standard proof of DERIV_exp_ln_one; changed imports
huffman
parents: 22653
diff changeset
  1110
lemma exp_ln [simp]: "0 < x \<Longrightarrow> exp (ln x) = x"
c2b6b5a9e136 new simp rule exp_ln; new standard proof of DERIV_exp_ln_one; changed imports
huffman
parents: 22653
diff changeset
  1111
by (auto dest: exp_total)
c2b6b5a9e136 new simp rule exp_ln; new standard proof of DERIV_exp_ln_one; changed imports
huffman
parents: 22653
diff changeset
  1112
29171
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1113
lemma exp_ln_iff [simp]: "exp (ln x) = x \<longleftrightarrow> 0 < x"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1114
apply (rule iffI)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1115
apply (erule subst, rule exp_gt_zero)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1116
apply (erule exp_ln)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1117
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1118
29171
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1119
lemma ln_unique: "exp y = x \<Longrightarrow> ln x = y"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1120
by (erule subst, rule ln_exp)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1121
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1122
lemma ln_one [simp]: "ln 1 = 0"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1123
by (rule ln_unique, simp)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1124
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1125
lemma ln_mult: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln (x * y) = ln x + ln y"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1126
by (rule ln_unique, simp add: exp_add)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1127
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1128
lemma ln_inverse: "0 < x \<Longrightarrow> ln (inverse x) = - ln x"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1129
by (rule ln_unique, simp add: exp_minus)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1130
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1131
lemma ln_div: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln (x / y) = ln x - ln y"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1132
by (rule ln_unique, simp add: exp_diff)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1133
29171
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1134
lemma ln_realpow: "0 < x \<Longrightarrow> ln (x ^ n) = real n * ln x"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1135
by (rule ln_unique, simp add: exp_real_of_nat_mult)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1136
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1137
lemma ln_less_cancel_iff [simp]: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln x < ln y \<longleftrightarrow> x < y"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1138
by (subst exp_less_cancel_iff [symmetric], simp)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1139
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1140
lemma ln_le_cancel_iff [simp]: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln x \<le> ln y \<longleftrightarrow> x \<le> y"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1141
by (simp add: linorder_not_less [symmetric])
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1142
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1143
lemma ln_inj_iff [simp]: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln x = ln y \<longleftrightarrow> x = y"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1144
by (simp add: order_eq_iff)
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1145
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1146
lemma ln_add_one_self_le_self [simp]: "0 \<le> x \<Longrightarrow> ln (1 + x) \<le> x"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1147
apply (rule exp_le_cancel_iff [THEN iffD1])
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1148
apply (simp add: exp_ge_add_one_self_aux)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1149
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1150
29171
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1151
lemma ln_less_self [simp]: "0 < x \<Longrightarrow> ln x < x"
5eff800a695f clean up lemmas about ln
huffman
parents: 29170
diff changeset
  1152
by (rule order_less_le_trans [where y="ln (1 + x)"]) simp_all
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1153
15234
ec91a90c604e simplification tweaks for better arithmetic reasoning
paulson
parents: 15229
diff changeset
  1154
lemma ln_ge_zero [simp]:
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1155
  assumes x: "1 \<le> x" shows "0 \<le> ln x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1156
proof -
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1157
  have "0 < x" using x by arith
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1158
  hence "exp 0 \<le> exp (ln x)"
22915
bb8a928a6bfa fix proofs
huffman
parents: 22722
diff changeset
  1159
    by (simp add: x)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1160
  thus ?thesis by (simp only: exp_le_cancel_iff)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1161
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1162
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1163
lemma ln_ge_zero_imp_ge_one:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1164
  assumes ln: "0 \<le> ln x"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1165
      and x:  "0 < x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1166
  shows "1 \<le> x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1167
proof -
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1168
  from ln have "ln 1 \<le> ln x" by simp
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1169
  thus ?thesis by (simp add: x del: ln_one)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1170
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1171
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1172
lemma ln_ge_zero_iff [simp]: "0 < x ==> (0 \<le> ln x) = (1 \<le> x)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1173
by (blast intro: ln_ge_zero ln_ge_zero_imp_ge_one)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1174
15234
ec91a90c604e simplification tweaks for better arithmetic reasoning
paulson
parents: 15229
diff changeset
  1175
lemma ln_less_zero_iff [simp]: "0 < x ==> (ln x < 0) = (x < 1)"
ec91a90c604e simplification tweaks for better arithmetic reasoning
paulson
parents: 15229
diff changeset
  1176
by (insert ln_ge_zero_iff [of x], arith)
ec91a90c604e simplification tweaks for better arithmetic reasoning
paulson
parents: 15229
diff changeset
  1177
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1178
lemma ln_gt_zero:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1179
  assumes x: "1 < x" shows "0 < ln x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1180
proof -
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1181
  have "0 < x" using x by arith
22915
bb8a928a6bfa fix proofs
huffman
parents: 22722
diff changeset
  1182
  hence "exp 0 < exp (ln x)" by (simp add: x)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1183
  thus ?thesis  by (simp only: exp_less_cancel_iff)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1184
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1185
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1186
lemma ln_gt_zero_imp_gt_one:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1187
  assumes ln: "0 < ln x"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1188
      and x:  "0 < x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1189
  shows "1 < x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1190
proof -
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1191
  from ln have "ln 1 < ln x" by simp
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1192
  thus ?thesis by (simp add: x del: ln_one)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1193
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1194
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1195
lemma ln_gt_zero_iff [simp]: "0 < x ==> (0 < ln x) = (1 < x)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1196
by (blast intro: ln_gt_zero ln_gt_zero_imp_gt_one)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1197
15234
ec91a90c604e simplification tweaks for better arithmetic reasoning
paulson
parents: 15229
diff changeset
  1198
lemma ln_eq_zero_iff [simp]: "0 < x ==> (ln x = 0) = (x = 1)"
ec91a90c604e simplification tweaks for better arithmetic reasoning
paulson
parents: 15229
diff changeset
  1199
by (insert ln_less_zero_iff [of x] ln_gt_zero_iff [of x], arith)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1200
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1201
lemma ln_less_zero: "[| 0 < x; x < 1 |] ==> ln x < 0"
15234
ec91a90c604e simplification tweaks for better arithmetic reasoning
paulson
parents: 15229
diff changeset
  1202
by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1203
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1204
lemma exp_ln_eq: "exp u = x ==> ln x = u"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1205
by auto
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1206
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1207
lemma isCont_ln: "0 < x \<Longrightarrow> isCont ln x"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1208
apply (subgoal_tac "isCont ln (exp (ln x))", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1209
apply (rule isCont_inverse_function [where f=exp], simp_all)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1210
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1211
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1212
lemma DERIV_ln: "0 < x \<Longrightarrow> DERIV ln x :> inverse x"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1213
apply (rule DERIV_inverse_function [where f=exp and a=0 and b="x+1"])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1214
apply (erule lemma_DERIV_subst [OF DERIV_exp exp_ln])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1215
apply (simp_all add: abs_if isCont_ln)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1216
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  1217
33667
958dc9f03611 A little rationalisation
paulson
parents: 33549
diff changeset
  1218
lemma DERIV_ln_divide: "0 < x ==> DERIV ln x :> 1 / x"
958dc9f03611 A little rationalisation
paulson
parents: 33549
diff changeset
  1219
  by (rule DERIV_ln[THEN DERIV_cong], simp, simp add: divide_inverse)
958dc9f03611 A little rationalisation
paulson
parents: 33549
diff changeset
  1220
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1221
lemma ln_series: assumes "0 < x" and "x < 2"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1222
  shows "ln x = (\<Sum> n. (-1)^n * (1 / real (n + 1)) * (x - 1)^(Suc n))" (is "ln x = suminf (?f (x - 1))")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1223
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1224
  let "?f' x n" = "(-1)^n * (x - 1)^n"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1225
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1226
  have "ln x - suminf (?f (x - 1)) = ln 1 - suminf (?f (1 - 1))"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1227
  proof (rule DERIV_isconst3[where x=x])
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1228
    fix x :: real assume "x \<in> {0 <..< 2}" hence "0 < x" and "x < 2" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1229
    have "norm (1 - x) < 1" using `0 < x` and `x < 2` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1230
    have "1 / x = 1 / (1 - (1 - x))" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1231
    also have "\<dots> = (\<Sum> n. (1 - x)^n)" using geometric_sums[OF `norm (1 - x) < 1`] by (rule sums_unique)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1232
    also have "\<dots> = suminf (?f' x)" unfolding power_mult_distrib[symmetric] by (rule arg_cong[where f=suminf], rule arg_cong[where f="op ^"], auto)
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  1233
    finally have "DERIV ln x :> suminf (?f' x)" using DERIV_ln[OF `0 < x`] unfolding divide_inverse by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1234
    moreover
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1235
    have repos: "\<And> h x :: real. h - 1 + x = h + x - 1" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1236
    have "DERIV (\<lambda>x. suminf (?f x)) (x - 1) :> (\<Sum>n. (-1)^n * (1 / real (n + 1)) * real (Suc n) * (x - 1) ^ n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1237
    proof (rule DERIV_power_series')
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1238
      show "x - 1 \<in> {- 1<..<1}" and "(0 :: real) < 1" using `0 < x` `x < 2` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1239
      { fix x :: real assume "x \<in> {- 1<..<1}" hence "norm (-x) < 1" by auto
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  1240
        show "summable (\<lambda>n. -1 ^ n * (1 / real (n + 1)) * real (Suc n) * x ^ n)"
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  1241
          unfolding One_nat_def
35216
7641e8d831d2 get rid of many duplicate simp rule warnings
huffman
parents: 35213
diff changeset
  1242
          by (auto simp add: power_mult_distrib[symmetric] summable_geometric[OF `norm (-x) < 1`])
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1243
      }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1244
    qed
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  1245
    hence "DERIV (\<lambda>x. suminf (?f x)) (x - 1) :> suminf (?f' x)" unfolding One_nat_def by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1246
    hence "DERIV (\<lambda>x. suminf (?f (x - 1))) x :> suminf (?f' x)" unfolding DERIV_iff repos .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1247
    ultimately have "DERIV (\<lambda>x. ln x - suminf (?f (x - 1))) x :> (suminf (?f' x) - suminf (?f' x))"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1248
      by (rule DERIV_diff)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1249
    thus "DERIV (\<lambda>x. ln x - suminf (?f (x - 1))) x :> 0" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1250
  qed (auto simp add: assms)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1251
  thus ?thesis by (auto simp add: suminf_zero)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1252
qed
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1253
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1254
subsection {* Sine and Cosine *}
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1255
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1256
definition
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1257
  sin_coeff :: "nat \<Rightarrow> real" where
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1258
  "sin_coeff = (\<lambda>n. if even n then 0 else -1 ^ ((n - Suc 0) div 2) / real (fact n))"
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1259
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1260
definition
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1261
  cos_coeff :: "nat \<Rightarrow> real" where
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1262
  "cos_coeff = (\<lambda>n. if even n then (-1 ^ (n div 2)) / real (fact n) else 0)"
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1263
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1264
definition
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1265
  sin :: "real => real" where
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1266
  "sin x = (\<Sum>n. sin_coeff n * x ^ n)"
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1267
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1268
definition
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1269
  cos :: "real => real" where
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1270
  "cos x = (\<Sum>n. cos_coeff n * x ^ n)"
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1272
lemma summable_sin: "summable (\<lambda>n. sin_coeff n * x ^ n)"
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1273
unfolding sin_coeff_def
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1274
apply (rule_tac g = "(%n. inverse (real (fact n)) * \<bar>x\<bar> ^ n)" in summable_comparison_test)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1275
apply (rule_tac [2] summable_exp)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1276
apply (rule_tac x = 0 in exI)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1277
apply (auto simp add: divide_inverse abs_mult power_abs [symmetric] zero_le_mult_iff)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1278
done
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1279
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1280
lemma summable_cos: "summable (\<lambda>n. cos_coeff n * x ^ n)"
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1281
unfolding cos_coeff_def
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1282
apply (rule_tac g = "(%n. inverse (real (fact n)) * \<bar>x\<bar> ^ n)" in summable_comparison_test)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1283
apply (rule_tac [2] summable_exp)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1284
apply (rule_tac x = 0 in exI)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1285
apply (auto simp add: divide_inverse abs_mult power_abs [symmetric] zero_le_mult_iff)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1286
done
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1287
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1288
lemma lemma_STAR_sin:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1289
     "(if even n then 0
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1290
       else -1 ^ ((n - Suc 0) div 2)/(real (fact n))) * 0 ^ n = 0"
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1291
by (induct "n", auto)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1292
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1293
lemma lemma_STAR_cos:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1294
     "0 < n -->
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1295
      -1 ^ (n div 2)/(real (fact n)) * 0 ^ n = 0"
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1296
by (induct "n", auto)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1297
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1298
lemma lemma_STAR_cos1:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1299
     "0 < n -->
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1300
      (-1) ^ (n div 2)/(real (fact n)) * 0 ^ n = 0"
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1301
by (induct "n", auto)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1302
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1303
lemma lemma_STAR_cos2:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1304
  "(\<Sum>n=1..<n. if even n then -1 ^ (n div 2)/(real (fact n)) *  0 ^ n
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1305
                         else 0) = 0"
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1306
apply (induct "n")
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1307
apply (case_tac [2] "n", auto)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1308
done
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1309
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1310
lemma sin_converges: "(\<lambda>n. sin_coeff n * x ^ n) sums sin(x)"
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1311
unfolding sin_def by (rule summable_sin [THEN summable_sums])
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1312
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1313
lemma cos_converges: "(\<lambda>n. cos_coeff n * x ^ n) sums cos(x)"
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1314
unfolding cos_def by (rule summable_cos [THEN summable_sums])
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1315
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1316
lemma sin_fdiffs: "diffs sin_coeff = cos_coeff"
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1317
unfolding sin_coeff_def cos_coeff_def
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1318
by (auto intro!: ext
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1319
         simp add: diffs_def divide_inverse real_of_nat_def of_nat_mult
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1320
         simp del: mult_Suc of_nat_Suc)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1321
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1322
lemma sin_fdiffs2: "diffs sin_coeff n = cos_coeff n"
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1323
by (simp only: sin_fdiffs)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1324
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1325
lemma cos_fdiffs: "diffs cos_coeff = (\<lambda>n. - sin_coeff n)"
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1326
unfolding sin_coeff_def cos_coeff_def
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1327
by (auto intro!: ext
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1328
         simp add: diffs_def divide_inverse odd_Suc_mult_two_ex real_of_nat_def of_nat_mult
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1329
         simp del: mult_Suc of_nat_Suc)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1330
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1331
lemma cos_fdiffs2: "diffs cos_coeff n = - sin_coeff n"
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1332
by (simp only: cos_fdiffs)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1333
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1334
text{*Now at last we can get the derivatives of exp, sin and cos*}
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1335
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1336
lemma lemma_sin_minus: "- sin x = (\<Sum>n. - (sin_coeff n * x ^ n))"
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1337
by (auto intro!: sums_unique sums_minus sin_converges)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1338
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1339
lemma lemma_sin_ext: "sin = (\<lambda>x. \<Sum>n. sin_coeff n * x ^ n)"
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1340
by (auto intro!: ext simp add: sin_def)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1341
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1342
lemma lemma_cos_ext: "cos = (\<lambda>x. \<Sum>n. cos_coeff n * x ^ n)"
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1343
by (auto intro!: ext simp add: cos_def)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1344
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1345
lemma DERIV_sin [simp]: "DERIV sin x :> cos(x)"
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1346
apply (simp add: cos_def)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1347
apply (subst lemma_sin_ext)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1348
apply (auto simp add: sin_fdiffs2 [symmetric])
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1349
apply (rule_tac K = "1 + \<bar>x\<bar>" in termdiffs)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1350
apply (auto intro: sin_converges cos_converges sums_summable intro!: sums_minus [THEN sums_summable] simp add: cos_fdiffs sin_fdiffs)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1351
done
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1352
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1353
lemma DERIV_cos [simp]: "DERIV cos x :> -sin(x)"
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1354
apply (subst lemma_cos_ext)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1355
apply (auto simp add: lemma_sin_minus cos_fdiffs2 [symmetric] minus_mult_left)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1356
apply (rule_tac K = "1 + \<bar>x\<bar>" in termdiffs)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1357
apply (auto intro: sin_converges cos_converges sums_summable intro!: sums_minus [THEN sums_summable] simp add: cos_fdiffs sin_fdiffs diffs_minus)
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1358
done
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1359
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1360
lemma isCont_sin [simp]: "isCont sin x"
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1361
by (rule DERIV_sin [THEN DERIV_isCont])
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1362
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1363
lemma isCont_cos [simp]: "isCont cos x"
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1364
by (rule DERIV_cos [THEN DERIV_isCont])
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1365
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1366
31880
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  1367
declare
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  1368
  DERIV_exp[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros]
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  1369
  DERIV_ln[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros]
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  1370
  DERIV_sin[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros]
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  1371
  DERIV_cos[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros]
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  1372
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1373
subsection {* Properties of Sine and Cosine *}
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1374
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1375
lemma sin_zero [simp]: "sin 0 = 0"
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1376
unfolding sin_def sin_coeff_def by (simp add: powser_zero)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1377
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1378
lemma cos_zero [simp]: "cos 0 = 1"
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1379
unfolding cos_def cos_coeff_def by (simp add: powser_zero)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1380
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1381
lemma DERIV_sin_sin_mult [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1382
     "DERIV (%x. sin(x)*sin(x)) x :> cos(x) * sin(x) + cos(x) * sin(x)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1383
by (rule DERIV_mult, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1384
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1385
lemma DERIV_sin_sin_mult2 [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1386
     "DERIV (%x. sin(x)*sin(x)) x :> 2 * cos(x) * sin(x)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1387
apply (cut_tac x = x in DERIV_sin_sin_mult)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1388
apply (auto simp add: mult_assoc)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1389
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1390
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1391
lemma DERIV_sin_realpow2 [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1392
     "DERIV (%x. (sin x)\<twosuperior>) x :> cos(x) * sin(x) + cos(x) * sin(x)"
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  1393
by (auto simp add: numeral_2_eq_2 mult_assoc [symmetric])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1394
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1395
lemma DERIV_sin_realpow2a [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1396
     "DERIV (%x. (sin x)\<twosuperior>) x :> 2 * cos(x) * sin(x)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1397
by (auto simp add: numeral_2_eq_2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1398
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1399
lemma DERIV_cos_cos_mult [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1400
     "DERIV (%x. cos(x)*cos(x)) x :> -sin(x) * cos(x) + -sin(x) * cos(x)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1401
by (rule DERIV_mult, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1402
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1403
lemma DERIV_cos_cos_mult2 [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1404
     "DERIV (%x. cos(x)*cos(x)) x :> -2 * cos(x) * sin(x)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1405
apply (cut_tac x = x in DERIV_cos_cos_mult)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1406
apply (auto simp add: mult_ac)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1407
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1408
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1409
lemma DERIV_cos_realpow2 [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1410
     "DERIV (%x. (cos x)\<twosuperior>) x :> -sin(x) * cos(x) + -sin(x) * cos(x)"
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  1411
by (auto simp add: numeral_2_eq_2 mult_assoc [symmetric])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1412
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1413
lemma DERIV_cos_realpow2a [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1414
     "DERIV (%x. (cos x)\<twosuperior>) x :> -2 * cos(x) * sin(x)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1415
by (auto simp add: numeral_2_eq_2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1416
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1417
lemma lemma_DERIV_subst: "[| DERIV f x :> D; D = E |] ==> DERIV f x :> E"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1418
by auto
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1419
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1420
lemma DERIV_cos_realpow2b: "DERIV (%x. (cos x)\<twosuperior>) x :> -(2 * cos(x) * sin(x))"
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  1421
  by (auto intro!: DERIV_intros)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1422
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1423
(* most useful *)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1424
lemma DERIV_cos_cos_mult3 [simp]:
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1425
     "DERIV (%x. cos(x)*cos(x)) x :> -(2 * cos(x) * sin(x))"
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  1426
  by (auto intro!: DERIV_intros)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1427
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1428
lemma DERIV_sin_circle_all:
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1429
     "\<forall>x. DERIV (%x. (sin x)\<twosuperior> + (cos x)\<twosuperior>) x :>
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1430
             (2*cos(x)*sin(x) - 2*cos(x)*sin(x))"
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  1431
  by (auto intro!: DERIV_intros)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1432
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1433
lemma DERIV_sin_circle_all_zero [simp]:
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1434
     "\<forall>x. DERIV (%x. (sin x)\<twosuperior> + (cos x)\<twosuperior>) x :> 0"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1435
by (cut_tac DERIV_sin_circle_all, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1436
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1437
lemma sin_cos_squared_add [simp]: "((sin x)\<twosuperior>) + ((cos x)\<twosuperior>) = 1"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1438
apply (cut_tac x = x and y = 0 in DERIV_sin_circle_all_zero [THEN DERIV_isconst_all])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1439
apply (auto simp add: numeral_2_eq_2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1440
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1441
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1442
lemma sin_cos_squared_add2 [simp]: "((cos x)\<twosuperior>) + ((sin x)\<twosuperior>) = 1"
23286
huffman
parents: 23278
diff changeset
  1443
apply (subst add_commute)
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
  1444
apply (rule sin_cos_squared_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1445
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1446
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1447
lemma sin_cos_squared_add3 [simp]: "cos x * cos x + sin x * sin x = 1"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1448
apply (cut_tac x = x in sin_cos_squared_add2)
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
  1449
apply (simp add: power2_eq_square)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1450
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1451
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1452
lemma sin_squared_eq: "(sin x)\<twosuperior> = 1 - (cos x)\<twosuperior>"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1453
apply (rule_tac a1 = "(cos x)\<twosuperior>" in add_right_cancel [THEN iffD1])
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
  1454
apply simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1455
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1456
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1457
lemma cos_squared_eq: "(cos x)\<twosuperior> = 1 - (sin x)\<twosuperior>"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1458
apply (rule_tac a1 = "(sin x)\<twosuperior>" in add_right_cancel [THEN iffD1])
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
  1459
apply simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1460
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1461
15081
32402f5624d1 abs notation
paulson
parents: 15079
diff changeset
  1462
lemma abs_sin_le_one [simp]: "\<bar>sin x\<bar> \<le> 1"
23097
f4779adcd1a2 simplify some proofs
huffman
parents: 23082
diff changeset
  1463
by (rule power2_le_imp_le, simp_all add: sin_squared_eq)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1464
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1465
lemma sin_ge_minus_one [simp]: "-1 \<le> sin x"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1466
apply (insert abs_sin_le_one [of x])
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1467
apply (simp add: abs_le_iff del: abs_sin_le_one)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1468
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1469
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1470
lemma sin_le_one [simp]: "sin x \<le> 1"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1471
apply (insert abs_sin_le_one [of x])
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1472
apply (simp add: abs_le_iff del: abs_sin_le_one)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1473
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1474
15081
32402f5624d1 abs notation
paulson
parents: 15079
diff changeset
  1475
lemma abs_cos_le_one [simp]: "\<bar>cos x\<bar> \<le> 1"
23097
f4779adcd1a2 simplify some proofs
huffman
parents: 23082
diff changeset
  1476
by (rule power2_le_imp_le, simp_all add: cos_squared_eq)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1477
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1478
lemma cos_ge_minus_one [simp]: "-1 \<le> cos x"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1479
apply (insert abs_cos_le_one [of x])
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1480
apply (simp add: abs_le_iff del: abs_cos_le_one)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1481
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1482
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1483
lemma cos_le_one [simp]: "cos x \<le> 1"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1484
apply (insert abs_cos_le_one [of x])
22998
97e1f9c2cc46 avoid using redundant lemmas from RealDef.thy
huffman
parents: 22978
diff changeset
  1485
apply (simp add: abs_le_iff del: abs_cos_le_one)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1486
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1487
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1488
lemma DERIV_fun_pow: "DERIV g x :> m ==>
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1489
      DERIV (%x. (g x) ^ n) x :> real n * (g x) ^ (n - 1) * m"
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  1490
unfolding One_nat_def
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1491
apply (rule lemma_DERIV_subst)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1492
apply (rule_tac f = "(%x. x ^ n)" in DERIV_chain2)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1493
apply (rule DERIV_pow, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1494
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1495
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1496
lemma DERIV_fun_exp:
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1497
     "DERIV g x :> m ==> DERIV (%x. exp(g x)) x :> exp(g x) * m"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1498
apply (rule lemma_DERIV_subst)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1499
apply (rule_tac f = exp in DERIV_chain2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1500
apply (rule DERIV_exp, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1501
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1502
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1503
lemma DERIV_fun_sin:
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1504
     "DERIV g x :> m ==> DERIV (%x. sin(g x)) x :> cos(g x) * m"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1505
apply (rule lemma_DERIV_subst)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1506
apply (rule_tac f = sin in DERIV_chain2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1507
apply (rule DERIV_sin, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1508
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1509
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1510
lemma DERIV_fun_cos:
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1511
     "DERIV g x :> m ==> DERIV (%x. cos(g x)) x :> -sin(g x) * m"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1512
apply (rule lemma_DERIV_subst)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1513
apply (rule_tac f = cos in DERIV_chain2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1514
apply (rule DERIV_cos, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1515
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1516
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1517
(* lemma *)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1518
lemma lemma_DERIV_sin_cos_add:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1519
     "\<forall>x.
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1520
         DERIV (%x. (sin (x + y) - (sin x * cos y + cos x * sin y)) ^ 2 +
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1521
               (cos (x + y) - (cos x * cos y - sin x * sin y)) ^ 2) x :> 0"
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  1522
  by (auto intro!: DERIV_intros simp add: algebra_simps)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1523
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1524
lemma sin_cos_add [simp]:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1525
     "(sin (x + y) - (sin x * cos y + cos x * sin y)) ^ 2 +
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1526
      (cos (x + y) - (cos x * cos y - sin x * sin y)) ^ 2 = 0"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1527
apply (cut_tac y = 0 and x = x and y7 = y
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1528
       in lemma_DERIV_sin_cos_add [THEN DERIV_isconst_all])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1529
apply (auto simp add: numeral_2_eq_2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1530
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1531
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1532
lemma sin_add: "sin (x + y) = sin x * cos y + cos x * sin y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1533
apply (cut_tac x = x and y = y in sin_cos_add)
22969
bf523cac9a05 tuned proofs
huffman
parents: 22960
diff changeset
  1534
apply (simp del: sin_cos_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1535
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1536
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1537
lemma cos_add: "cos (x + y) = cos x * cos y - sin x * sin y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1538
apply (cut_tac x = x and y = y in sin_cos_add)
22969
bf523cac9a05 tuned proofs
huffman
parents: 22960
diff changeset
  1539
apply (simp del: sin_cos_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1540
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1541
15085
5693a977a767 removed some [iff] declarations from RealDef.thy, concerning inequalities
paulson
parents: 15081
diff changeset
  1542
lemma lemma_DERIV_sin_cos_minus:
5693a977a767 removed some [iff] declarations from RealDef.thy, concerning inequalities
paulson
parents: 15081
diff changeset
  1543
    "\<forall>x. DERIV (%x. (sin(-x) + (sin x)) ^ 2 + (cos(-x) - (cos x)) ^ 2) x :> 0"
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  1544
  by (auto intro!: DERIV_intros simp add: algebra_simps)
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  1545
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1546
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1547
lemma sin_cos_minus:
15085
5693a977a767 removed some [iff] declarations from RealDef.thy, concerning inequalities
paulson
parents: 15081
diff changeset
  1548
    "(sin(-x) + (sin x)) ^ 2 + (cos(-x) - (cos x)) ^ 2 = 0"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1549
apply (cut_tac y = 0 and x = x
15085
5693a977a767 removed some [iff] declarations from RealDef.thy, concerning inequalities
paulson
parents: 15081
diff changeset
  1550
       in lemma_DERIV_sin_cos_minus [THEN DERIV_isconst_all])
22969
bf523cac9a05 tuned proofs
huffman
parents: 22960
diff changeset
  1551
apply simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1552
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1553
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1554
lemma sin_minus [simp]: "sin (-x) = -sin(x)"
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1555
  using sin_cos_minus [where x=x] by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1556
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1557
lemma cos_minus [simp]: "cos (-x) = cos(x)"
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1558
  using sin_cos_minus [where x=x] by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1559
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1560
lemma sin_diff: "sin (x - y) = sin x * cos y - cos x * sin y"
22969
bf523cac9a05 tuned proofs
huffman
parents: 22960
diff changeset
  1561
by (simp add: diff_minus sin_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1562
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1563
lemma sin_diff2: "sin (x - y) = cos y * sin x - sin y * cos x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1564
by (simp add: sin_diff mult_commute)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1565
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1566
lemma cos_diff: "cos (x - y) = cos x * cos y + sin x * sin y"
22969
bf523cac9a05 tuned proofs
huffman
parents: 22960
diff changeset
  1567
by (simp add: diff_minus cos_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1568
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1569
lemma cos_diff2: "cos (x - y) = cos y * cos x + sin y * sin x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1570
by (simp add: cos_diff mult_commute)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1571
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1572
lemma sin_double [simp]: "sin(2 * x) = 2* sin x * cos x"
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1573
  using sin_add [where x=x and y=x] by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1574
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1575
lemma cos_double: "cos(2* x) = ((cos x)\<twosuperior>) - ((sin x)\<twosuperior>)"
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1576
  using cos_add [where x=x and y=x]
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1577
  by (simp add: power2_eq_square)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1578
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1579
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  1580
subsection {* The Constant Pi *}
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1581
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  1582
definition
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  1583
  pi :: "real" where
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1584
  "pi = 2 * (THE x. 0 \<le> (x::real) & x \<le> 2 & cos x = 0)"
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  1585
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1586
text{*Show that there's a least positive @{term x} with @{term "cos(x) = 0"};
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1587
   hence define pi.*}
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1588
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1589
lemma sin_paired:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1590
     "(%n. -1 ^ n /(real (fact (2 * n + 1))) * x ^ (2 * n + 1))
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1591
      sums  sin x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1592
proof -
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1593
  have "(\<lambda>n. \<Sum>k = n * 2..<n * 2 + 2. sin_coeff k * x ^ k) sums sin x"
23176
40a760921d94 simplify some proofs
huffman
parents: 23127
diff changeset
  1594
    unfolding sin_def
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1595
    by (rule sin_converges [THEN sums_summable, THEN sums_group], simp)
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1596
  thus ?thesis unfolding One_nat_def sin_coeff_def by (simp add: mult_ac)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1597
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1598
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
  1599
text {* FIXME: This is a long, ugly proof! *}
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1600
lemma sin_gt_zero: "[|0 < x; x < 2 |] ==> 0 < sin x"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1601
apply (subgoal_tac
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1602
       "(\<lambda>n. \<Sum>k = n * 2..<n * 2 + 2.
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1603
              -1 ^ k / real (fact (2 * k + 1)) * x ^ (2 * k + 1))
23177
3004310c95b1 replace (- 1) with -1
huffman
parents: 23176
diff changeset
  1604
     sums (\<Sum>n. -1 ^ n / real (fact (2 * n + 1)) * x ^ (2 * n + 1))")
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1605
 prefer 2
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1606
 apply (rule sin_paired [THEN sums_summable, THEN sums_group], simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1607
apply (rotate_tac 2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1608
apply (drule sin_paired [THEN sums_unique, THEN ssubst])
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  1609
unfolding One_nat_def
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1610
apply (auto simp del: fact_Suc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1611
apply (frule sums_unique)
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1612
apply (auto simp del: fact_Suc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1613
apply (rule_tac n1 = 0 in series_pos_less [THEN [2] order_le_less_trans])
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1614
apply (auto simp del: fact_Suc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1615
apply (erule sums_summable)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1616
apply (case_tac "m=0")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1617
apply (simp (no_asm_simp))
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1618
apply (subgoal_tac "6 * (x * (x * x) / real (Suc (Suc (Suc (Suc (Suc (Suc 0))))))) < 6 * x")
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1619
apply (simp only: mult_less_cancel_left, simp)
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  1620
apply (simp (no_asm_simp) add: numeral_2_eq_2 [symmetric] mult_assoc [symmetric])
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1621
apply (subgoal_tac "x*x < 2*3", simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1622
apply (rule mult_strict_mono)
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1623
apply (auto simp add: real_0_less_add_iff real_of_nat_Suc simp del: fact_Suc)
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1624
apply (subst fact_Suc)
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1625
apply (subst fact_Suc)
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1626
apply (subst fact_Suc)
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1627
apply (subst fact_Suc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1628
apply (subst real_of_nat_mult)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1629
apply (subst real_of_nat_mult)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1630
apply (subst real_of_nat_mult)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1631
apply (subst real_of_nat_mult)
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1632
apply (simp (no_asm) add: divide_inverse del: fact_Suc)
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1633
apply (auto simp add: mult_assoc [symmetric] simp del: fact_Suc)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1634
apply (rule_tac c="real (Suc (Suc (4*m)))" in mult_less_imp_less_right)
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1635
apply (auto simp add: mult_assoc simp del: fact_Suc)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1636
apply (rule_tac c="real (Suc (Suc (Suc (4*m))))" in mult_less_imp_less_right)
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1637
apply (auto simp add: mult_assoc mult_less_cancel_left simp del: fact_Suc)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1638
apply (subgoal_tac "x * (x * x ^ (4*m)) = (x ^ (4*m)) * (x * x)")
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1639
apply (erule ssubst)+
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1640
apply (auto simp del: fact_Suc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1641
apply (subgoal_tac "0 < x ^ (4 * m) ")
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1642
 prefer 2 apply (simp only: zero_less_power)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1643
apply (simp (no_asm_simp) add: mult_less_cancel_left)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1644
apply (rule mult_strict_mono)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1645
apply (simp_all (no_asm_simp))
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1646
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1647
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1648
lemma sin_gt_zero1: "[|0 < x; x < 2 |] ==> 0 < sin x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1649
by (auto intro: sin_gt_zero)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1650
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1651
lemma cos_double_less_one: "[| 0 < x; x < 2 |] ==> cos (2 * x) < 1"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1652
apply (cut_tac x = x in sin_gt_zero1)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1653
apply (auto simp add: cos_squared_eq cos_double)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1654
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1655
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1656
lemma cos_paired:
23177
3004310c95b1 replace (- 1) with -1
huffman
parents: 23176
diff changeset
  1657
     "(%n. -1 ^ n /(real (fact (2 * n))) * x ^ (2 * n)) sums cos x"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1658
proof -
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1659
  have "(\<lambda>n. \<Sum>k = n * 2..<n * 2 + 2. cos_coeff k * x ^ k) sums cos x"
23176
40a760921d94 simplify some proofs
huffman
parents: 23127
diff changeset
  1660
    unfolding cos_def
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1661
    by (rule cos_converges [THEN sums_summable, THEN sums_group], simp)
31271
0237e5e40b71 add constants sin_coeff, cos_coeff
huffman
parents: 31148
diff changeset
  1662
  thus ?thesis unfolding cos_coeff_def by (simp add: mult_ac)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1663
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1664
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1665
lemma fact_lemma: "real (n::nat) * 4 = real (4 * n)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1666
by simp
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1667
36824
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1668
lemma real_mult_inverse_cancel:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1669
     "[|(0::real) < x; 0 < x1; x1 * y < x * u |]
36824
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1670
      ==> inverse x * y < inverse x1 * u"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1671
apply (rule_tac c=x in mult_less_imp_less_left)
36824
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1672
apply (auto simp add: mult_assoc [symmetric])
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1673
apply (simp (no_asm) add: mult_ac)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1674
apply (rule_tac c=x1 in mult_less_imp_less_right)
36824
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1675
apply (auto simp add: mult_ac)
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1676
done
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1677
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1678
lemma real_mult_inverse_cancel2:
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1679
     "[|(0::real) < x;0 < x1; x1 * y < x * u |] ==> y * inverse x < u * inverse x1"
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1680
apply (auto dest: real_mult_inverse_cancel simp add: mult_ac)
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1681
done
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1682
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1683
lemma realpow_num_eq_if:
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1684
  fixes m :: "'a::power"
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1685
  shows "m ^ n = (if n=0 then 1 else m * m ^ (n - 1))"
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1686
by (cases n, auto)
2e9a866141b8 move some theorems from RealPow.thy to Transcendental.thy
huffman
parents: 36777
diff changeset
  1687
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1688
lemma cos_two_less_zero [simp]: "cos (2) < 0"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1689
apply (cut_tac x = 2 in cos_paired)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1690
apply (drule sums_minus)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1691
apply (rule neg_less_iff_less [THEN iffD1])
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  1692
apply (frule sums_unique, auto)
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  1693
apply (rule_tac y =
23177
3004310c95b1 replace (- 1) with -1
huffman
parents: 23176
diff changeset
  1694
 "\<Sum>n=0..< Suc(Suc(Suc 0)). - (-1 ^ n / (real(fact (2*n))) * 2 ^ (2*n))"
15481
fc075ae929e4 the new subst tactic, by Lucas Dixon
paulson
parents: 15383
diff changeset
  1695
       in order_less_trans)
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1696
apply (simp (no_asm) add: fact_num_eq_if_nat realpow_num_eq_if del: fact_Suc)
15561
045a07ac35a7 another reorganization of setsums and intervals
nipkow
parents: 15546
diff changeset
  1697
apply (simp (no_asm) add: mult_assoc del: setsum_op_ivl_Suc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1698
apply (rule sumr_pos_lt_pair)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1699
apply (erule sums_summable, safe)
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  1700
unfolding One_nat_def
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1701
apply (simp (no_asm) add: divide_inverse real_0_less_add_iff mult_assoc [symmetric]
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1702
            del: fact_Suc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1703
apply (rule real_mult_inverse_cancel2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1704
apply (rule real_of_nat_fact_gt_zero)+
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1705
apply (simp (no_asm) add: mult_assoc [symmetric] del: fact_Suc)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1706
apply (subst fact_lemma)
32047
c141f139ce26 Changed fact_Suc_nat back to fact_Suc
avigad
parents: 32036
diff changeset
  1707
apply (subst fact_Suc [of "Suc (Suc (Suc (Suc (Suc (Suc (Suc (4 * d)))))))"])
15481
fc075ae929e4 the new subst tactic, by Lucas Dixon
paulson
parents: 15383
diff changeset
  1708
apply (simp only: real_of_nat_mult)
23007
e025695d9b0e use mult_strict_mono instead of real_mult_less_mono
huffman
parents: 22998
diff changeset
  1709
apply (rule mult_strict_mono, force)
27483
7c58324cd418 use real_of_nat_ge_zero instead of real_of_nat_fact_ge_zero
huffman
parents: 25875
diff changeset
  1710
  apply (rule_tac [3] real_of_nat_ge_zero)
15481
fc075ae929e4 the new subst tactic, by Lucas Dixon
paulson
parents: 15383
diff changeset
  1711
 prefer 2 apply force
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1712
apply (rule real_of_nat_less_iff [THEN iffD2])
32036
8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged.
avigad
parents: 31881
diff changeset
  1713
apply (rule fact_less_mono_nat, auto)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1714
done
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1715
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1716
lemmas cos_two_neq_zero [simp] = cos_two_less_zero [THEN less_imp_neq]
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1717
lemmas cos_two_le_zero [simp] = cos_two_less_zero [THEN order_less_imp_le]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1718
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1719
lemma cos_is_zero: "EX! x. 0 \<le> x & x \<le> 2 & cos x = 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1720
apply (subgoal_tac "\<exists>x. 0 \<le> x & x \<le> 2 & cos x = 0")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1721
apply (rule_tac [2] IVT2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1722
apply (auto intro: DERIV_isCont DERIV_cos)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1723
apply (cut_tac x = xa and y = y in linorder_less_linear)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1724
apply (rule ccontr)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1725
apply (subgoal_tac " (\<forall>x. cos differentiable x) & (\<forall>x. isCont cos x) ")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1726
apply (auto intro: DERIV_cos DERIV_isCont simp add: differentiable_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1727
apply (drule_tac f = cos in Rolle)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1728
apply (drule_tac [5] f = cos in Rolle)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1729
apply (auto dest!: DERIV_cos [THEN DERIV_unique] simp add: differentiable_def)
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  1730
apply (metis order_less_le_trans less_le sin_gt_zero)
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  1731
apply (metis order_less_le_trans less_le sin_gt_zero)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1732
done
31880
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  1733
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1734
lemma pi_half: "pi/2 = (THE x. 0 \<le> x & x \<le> 2 & cos x = 0)"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1735
by (simp add: pi_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1736
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1737
lemma cos_pi_half [simp]: "cos (pi / 2) = 0"
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1738
by (simp add: pi_half cos_is_zero [THEN theI'])
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1739
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1740
lemma pi_half_gt_zero [simp]: "0 < pi / 2"
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1741
apply (rule order_le_neq_trans)
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1742
apply (simp add: pi_half cos_is_zero [THEN theI'])
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1743
apply (rule notI, drule arg_cong [where f=cos], simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1744
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1745
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1746
lemmas pi_half_neq_zero [simp] = pi_half_gt_zero [THEN less_imp_neq, symmetric]
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1747
lemmas pi_half_ge_zero [simp] = pi_half_gt_zero [THEN order_less_imp_le]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1748
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1749
lemma pi_half_less_two [simp]: "pi / 2 < 2"
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1750
apply (rule order_le_neq_trans)
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1751
apply (simp add: pi_half cos_is_zero [THEN theI'])
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1752
apply (rule notI, drule arg_cong [where f=cos], simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1753
done
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1754
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1755
lemmas pi_half_neq_two [simp] = pi_half_less_two [THEN less_imp_neq]
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1756
lemmas pi_half_le_two [simp] =  pi_half_less_two [THEN order_less_imp_le]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1757
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1758
lemma pi_gt_zero [simp]: "0 < pi"
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1759
by (insert pi_half_gt_zero, simp)
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1760
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1761
lemma pi_ge_zero [simp]: "0 \<le> pi"
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1762
by (rule pi_gt_zero [THEN order_less_imp_le])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1763
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1764
lemma pi_neq_zero [simp]: "pi \<noteq> 0"
22998
97e1f9c2cc46 avoid using redundant lemmas from RealDef.thy
huffman
parents: 22978
diff changeset
  1765
by (rule pi_gt_zero [THEN less_imp_neq, THEN not_sym])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1766
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1767
lemma pi_not_less_zero [simp]: "\<not> pi < 0"
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1768
by (simp add: linorder_not_less)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1769
29165
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1770
lemma minus_pi_half_less_zero: "-(pi/2) < 0"
562f95f06244 cleaned up some proofs; removed redundant simp rules
huffman
parents: 29164
diff changeset
  1771
by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1772
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1773
lemma m2pi_less_pi: "- (2 * pi) < pi"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1774
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1775
  have "- (2 * pi) < 0" and "0 < pi" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1776
  from order_less_trans[OF this] show ?thesis .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1777
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1778
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1779
lemma sin_pi_half [simp]: "sin(pi/2) = 1"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1780
apply (cut_tac x = "pi/2" in sin_cos_squared_add2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1781
apply (cut_tac sin_gt_zero [OF pi_half_gt_zero pi_half_less_two])
36970
fb3fdb4b585e remove simp attribute from square_eq_1_iff
huffman
parents: 36842
diff changeset
  1782
apply (simp add: power2_eq_1_iff)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1783
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1784
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1785
lemma cos_pi [simp]: "cos pi = -1"
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  1786
by (cut_tac x = "pi/2" and y = "pi/2" in cos_add, simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1787
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1788
lemma sin_pi [simp]: "sin pi = 0"
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  1789
by (cut_tac x = "pi/2" and y = "pi/2" in sin_add, simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1790
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1791
lemma sin_cos_eq: "sin x = cos (pi/2 - x)"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1792
by (simp add: diff_minus cos_add)
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1793
declare sin_cos_eq [symmetric, simp]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1794
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1795
lemma minus_sin_cos_eq: "-sin x = cos (x + pi/2)"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1796
by (simp add: cos_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1797
declare minus_sin_cos_eq [symmetric, simp]
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1798
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1799
lemma cos_sin_eq: "cos x = sin (pi/2 - x)"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1800
by (simp add: diff_minus sin_add)
23053
03fe1dafa418 define pi with THE instead of SOME; cleaned up
huffman
parents: 23052
diff changeset
  1801
declare cos_sin_eq [symmetric, simp]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1802
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1803
lemma sin_periodic_pi [simp]: "sin (x + pi) = - sin x"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1804
by (simp add: sin_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1805
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1806
lemma sin_periodic_pi2 [simp]: "sin (pi + x) = - sin x"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1807
by (simp add: sin_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1808
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1809
lemma cos_periodic_pi [simp]: "cos (x + pi) = - cos x"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1810
by (simp add: cos_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1811
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1812
lemma sin_periodic [simp]: "sin (x + 2*pi) = sin x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1813
by (simp add: sin_add cos_double)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1814
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1815
lemma cos_periodic [simp]: "cos (x + 2*pi) = cos x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1816
by (simp add: cos_add cos_double)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1817
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1818
lemma cos_npi [simp]: "cos (real n * pi) = -1 ^ n"
15251
bb6f072c8d10 converted some induct_tac to induct
paulson
parents: 15241
diff changeset
  1819
apply (induct "n")
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1820
apply (auto simp add: real_of_nat_Suc left_distrib)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1821
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1822
15383
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  1823
lemma cos_npi2 [simp]: "cos (pi * real n) = -1 ^ n"
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  1824
proof -
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  1825
  have "cos (pi * real n) = cos (real n * pi)" by (simp only: mult_commute)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1826
  also have "... = -1 ^ n" by (rule cos_npi)
15383
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  1827
  finally show ?thesis .
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  1828
qed
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  1829
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1830
lemma sin_npi [simp]: "sin (real (n::nat) * pi) = 0"
15251
bb6f072c8d10 converted some induct_tac to induct
paulson
parents: 15241
diff changeset
  1831
apply (induct "n")
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1832
apply (auto simp add: real_of_nat_Suc left_distrib)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1833
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1834
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1835
lemma sin_npi2 [simp]: "sin (pi * real (n::nat)) = 0"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1836
by (simp add: mult_commute [of pi])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1837
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1838
lemma cos_two_pi [simp]: "cos (2 * pi) = 1"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1839
by (simp add: cos_double)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1840
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1841
lemma sin_two_pi [simp]: "sin (2 * pi) = 0"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1842
by simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1843
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1844
lemma sin_gt_zero2: "[| 0 < x; x < pi/2 |] ==> 0 < sin x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1845
apply (rule sin_gt_zero, assumption)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1846
apply (rule order_less_trans, assumption)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1847
apply (rule pi_half_less_two)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1848
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1849
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1850
lemma sin_less_zero:
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1851
  assumes lb: "- pi/2 < x" and "x < 0" shows "sin x < 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1852
proof -
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1853
  have "0 < sin (- x)" using assms by (simp only: sin_gt_zero2)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1854
  thus ?thesis by simp
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1855
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1856
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1857
lemma pi_less_4: "pi < 4"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1858
by (cut_tac pi_half_less_two, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1859
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1860
lemma cos_gt_zero: "[| 0 < x; x < pi/2 |] ==> 0 < cos x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1861
apply (cut_tac pi_less_4)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1862
apply (cut_tac f = cos and a = 0 and b = x and y = 0 in IVT2_objl, safe, simp_all)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1863
apply (cut_tac cos_is_zero, safe)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1864
apply (rename_tac y z)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1865
apply (drule_tac x = y in spec)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1866
apply (drule_tac x = "pi/2" in spec, simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1867
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1868
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1869
lemma cos_gt_zero_pi: "[| -(pi/2) < x; x < pi/2 |] ==> 0 < cos x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1870
apply (rule_tac x = x and y = 0 in linorder_cases)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1871
apply (rule cos_minus [THEN subst])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1872
apply (rule cos_gt_zero)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1873
apply (auto intro: cos_gt_zero)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1874
done
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1875
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1876
lemma cos_ge_zero: "[| -(pi/2) \<le> x; x \<le> pi/2 |] ==> 0 \<le> cos x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1877
apply (auto simp add: order_le_less cos_gt_zero_pi)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1878
apply (subgoal_tac "x = pi/2", auto)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1879
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1880
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1881
lemma sin_gt_zero_pi: "[| 0 < x; x < pi  |] ==> 0 < sin x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1882
apply (subst sin_cos_eq)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1883
apply (rotate_tac 1)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1884
apply (drule real_sum_of_halves [THEN ssubst])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1885
apply (auto intro!: cos_gt_zero_pi simp del: sin_cos_eq [symmetric])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1886
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1887
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1888
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1889
lemma pi_ge_two: "2 \<le> pi"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1890
proof (rule ccontr)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1891
  assume "\<not> 2 \<le> pi" hence "pi < 2" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1892
  have "\<exists>y > pi. y < 2 \<and> y < 2 * pi"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1893
  proof (cases "2 < 2 * pi")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1894
    case True with dense[OF `pi < 2`] show ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1895
  next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1896
    case False have "pi < 2 * pi" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1897
    from dense[OF this] and False show ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1898
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1899
  then obtain y where "pi < y" and "y < 2" and "y < 2 * pi" by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1900
  hence "0 < sin y" using sin_gt_zero by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1901
  moreover
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1902
  have "sin y < 0" using sin_gt_zero_pi[of "y - pi"] `pi < y` and `y < 2 * pi` sin_periodic_pi[of "y - pi"] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1903
  ultimately show False by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1904
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  1905
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1906
lemma sin_ge_zero: "[| 0 \<le> x; x \<le> pi |] ==> 0 \<le> sin x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1907
by (auto simp add: order_le_less sin_gt_zero_pi)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1908
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1909
lemma cos_total: "[| -1 \<le> y; y \<le> 1 |] ==> EX! x. 0 \<le> x & x \<le> pi & (cos x = y)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1910
apply (subgoal_tac "\<exists>x. 0 \<le> x & x \<le> pi & cos x = y")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1911
apply (rule_tac [2] IVT2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1912
apply (auto intro: order_less_imp_le DERIV_isCont DERIV_cos)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1913
apply (cut_tac x = xa and y = y in linorder_less_linear)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1914
apply (rule ccontr, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1915
apply (drule_tac f = cos in Rolle)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1916
apply (drule_tac [5] f = cos in Rolle)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1917
apply (auto intro: order_less_imp_le DERIV_isCont DERIV_cos
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1918
            dest!: DERIV_cos [THEN DERIV_unique]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1919
            simp add: differentiable_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1920
apply (auto dest: sin_gt_zero_pi [OF order_le_less_trans order_less_le_trans])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1921
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1922
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1923
lemma sin_total:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1924
     "[| -1 \<le> y; y \<le> 1 |] ==> EX! x. -(pi/2) \<le> x & x \<le> pi/2 & (sin x = y)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1925
apply (rule ccontr)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1926
apply (subgoal_tac "\<forall>x. (- (pi/2) \<le> x & x \<le> pi/2 & (sin x = y)) = (0 \<le> (x + pi/2) & (x + pi/2) \<le> pi & (cos (x + pi/2) = -y))")
18585
5d379fe2eb74 replaced swap by contrapos_np;
wenzelm
parents: 17318
diff changeset
  1927
apply (erule contrapos_np)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1928
apply (simp del: minus_sin_cos_eq [symmetric])
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1929
apply (cut_tac y="-y" in cos_total, simp) apply simp
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1930
apply (erule ex1E)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1931
apply (rule_tac a = "x - (pi/2)" in ex1I)
23286
huffman
parents: 23278
diff changeset
  1932
apply (simp (no_asm) add: add_assoc)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1933
apply (rotate_tac 3)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1934
apply (drule_tac x = "xa + pi/2" in spec, safe, simp_all)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1935
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1936
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1937
lemma reals_Archimedean4:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1938
     "[| 0 < y; 0 \<le> x |] ==> \<exists>n. real n * y \<le> x & x < real (Suc n) * y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1939
apply (auto dest!: reals_Archimedean3)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1940
apply (drule_tac x = x in spec, clarify)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1941
apply (subgoal_tac "x < real(LEAST m::nat. x < real m * y) * y")
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1942
 prefer 2 apply (erule LeastI)
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1943
apply (case_tac "LEAST m::nat. x < real m * y", simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1944
apply (subgoal_tac "~ x < real nat * y")
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1945
 prefer 2 apply (rule not_less_Least, simp, force)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1946
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1947
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1948
(* Pre Isabelle99-2 proof was simpler- numerals arithmetic
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1949
   now causes some unwanted re-arrangements of literals!   *)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1950
lemma cos_zero_lemma:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1951
     "[| 0 \<le> x; cos x = 0 |] ==>
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1952
      \<exists>n::nat. ~even n & x = real n * (pi/2)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1953
apply (drule pi_gt_zero [THEN reals_Archimedean4], safe)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1954
apply (subgoal_tac "0 \<le> x - real n * pi &
15086
e6a2a98d5ef5 removal of more iff-rules from RealDef.thy
paulson
parents: 15085
diff changeset
  1955
                    (x - real n * pi) \<le> pi & (cos (x - real n * pi) = 0) ")
29667
53103fc8ffa3 Replaced group_ and ring_simps by algebra_simps;
nipkow
parents: 29171
diff changeset
  1956
apply (auto simp add: algebra_simps real_of_nat_Suc)
53103fc8ffa3 Replaced group_ and ring_simps by algebra_simps;
nipkow
parents: 29171
diff changeset
  1957
 prefer 2 apply (simp add: cos_diff)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1958
apply (simp add: cos_diff)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1959
apply (subgoal_tac "EX! x. 0 \<le> x & x \<le> pi & cos x = 0")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1960
apply (rule_tac [2] cos_total, safe)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1961
apply (drule_tac x = "x - real n * pi" in spec)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1962
apply (drule_tac x = "pi/2" in spec)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1963
apply (simp add: cos_diff)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1964
apply (rule_tac x = "Suc (2 * n)" in exI)
29667
53103fc8ffa3 Replaced group_ and ring_simps by algebra_simps;
nipkow
parents: 29171
diff changeset
  1965
apply (simp add: real_of_nat_Suc algebra_simps, auto)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1966
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1967
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1968
lemma sin_zero_lemma:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1969
     "[| 0 \<le> x; sin x = 0 |] ==>
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1970
      \<exists>n::nat. even n & x = real n * (pi/2)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1971
apply (subgoal_tac "\<exists>n::nat. ~ even n & x + pi/2 = real n * (pi/2) ")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1972
 apply (clarify, rule_tac x = "n - 1" in exI)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1973
 apply (force simp add: odd_Suc_mult_two_ex real_of_nat_Suc left_distrib)
15085
5693a977a767 removed some [iff] declarations from RealDef.thy, concerning inequalities
paulson
parents: 15081
diff changeset
  1974
apply (rule cos_zero_lemma)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1975
apply (simp_all add: add_increasing)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1976
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1977
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1978
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1979
lemma cos_zero_iff:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1980
     "(cos x = 0) =
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1981
      ((\<exists>n::nat. ~even n & (x = real n * (pi/2))) |
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1982
       (\<exists>n::nat. ~even n & (x = -(real n * (pi/2)))))"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1983
apply (rule iffI)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1984
apply (cut_tac linorder_linear [of 0 x], safe)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1985
apply (drule cos_zero_lemma, assumption+)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1986
apply (cut_tac x="-x" in cos_zero_lemma, simp, simp)
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1987
apply (force simp add: minus_equation_iff [of x])
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1988
apply (auto simp only: odd_Suc_mult_two_ex real_of_nat_Suc left_distrib)
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  1989
apply (auto simp add: cos_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1990
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1991
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1992
(* ditto: but to a lesser extent *)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  1993
lemma sin_zero_iff:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1994
     "(sin x = 0) =
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  1995
      ((\<exists>n::nat. even n & (x = real n * (pi/2))) |
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1996
       (\<exists>n::nat. even n & (x = -(real n * (pi/2)))))"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1997
apply (rule iffI)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1998
apply (cut_tac linorder_linear [of 0 x], safe)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  1999
apply (drule sin_zero_lemma, assumption+)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2000
apply (cut_tac x="-x" in sin_zero_lemma, simp, simp, safe)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2001
apply (force simp add: minus_equation_iff [of x])
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  2002
apply (auto simp add: even_mult_two_ex)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2003
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2004
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2005
lemma cos_monotone_0_pi: assumes "0 \<le> y" and "y < x" and "x \<le> pi"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2006
  shows "cos x < cos y"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2007
proof -
33549
39f2855ce41b tuned proofs;
wenzelm
parents: 32960
diff changeset
  2008
  have "- (x - y) < 0" using assms by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2009
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2010
  from MVT2[OF `y < x` DERIV_cos[THEN impI, THEN allI]]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2011
  obtain z where "y < z" and "z < x" and cos_diff: "cos x - cos y = (x - y) * - sin z" by auto
33549
39f2855ce41b tuned proofs;
wenzelm
parents: 32960
diff changeset
  2012
  hence "0 < z" and "z < pi" using assms by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2013
  hence "0 < sin z" using sin_gt_zero_pi by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2014
  hence "cos x - cos y < 0" unfolding cos_diff minus_mult_commute[symmetric] using `- (x - y) < 0` by (rule mult_pos_neg2)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2015
  thus ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2016
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2017
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2018
lemma cos_monotone_0_pi': assumes "0 \<le> y" and "y \<le> x" and "x \<le> pi" shows "cos x \<le> cos y"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2019
proof (cases "y < x")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2020
  case True show ?thesis using cos_monotone_0_pi[OF `0 \<le> y` True `x \<le> pi`] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2021
next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2022
  case False hence "y = x" using `y \<le> x` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2023
  thus ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2024
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2025
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2026
lemma cos_monotone_minus_pi_0: assumes "-pi \<le> y" and "y < x" and "x \<le> 0"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2027
  shows "cos y < cos x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2028
proof -
33549
39f2855ce41b tuned proofs;
wenzelm
parents: 32960
diff changeset
  2029
  have "0 \<le> -x" and "-x < -y" and "-y \<le> pi" using assms by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2030
  from cos_monotone_0_pi[OF this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2031
  show ?thesis unfolding cos_minus .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2032
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2033
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2034
lemma cos_monotone_minus_pi_0': assumes "-pi \<le> y" and "y \<le> x" and "x \<le> 0" shows "cos y \<le> cos x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2035
proof (cases "y < x")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2036
  case True show ?thesis using cos_monotone_minus_pi_0[OF `-pi \<le> y` True `x \<le> 0`] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2037
next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2038
  case False hence "y = x" using `y \<le> x` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2039
  thus ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2040
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2041
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2042
lemma sin_monotone_2pi': assumes "- (pi / 2) \<le> y" and "y \<le> x" and "x \<le> pi / 2" shows "sin y \<le> sin x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2043
proof -
33549
39f2855ce41b tuned proofs;
wenzelm
parents: 32960
diff changeset
  2044
  have "0 \<le> y + pi / 2" and "y + pi / 2 \<le> x + pi / 2" and "x + pi /2 \<le> pi"
39f2855ce41b tuned proofs;
wenzelm
parents: 32960
diff changeset
  2045
    using pi_ge_two and assms by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2046
  from cos_monotone_0_pi'[OF this] show ?thesis unfolding minus_sin_cos_eq[symmetric] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2047
qed
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2048
29164
0d49c5b55046 move sin and cos to their own subsection
huffman
parents: 29163
diff changeset
  2049
subsection {* Tangent *}
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2050
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2051
definition
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2052
  tan :: "real => real" where
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2053
  "tan x = (sin x)/(cos x)"
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2054
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2055
lemma tan_zero [simp]: "tan 0 = 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2056
by (simp add: tan_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2057
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2058
lemma tan_pi [simp]: "tan pi = 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2059
by (simp add: tan_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2060
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2061
lemma tan_npi [simp]: "tan (real (n::nat) * pi) = 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2062
by (simp add: tan_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2063
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2064
lemma tan_minus [simp]: "tan (-x) = - tan x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2065
by (simp add: tan_def minus_mult_left)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2066
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2067
lemma tan_periodic [simp]: "tan (x + 2*pi) = tan x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2068
by (simp add: tan_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2069
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2070
lemma lemma_tan_add1:
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2071
      "[| cos x \<noteq> 0; cos y \<noteq> 0 |]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2072
        ==> 1 - tan(x)*tan(y) = cos (x + y)/(cos x * cos y)"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2073
apply (simp add: tan_def divide_inverse)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2074
apply (auto simp del: inverse_mult_distrib
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2075
            simp add: inverse_mult_distrib [symmetric] mult_ac)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2076
apply (rule_tac c1 = "cos x * cos y" in real_mult_right_cancel [THEN subst])
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2077
apply (auto simp del: inverse_mult_distrib
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2078
            simp add: mult_assoc left_diff_distrib cos_add)
29667
53103fc8ffa3 Replaced group_ and ring_simps by algebra_simps;
nipkow
parents: 29171
diff changeset
  2079
done
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2080
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2081
lemma add_tan_eq:
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2082
      "[| cos x \<noteq> 0; cos y \<noteq> 0 |]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2083
       ==> tan x + tan y = sin(x + y)/(cos x * cos y)"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2084
apply (simp add: tan_def)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2085
apply (rule_tac c1 = "cos x * cos y" in real_mult_right_cancel [THEN subst])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2086
apply (auto simp add: mult_assoc left_distrib)
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  2087
apply (simp add: sin_add)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2088
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2089
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2090
lemma tan_add:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2091
     "[| cos x \<noteq> 0; cos y \<noteq> 0; cos (x + y) \<noteq> 0 |]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2092
      ==> tan(x + y) = (tan(x) + tan(y))/(1 - tan(x) * tan(y))"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2093
apply (simp (no_asm_simp) add: add_tan_eq lemma_tan_add1)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2094
apply (simp add: tan_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2095
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2096
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2097
lemma tan_double:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2098
     "[| cos x \<noteq> 0; cos (2 * x) \<noteq> 0 |]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2099
      ==> tan (2 * x) = (2 * tan x)/(1 - (tan(x) ^ 2))"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2100
apply (insert tan_add [of x x])
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2101
apply (simp add: mult_2 [symmetric])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2102
apply (auto simp add: numeral_2_eq_2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2103
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2104
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2105
lemma tan_gt_zero: "[| 0 < x; x < pi/2 |] ==> 0 < tan x"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2106
by (simp add: tan_def zero_less_divide_iff sin_gt_zero2 cos_gt_zero_pi)
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2107
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2108
lemma tan_less_zero:
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2109
  assumes lb: "- pi/2 < x" and "x < 0" shows "tan x < 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2110
proof -
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2111
  have "0 < tan (- x)" using assms by (simp only: tan_gt_zero)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2112
  thus ?thesis by simp
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2113
qed
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2114
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2115
lemma tan_half: fixes x :: real assumes "- (pi / 2) < x" and "x < pi / 2"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2116
  shows "tan x = sin (2 * x) / (cos (2 * x) + 1)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2117
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2118
  from cos_gt_zero_pi[OF `- (pi / 2) < x` `x < pi / 2`]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2119
  have "cos x \<noteq> 0" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2120
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2121
  have minus_cos_2x: "\<And>X. X - cos (2*x) = X - (cos x) ^ 2 + (sin x) ^ 2" unfolding cos_double by algebra
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2122
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2123
  have "tan x = (tan x + tan x) / 2" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2124
  also have "\<dots> = sin (x + x) / (cos x * cos x) / 2" unfolding add_tan_eq[OF `cos x \<noteq> 0` `cos x \<noteq> 0`] ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2125
  also have "\<dots> = sin (2 * x) / ((cos x) ^ 2 + (cos x) ^ 2 + cos (2*x) - cos (2*x))" unfolding divide_divide_eq_left numeral_2_eq_2 by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2126
  also have "\<dots> = sin (2 * x) / ((cos x) ^ 2 + cos (2*x) + (sin x)^2)" unfolding minus_cos_2x by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2127
  also have "\<dots> = sin (2 * x) / (cos (2*x) + 1)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2128
  finally show ?thesis .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2129
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2130
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2131
lemma lemma_DERIV_tan:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2132
     "cos x \<noteq> 0 ==> DERIV (%x. sin(x)/cos(x)) x :> inverse((cos x)\<twosuperior>)"
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  2133
  by (auto intro!: DERIV_intros simp add: field_simps numeral_2_eq_2)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2134
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2135
lemma DERIV_tan [simp]: "cos x \<noteq> 0 ==> DERIV tan x :> inverse((cos x)\<twosuperior>)"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2136
by (auto dest: lemma_DERIV_tan simp add: tan_def [symmetric])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2137
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2138
lemma isCont_tan [simp]: "cos x \<noteq> 0 ==> isCont tan x"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2139
by (rule DERIV_tan [THEN DERIV_isCont])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2140
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2141
lemma LIM_cos_div_sin [simp]: "(%x. cos(x)/sin(x)) -- pi/2 --> 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2142
apply (subgoal_tac "(\<lambda>x. cos x * inverse (sin x)) -- pi * inverse 2 --> 0*1")
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2143
apply (simp add: divide_inverse [symmetric])
22613
2f119f54d150 remove redundant lemmas
huffman
parents: 21404
diff changeset
  2144
apply (rule LIM_mult)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2145
apply (rule_tac [2] inverse_1 [THEN subst])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2146
apply (rule_tac [2] LIM_inverse)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2147
apply (simp_all add: divide_inverse [symmetric])
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2148
apply (simp_all only: isCont_def [symmetric] cos_pi_half [symmetric] sin_pi_half [symmetric])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2149
apply (blast intro!: DERIV_isCont DERIV_sin DERIV_cos)+
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2150
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2151
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2152
lemma lemma_tan_total: "0 < y ==> \<exists>x. 0 < x & x < pi/2 & y < tan x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2153
apply (cut_tac LIM_cos_div_sin)
31338
d41a8ba25b67 generalize constants from Lim.thy to class metric_space
huffman
parents: 31271
diff changeset
  2154
apply (simp only: LIM_eq)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2155
apply (drule_tac x = "inverse y" in spec, safe, force)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2156
apply (drule_tac ?d1.0 = s in pi_half_gt_zero [THEN [2] real_lbound_gt_zero], safe)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2157
apply (rule_tac x = "(pi/2) - e" in exI)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2158
apply (simp (no_asm_simp))
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2159
apply (drule_tac x = "(pi/2) - e" in spec)
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2160
apply (auto simp add: tan_def)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2161
apply (rule inverse_less_iff_less [THEN iffD1])
15079
2ef899e4526d conversion of Hyperreal/MacLaurin_lemmas to Isar script
paulson
parents: 15077
diff changeset
  2162
apply (auto simp add: divide_inverse)
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  2163
apply (rule mult_pos_pos)
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2164
apply (subgoal_tac [3] "0 < sin e & 0 < cos e")
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  2165
apply (auto intro: cos_gt_zero sin_gt_zero2 simp add: mult_commute)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2166
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2167
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2168
lemma tan_total_pos: "0 \<le> y ==> \<exists>x. 0 \<le> x & x < pi/2 & tan x = y"
22998
97e1f9c2cc46 avoid using redundant lemmas from RealDef.thy
huffman
parents: 22978
diff changeset
  2169
apply (frule order_le_imp_less_or_eq, safe)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2170
 prefer 2 apply force
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2171
apply (drule lemma_tan_total, safe)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2172
apply (cut_tac f = tan and a = 0 and b = x and y = y in IVT_objl)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2173
apply (auto intro!: DERIV_tan [THEN DERIV_isCont])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2174
apply (drule_tac y = xa in order_le_imp_less_or_eq)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2175
apply (auto dest: cos_gt_zero)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2176
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2177
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2178
lemma lemma_tan_total1: "\<exists>x. -(pi/2) < x & x < (pi/2) & tan x = y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2179
apply (cut_tac linorder_linear [of 0 y], safe)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2180
apply (drule tan_total_pos)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2181
apply (cut_tac [2] y="-y" in tan_total_pos, safe)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2182
apply (rule_tac [3] x = "-x" in exI)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2183
apply (auto intro!: exI)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2184
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2185
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2186
lemma tan_total: "EX! x. -(pi/2) < x & x < (pi/2) & tan x = y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2187
apply (cut_tac y = y in lemma_tan_total1, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2188
apply (cut_tac x = xa and y = y in linorder_less_linear, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2189
apply (subgoal_tac [2] "\<exists>z. y < z & z < xa & DERIV tan z :> 0")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2190
apply (subgoal_tac "\<exists>z. xa < z & z < y & DERIV tan z :> 0")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2191
apply (rule_tac [4] Rolle)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2192
apply (rule_tac [2] Rolle)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2193
apply (auto intro!: DERIV_tan DERIV_isCont exI
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2194
            simp add: differentiable_def)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2195
txt{*Now, simulate TRYALL*}
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2196
apply (rule_tac [!] DERIV_tan asm_rl)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2197
apply (auto dest!: DERIV_unique [OF _ DERIV_tan]
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2198
            simp add: cos_gt_zero_pi [THEN less_imp_neq, THEN not_sym])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2199
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2200
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2201
lemma tan_monotone: assumes "- (pi / 2) < y" and "y < x" and "x < pi / 2"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2202
  shows "tan y < tan x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2203
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2204
  have "\<forall> x'. y \<le> x' \<and> x' \<le> x \<longrightarrow> DERIV tan x' :> inverse (cos x'^2)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2205
  proof (rule allI, rule impI)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2206
    fix x' :: real assume "y \<le> x' \<and> x' \<le> x"
33549
39f2855ce41b tuned proofs;
wenzelm
parents: 32960
diff changeset
  2207
    hence "-(pi/2) < x'" and "x' < pi/2" using assms by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2208
    from cos_gt_zero_pi[OF this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2209
    have "cos x' \<noteq> 0" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2210
    thus "DERIV tan x' :> inverse (cos x'^2)" by (rule DERIV_tan)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2211
  qed
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2212
  from MVT2[OF `y < x` this]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2213
  obtain z where "y < z" and "z < x" and tan_diff: "tan x - tan y = (x - y) * inverse ((cos z)\<twosuperior>)" by auto
33549
39f2855ce41b tuned proofs;
wenzelm
parents: 32960
diff changeset
  2214
  hence "- (pi / 2) < z" and "z < pi / 2" using assms by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2215
  hence "0 < cos z" using cos_gt_zero_pi by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2216
  hence inv_pos: "0 < inverse ((cos z)\<twosuperior>)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2217
  have "0 < x - y" using `y < x` by auto
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  2218
  from mult_pos_pos [OF this inv_pos]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2219
  have "0 < tan x - tan y" unfolding tan_diff by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2220
  thus ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2221
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2222
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2223
lemma tan_monotone': assumes "- (pi / 2) < y" and "y < pi / 2" and "- (pi / 2) < x" and "x < pi / 2"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2224
  shows "(y < x) = (tan y < tan x)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2225
proof
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2226
  assume "y < x" thus "tan y < tan x" using tan_monotone and `- (pi / 2) < y` and `x < pi / 2` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2227
next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2228
  assume "tan y < tan x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2229
  show "y < x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2230
  proof (rule ccontr)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2231
    assume "\<not> y < x" hence "x \<le> y" by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2232
    hence "tan x \<le> tan y"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2233
    proof (cases "x = y")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2234
      case True thus ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2235
    next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2236
      case False hence "x < y" using `x \<le> y` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2237
      from tan_monotone[OF `- (pi/2) < x` this `y < pi / 2`] show ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2238
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2239
    thus False using `tan y < tan x` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2240
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2241
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2242
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2243
lemma tan_inverse: "1 / (tan y) = tan (pi / 2 - y)" unfolding tan_def sin_cos_eq[of y] cos_sin_eq[of y] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2244
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2245
lemma tan_periodic_pi[simp]: "tan (x + pi) = tan x"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2246
  by (simp add: tan_def)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2247
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2248
lemma tan_periodic_nat[simp]: fixes n :: nat shows "tan (x + real n * pi) = tan x"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2249
proof (induct n arbitrary: x)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2250
  case (Suc n)
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  2251
  have split_pi_off: "x + real (Suc n) * pi = (x + real n * pi) + pi" unfolding Suc_eq_plus1 real_of_nat_add real_of_one left_distrib by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2252
  show ?case unfolding split_pi_off using Suc by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2253
qed auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2254
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2255
lemma tan_periodic_int[simp]: fixes i :: int shows "tan (x + real i * pi) = tan x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2256
proof (cases "0 \<le> i")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2257
  case True hence i_nat: "real i = real (nat i)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2258
  show ?thesis unfolding i_nat by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2259
next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2260
  case False hence i_nat: "real i = - real (nat (-i))" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2261
  have "tan x = tan (x + real i * pi - real i * pi)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2262
  also have "\<dots> = tan (x + real i * pi)" unfolding i_nat mult_minus_left diff_minus_eq_add by (rule tan_periodic_nat)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2263
  finally show ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2264
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2265
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2266
lemma tan_periodic_n[simp]: "tan (x + number_of n * pi) = tan x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2267
  using tan_periodic_int[of _ "number_of n" ] unfolding real_number_of .
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2268
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2269
subsection {* Inverse Trigonometric Functions *}
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2270
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2271
definition
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2272
  arcsin :: "real => real" where
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2273
  "arcsin y = (THE x. -(pi/2) \<le> x & x \<le> pi/2 & sin x = y)"
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2274
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2275
definition
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2276
  arccos :: "real => real" where
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2277
  "arccos y = (THE x. 0 \<le> x & x \<le> pi & cos x = y)"
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2278
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2279
definition
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2280
  arctan :: "real => real" where
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2281
  "arctan y = (THE x. -(pi/2) < x & x < pi/2 & tan x = y)"
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2282
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2283
lemma arcsin:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2284
     "[| -1 \<le> y; y \<le> 1 |]
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2285
      ==> -(pi/2) \<le> arcsin y &
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2286
           arcsin y \<le> pi/2 & sin(arcsin y) = y"
23011
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2287
unfolding arcsin_def by (rule theI' [OF sin_total])
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2288
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2289
lemma arcsin_pi:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2290
     "[| -1 \<le> y; y \<le> 1 |]
23011
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2291
      ==> -(pi/2) \<le> arcsin y & arcsin y \<le> pi & sin(arcsin y) = y"
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2292
apply (drule (1) arcsin)
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2293
apply (force intro: order_trans)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2294
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2295
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2296
lemma sin_arcsin [simp]: "[| -1 \<le> y; y \<le> 1 |] ==> sin(arcsin y) = y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2297
by (blast dest: arcsin)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2298
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2299
lemma arcsin_bounded:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2300
     "[| -1 \<le> y; y \<le> 1 |] ==> -(pi/2) \<le> arcsin y & arcsin y \<le> pi/2"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2301
by (blast dest: arcsin)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2302
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2303
lemma arcsin_lbound: "[| -1 \<le> y; y \<le> 1 |] ==> -(pi/2) \<le> arcsin y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2304
by (blast dest: arcsin)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2305
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2306
lemma arcsin_ubound: "[| -1 \<le> y; y \<le> 1 |] ==> arcsin y \<le> pi/2"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2307
by (blast dest: arcsin)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2308
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2309
lemma arcsin_lt_bounded:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2310
     "[| -1 < y; y < 1 |] ==> -(pi/2) < arcsin y & arcsin y < pi/2"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2311
apply (frule order_less_imp_le)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2312
apply (frule_tac y = y in order_less_imp_le)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2313
apply (frule arcsin_bounded)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2314
apply (safe, simp)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2315
apply (drule_tac y = "arcsin y" in order_le_imp_less_or_eq)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2316
apply (drule_tac [2] y = "pi/2" in order_le_imp_less_or_eq, safe)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2317
apply (drule_tac [!] f = sin in arg_cong, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2318
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2319
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2320
lemma arcsin_sin: "[|-(pi/2) \<le> x; x \<le> pi/2 |] ==> arcsin(sin x) = x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2321
apply (unfold arcsin_def)
23011
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2322
apply (rule the1_equality)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2323
apply (rule sin_total, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2324
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2325
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2326
lemma arccos:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2327
     "[| -1 \<le> y; y \<le> 1 |]
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2328
      ==> 0 \<le> arccos y & arccos y \<le> pi & cos(arccos y) = y"
23011
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2329
unfolding arccos_def by (rule theI' [OF cos_total])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2330
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2331
lemma cos_arccos [simp]: "[| -1 \<le> y; y \<le> 1 |] ==> cos(arccos y) = y"
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2332
by (blast dest: arccos)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2333
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2334
lemma arccos_bounded: "[| -1 \<le> y; y \<le> 1 |] ==> 0 \<le> arccos y & arccos y \<le> pi"
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2335
by (blast dest: arccos)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2336
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2337
lemma arccos_lbound: "[| -1 \<le> y; y \<le> 1 |] ==> 0 \<le> arccos y"
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2338
by (blast dest: arccos)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2339
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2340
lemma arccos_ubound: "[| -1 \<le> y; y \<le> 1 |] ==> arccos y \<le> pi"
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2341
by (blast dest: arccos)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2342
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2343
lemma arccos_lt_bounded:
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2344
     "[| -1 < y; y < 1 |]
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2345
      ==> 0 < arccos y & arccos y < pi"
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2346
apply (frule order_less_imp_le)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2347
apply (frule_tac y = y in order_less_imp_le)
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2348
apply (frule arccos_bounded, auto)
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2349
apply (drule_tac y = "arccos y" in order_le_imp_less_or_eq)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2350
apply (drule_tac [2] y = pi in order_le_imp_less_or_eq, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2351
apply (drule_tac [!] f = cos in arg_cong, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2352
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2353
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2354
lemma arccos_cos: "[|0 \<le> x; x \<le> pi |] ==> arccos(cos x) = x"
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2355
apply (simp add: arccos_def)
23011
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2356
apply (auto intro!: the1_equality cos_total)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2357
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2358
22975
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2359
lemma arccos_cos2: "[|x \<le> 0; -pi \<le> x |] ==> arccos(cos x) = -x"
03085c441c14 spelling: rename arcos -> arccos
huffman
parents: 22969
diff changeset
  2360
apply (simp add: arccos_def)
23011
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2361
apply (auto intro!: the1_equality cos_total)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2362
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2363
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2364
lemma cos_arcsin: "\<lbrakk>-1 \<le> x; x \<le> 1\<rbrakk> \<Longrightarrow> cos (arcsin x) = sqrt (1 - x\<twosuperior>)"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2365
apply (subgoal_tac "x\<twosuperior> \<le> 1")
23052
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2366
apply (rule power2_eq_imp_eq)
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2367
apply (simp add: cos_squared_eq)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2368
apply (rule cos_ge_zero)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2369
apply (erule (1) arcsin_lbound)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2370
apply (erule (1) arcsin_ubound)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2371
apply simp
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2372
apply (subgoal_tac "\<bar>x\<bar>\<twosuperior> \<le> 1\<twosuperior>", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2373
apply (rule power_mono, simp, simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2374
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2375
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2376
lemma sin_arccos: "\<lbrakk>-1 \<le> x; x \<le> 1\<rbrakk> \<Longrightarrow> sin (arccos x) = sqrt (1 - x\<twosuperior>)"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2377
apply (subgoal_tac "x\<twosuperior> \<le> 1")
23052
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2378
apply (rule power2_eq_imp_eq)
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2379
apply (simp add: sin_squared_eq)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2380
apply (rule sin_ge_zero)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2381
apply (erule (1) arccos_lbound)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2382
apply (erule (1) arccos_ubound)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2383
apply simp
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2384
apply (subgoal_tac "\<bar>x\<bar>\<twosuperior> \<le> 1\<twosuperior>", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2385
apply (rule power_mono, simp, simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2386
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2387
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2388
lemma arctan [simp]:
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2389
     "- (pi/2) < arctan y  & arctan y < pi/2 & tan (arctan y) = y"
23011
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2390
unfolding arctan_def by (rule theI' [OF tan_total])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2391
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2392
lemma tan_arctan: "tan(arctan y) = y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2393
by auto
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2394
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2395
lemma arctan_bounded: "- (pi/2) < arctan y  & arctan y < pi/2"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2396
by (auto simp only: arctan)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2397
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2398
lemma arctan_lbound: "- (pi/2) < arctan y"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2399
by auto
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2400
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2401
lemma arctan_ubound: "arctan y < pi/2"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2402
by (auto simp only: arctan)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2403
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2404
lemma arctan_tan:
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2405
      "[|-(pi/2) < x; x < pi/2 |] ==> arctan(tan x) = x"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2406
apply (unfold arctan_def)
23011
3eae3140b4b2 use THE instead of SOME
huffman
parents: 23007
diff changeset
  2407
apply (rule the1_equality)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2408
apply (rule tan_total, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2409
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2410
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2411
lemma arctan_zero_zero [simp]: "arctan 0 = 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2412
by (insert arctan_tan [of 0], simp)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2413
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2414
lemma cos_arctan_not_zero [simp]: "cos(arctan x) \<noteq> 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2415
apply (auto simp add: cos_zero_iff)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2416
apply (case_tac "n")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2417
apply (case_tac [3] "n")
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2418
apply (cut_tac [2] y = x in arctan_ubound)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2419
apply (cut_tac [4] y = x in arctan_lbound)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2420
apply (auto simp add: real_of_nat_Suc left_distrib mult_less_0_iff)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2421
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2422
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2423
lemma tan_sec: "cos x \<noteq> 0 ==> 1 + tan(x) ^ 2 = inverse(cos x) ^ 2"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2424
apply (rule power_inverse [THEN subst])
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2425
apply (rule_tac c1 = "(cos x)\<twosuperior>" in real_mult_right_cancel [THEN iffD1])
22960
114cf1906681 remove redundant lemmas
huffman
parents: 22956
diff changeset
  2426
apply (auto dest: field_power_not_zero
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2427
        simp add: power_mult_distrib left_distrib power_divide tan_def
30273
ecd6f0ca62ea declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
huffman
parents: 30082
diff changeset
  2428
                  mult_assoc power_inverse [symmetric])
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2429
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2430
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2431
lemma isCont_inverse_function2:
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2432
  fixes f g :: "real \<Rightarrow> real" shows
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2433
  "\<lbrakk>a < x; x < b;
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2434
    \<forall>z. a \<le> z \<and> z \<le> b \<longrightarrow> g (f z) = z;
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2435
    \<forall>z. a \<le> z \<and> z \<le> b \<longrightarrow> isCont f z\<rbrakk>
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2436
   \<Longrightarrow> isCont g (f x)"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2437
apply (rule isCont_inverse_function
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2438
       [where f=f and d="min (x - a) (b - x)"])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2439
apply (simp_all add: abs_le_iff)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2440
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2441
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2442
lemma isCont_arcsin: "\<lbrakk>-1 < x; x < 1\<rbrakk> \<Longrightarrow> isCont arcsin x"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2443
apply (subgoal_tac "isCont arcsin (sin (arcsin x))", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2444
apply (rule isCont_inverse_function2 [where f=sin])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2445
apply (erule (1) arcsin_lt_bounded [THEN conjunct1])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2446
apply (erule (1) arcsin_lt_bounded [THEN conjunct2])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2447
apply (fast intro: arcsin_sin, simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2448
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2449
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2450
lemma isCont_arccos: "\<lbrakk>-1 < x; x < 1\<rbrakk> \<Longrightarrow> isCont arccos x"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2451
apply (subgoal_tac "isCont arccos (cos (arccos x))", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2452
apply (rule isCont_inverse_function2 [where f=cos])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2453
apply (erule (1) arccos_lt_bounded [THEN conjunct1])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2454
apply (erule (1) arccos_lt_bounded [THEN conjunct2])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2455
apply (fast intro: arccos_cos, simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2456
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2457
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2458
lemma isCont_arctan: "isCont arctan x"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2459
apply (rule arctan_lbound [of x, THEN dense, THEN exE], clarify)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2460
apply (rule arctan_ubound [of x, THEN dense, THEN exE], clarify)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2461
apply (subgoal_tac "isCont arctan (tan (arctan x))", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2462
apply (erule (1) isCont_inverse_function2 [where f=tan])
33667
958dc9f03611 A little rationalisation
paulson
parents: 33549
diff changeset
  2463
apply (metis arctan_tan order_le_less_trans order_less_le_trans)
36777
be5461582d0f avoid using real-specific versions of generic lemmas
huffman
parents: 36776
diff changeset
  2464
apply (metis cos_gt_zero_pi isCont_tan order_less_le_trans less_le)
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2465
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2466
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2467
lemma DERIV_arcsin:
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2468
  "\<lbrakk>-1 < x; x < 1\<rbrakk> \<Longrightarrow> DERIV arcsin x :> inverse (sqrt (1 - x\<twosuperior>))"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2469
apply (rule DERIV_inverse_function [where f=sin and a="-1" and b="1"])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2470
apply (rule lemma_DERIV_subst [OF DERIV_sin])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2471
apply (simp add: cos_arcsin)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2472
apply (subgoal_tac "\<bar>x\<bar>\<twosuperior> < 1\<twosuperior>", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2473
apply (rule power_strict_mono, simp, simp, simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2474
apply assumption
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2475
apply assumption
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2476
apply simp
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2477
apply (erule (1) isCont_arcsin)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2478
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2479
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2480
lemma DERIV_arccos:
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2481
  "\<lbrakk>-1 < x; x < 1\<rbrakk> \<Longrightarrow> DERIV arccos x :> inverse (- sqrt (1 - x\<twosuperior>))"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2482
apply (rule DERIV_inverse_function [where f=cos and a="-1" and b="1"])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2483
apply (rule lemma_DERIV_subst [OF DERIV_cos])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2484
apply (simp add: sin_arccos)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2485
apply (subgoal_tac "\<bar>x\<bar>\<twosuperior> < 1\<twosuperior>", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2486
apply (rule power_strict_mono, simp, simp, simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2487
apply assumption
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2488
apply assumption
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2489
apply simp
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2490
apply (erule (1) isCont_arccos)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2491
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2492
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2493
lemma DERIV_arctan: "DERIV arctan x :> inverse (1 + x\<twosuperior>)"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2494
apply (rule DERIV_inverse_function [where f=tan and a="x - 1" and b="x + 1"])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2495
apply (rule lemma_DERIV_subst [OF DERIV_tan])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2496
apply (rule cos_arctan_not_zero)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2497
apply (simp add: power_inverse tan_sec [symmetric])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2498
apply (subgoal_tac "0 < 1 + x\<twosuperior>", simp)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2499
apply (simp add: add_pos_nonneg)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2500
apply (simp, simp, simp, rule isCont_arctan)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2501
done
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  2502
31880
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  2503
declare
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  2504
  DERIV_arcsin[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros]
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  2505
  DERIV_arccos[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros]
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  2506
  DERIV_arctan[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros]
6fb86c61747c Added DERIV_intros
hoelzl
parents: 31790
diff changeset
  2507
23043
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2508
subsection {* More Theorems about Sin and Cos *}
5dbfd67516a4 rearranged sections
huffman
parents: 23011
diff changeset
  2509
23052
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2510
lemma cos_45: "cos (pi / 4) = sqrt 2 / 2"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2511
proof -
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2512
  let ?c = "cos (pi / 4)" and ?s = "sin (pi / 4)"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2513
  have nonneg: "0 \<le> ?c"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2514
    by (rule cos_ge_zero, rule order_trans [where y=0], simp_all)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2515
  have "0 = cos (pi / 4 + pi / 4)"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2516
    by simp
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2517
  also have "cos (pi / 4 + pi / 4) = ?c\<twosuperior> - ?s\<twosuperior>"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2518
    by (simp only: cos_add power2_eq_square)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2519
  also have "\<dots> = 2 * ?c\<twosuperior> - 1"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2520
    by (simp add: sin_squared_eq)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2521
  finally have "?c\<twosuperior> = (sqrt 2 / 2)\<twosuperior>"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2522
    by (simp add: power_divide)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2523
  thus ?thesis
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2524
    using nonneg by (rule power2_eq_imp_eq) simp
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2525
qed
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2526
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2527
lemma cos_30: "cos (pi / 6) = sqrt 3 / 2"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2528
proof -
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2529
  let ?c = "cos (pi / 6)" and ?s = "sin (pi / 6)"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2530
  have pos_c: "0 < ?c"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2531
    by (rule cos_gt_zero, simp, simp)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2532
  have "0 = cos (pi / 6 + pi / 6 + pi / 6)"
23066
26a9157b620a new field_combine_numerals simproc, which uses fractions as coefficients
huffman
parents: 23053
diff changeset
  2533
    by simp
23052
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2534
  also have "\<dots> = (?c * ?c - ?s * ?s) * ?c - (?s * ?c + ?c * ?s) * ?s"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2535
    by (simp only: cos_add sin_add)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2536
  also have "\<dots> = ?c * (?c\<twosuperior> - 3 * ?s\<twosuperior>)"
29667
53103fc8ffa3 Replaced group_ and ring_simps by algebra_simps;
nipkow
parents: 29171
diff changeset
  2537
    by (simp add: algebra_simps power2_eq_square)
23052
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2538
  finally have "?c\<twosuperior> = (sqrt 3 / 2)\<twosuperior>"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2539
    using pos_c by (simp add: sin_squared_eq power_divide)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2540
  thus ?thesis
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2541
    using pos_c [THEN order_less_imp_le]
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2542
    by (rule power2_eq_imp_eq) simp
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2543
qed
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2544
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2545
lemma sin_45: "sin (pi / 4) = sqrt 2 / 2"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2546
proof -
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2547
  have "sin (pi / 4) = cos (pi / 2 - pi / 4)" by (rule sin_cos_eq)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2548
  also have "pi / 2 - pi / 4 = pi / 4" by simp
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2549
  also have "cos (pi / 4) = sqrt 2 / 2" by (rule cos_45)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2550
  finally show ?thesis .
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2551
qed
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2552
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2553
lemma sin_60: "sin (pi / 3) = sqrt 3 / 2"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2554
proof -
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2555
  have "sin (pi / 3) = cos (pi / 2 - pi / 3)" by (rule sin_cos_eq)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2556
  also have "pi / 2 - pi / 3 = pi / 6" by simp
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2557
  also have "cos (pi / 6) = sqrt 3 / 2" by (rule cos_30)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2558
  finally show ?thesis .
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2559
qed
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2560
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2561
lemma cos_60: "cos (pi / 3) = 1 / 2"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2562
apply (rule power2_eq_imp_eq)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2563
apply (simp add: cos_squared_eq sin_60 power_divide)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2564
apply (rule cos_ge_zero, rule order_trans [where y=0], simp_all)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2565
done
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2566
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2567
lemma sin_30: "sin (pi / 6) = 1 / 2"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2568
proof -
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2569
  have "sin (pi / 6) = cos (pi / 2 - pi / 6)" by (rule sin_cos_eq)
23066
26a9157b620a new field_combine_numerals simproc, which uses fractions as coefficients
huffman
parents: 23053
diff changeset
  2570
  also have "pi / 2 - pi / 6 = pi / 3" by simp
23052
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2571
  also have "cos (pi / 3) = 1 / 2" by (rule cos_60)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2572
  finally show ?thesis .
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2573
qed
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2574
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2575
lemma tan_30: "tan (pi / 6) = 1 / sqrt 3"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2576
unfolding tan_def by (simp add: sin_30 cos_30)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2577
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2578
lemma tan_45: "tan (pi / 4) = 1"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2579
unfolding tan_def by (simp add: sin_45 cos_45)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2580
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2581
lemma tan_60: "tan (pi / 3) = sqrt 3"
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2582
unfolding tan_def by (simp add: sin_60 cos_60)
0e36f0dbfa1c add lemmas for sin,cos,tan of 30,45,60 degrees; cleaned up
huffman
parents: 23049
diff changeset
  2583
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2584
lemma DERIV_sin_add [simp]: "DERIV (%x. sin (x + k)) xa :> cos (xa + k)"
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  2585
  by (auto intro!: DERIV_intros)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2586
15383
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  2587
lemma sin_cos_npi [simp]: "sin (real (Suc (2 * n)) * pi / 2) = (-1) ^ n"
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  2588
proof -
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  2589
  have "sin ((real n + 1/2) * pi) = cos (real n * pi)"
29667
53103fc8ffa3 Replaced group_ and ring_simps by algebra_simps;
nipkow
parents: 29171
diff changeset
  2590
    by (auto simp add: algebra_simps sin_add)
15383
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  2591
  thus ?thesis
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2592
    by (simp add: real_of_nat_Suc left_distrib add_divide_distrib
15383
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  2593
                  mult_commute [of pi])
c49e4225ef4f made proofs more robust
paulson
parents: 15251
diff changeset
  2594
qed
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2595
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2596
lemma cos_2npi [simp]: "cos (2 * real (n::nat) * pi) = 1"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2597
by (simp add: cos_double mult_assoc power_add [symmetric] numeral_2_eq_2)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2598
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2599
lemma cos_3over2_pi [simp]: "cos (3 / 2 * pi) = 0"
23066
26a9157b620a new field_combine_numerals simproc, which uses fractions as coefficients
huffman
parents: 23053
diff changeset
  2600
apply (subgoal_tac "cos (pi + pi/2) = 0", simp)
26a9157b620a new field_combine_numerals simproc, which uses fractions as coefficients
huffman
parents: 23053
diff changeset
  2601
apply (subst cos_add, simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2602
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2603
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2604
lemma sin_2npi [simp]: "sin (2 * real (n::nat) * pi) = 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2605
by (auto simp add: mult_assoc)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2606
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2607
lemma sin_3over2_pi [simp]: "sin (3 / 2 * pi) = - 1"
23066
26a9157b620a new field_combine_numerals simproc, which uses fractions as coefficients
huffman
parents: 23053
diff changeset
  2608
apply (subgoal_tac "sin (pi + pi/2) = - 1", simp)
26a9157b620a new field_combine_numerals simproc, which uses fractions as coefficients
huffman
parents: 23053
diff changeset
  2609
apply (subst sin_add, simp)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2610
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2611
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2612
lemma cos_pi_eq_zero [simp]: "cos (pi * real (Suc (2 * m)) / 2) = 0"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  2613
by (simp only: cos_add sin_add real_of_nat_Suc left_distrib right_distrib add_divide_distrib, auto)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2614
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2615
lemma DERIV_cos_add [simp]: "DERIV (%x. cos (x + k)) xa :> - sin (xa + k)"
31881
eba74a5790d2 use DERIV_intros
hoelzl
parents: 31880
diff changeset
  2616
  by (auto intro!: DERIV_intros)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2617
15081
32402f5624d1 abs notation
paulson
parents: 15079
diff changeset
  2618
lemma sin_zero_abs_cos_one: "sin x = 0 ==> \<bar>cos x\<bar> = 1"
15539
333a88244569 comprehensive cleanup, replacing sumr by setsum
nipkow
parents: 15536
diff changeset
  2619
by (auto simp add: sin_zero_iff even_mult_two_ex)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2620
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2621
lemma cos_one_sin_zero: "cos x = 1 ==> sin x = 0"
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2622
by (cut_tac x = x in sin_cos_squared_add3, auto)
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  2623
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2624
subsection {* Machins formula *}
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2625
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2626
lemma tan_total_pi4: assumes "\<bar>x\<bar> < 1"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2627
  shows "\<exists> z. - (pi / 4) < z \<and> z < pi / 4 \<and> tan z = x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2628
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2629
  obtain z where "- (pi / 2) < z" and "z < pi / 2" and "tan z = x" using tan_total by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2630
  have "tan (pi / 4) = 1" and "tan (- (pi / 4)) = - 1" using tan_45 tan_minus by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2631
  have "z \<noteq> pi / 4"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2632
  proof (rule ccontr)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2633
    assume "\<not> (z \<noteq> pi / 4)" hence "z = pi / 4" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2634
    have "tan z = 1" unfolding `z = pi / 4` `tan (pi / 4) = 1` ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2635
    thus False unfolding `tan z = x` using `\<bar>x\<bar> < 1` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2636
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2637
  have "z \<noteq> - (pi / 4)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2638
  proof (rule ccontr)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2639
    assume "\<not> (z \<noteq> - (pi / 4))" hence "z = - (pi / 4)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2640
    have "tan z = - 1" unfolding `z = - (pi / 4)` `tan (- (pi / 4)) = - 1` ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2641
    thus False unfolding `tan z = x` using `\<bar>x\<bar> < 1` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2642
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2643
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2644
  have "z < pi / 4"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2645
  proof (rule ccontr)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2646
    assume "\<not> (z < pi / 4)" hence "pi / 4 < z" using `z \<noteq> pi / 4` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2647
    have "- (pi / 2) < pi / 4" using m2pi_less_pi by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2648
    from tan_monotone[OF this `pi / 4 < z` `z < pi / 2`]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2649
    have "1 < x" unfolding `tan z = x` `tan (pi / 4) = 1` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2650
    thus False using `\<bar>x\<bar> < 1` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2651
  qed
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2652
  moreover
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2653
  have "-(pi / 4) < z"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2654
  proof (rule ccontr)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2655
    assume "\<not> (-(pi / 4) < z)" hence "z < - (pi / 4)" using `z \<noteq> - (pi / 4)` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2656
    have "-(pi / 4) < pi / 2" using m2pi_less_pi by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2657
    from tan_monotone[OF `-(pi / 2) < z` `z < -(pi / 4)` this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2658
    have "x < - 1" unfolding `tan z = x` `tan (-(pi / 4)) = - 1` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2659
    thus False using `\<bar>x\<bar> < 1` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2660
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2661
  ultimately show ?thesis using `tan z = x` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2662
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2663
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2664
lemma arctan_add: assumes "\<bar>x\<bar> \<le> 1" and "\<bar>y\<bar> < 1"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2665
  shows "arctan x + arctan y = arctan ((x + y) / (1 - x * y))"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2666
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2667
  obtain y' where "-(pi/4) < y'" and "y' < pi/4" and "tan y' = y" using tan_total_pi4[OF `\<bar>y\<bar> < 1`] by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2668
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2669
  have "pi / 4 < pi / 2" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2670
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2671
  have "\<exists> x'. -(pi/4) \<le> x' \<and> x' \<le> pi/4 \<and> tan x' = x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2672
  proof (cases "\<bar>x\<bar> < 1")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2673
    case True from tan_total_pi4[OF this] obtain x' where "-(pi/4) < x'" and "x' < pi/4" and "tan x' = x" by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2674
    hence "-(pi/4) \<le> x'" and "x' \<le> pi/4" and "tan x' = x" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2675
    thus ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2676
  next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2677
    case False
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2678
    show ?thesis
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2679
    proof (cases "x = 1")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2680
      case True hence "tan (pi/4) = x" using tan_45 by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2681
      moreover
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2682
      have "- pi \<le> pi" unfolding minus_le_self_iff by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2683
      hence "-(pi/4) \<le> pi/4" and "pi/4 \<le> pi/4" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2684
      ultimately show ?thesis by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2685
    next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2686
      case False hence "x = -1" using `\<not> \<bar>x\<bar> < 1` and `\<bar>x\<bar> \<le> 1` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2687
      hence "tan (-(pi/4)) = x" using tan_45 tan_minus by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2688
      moreover
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2689
      have "- pi \<le> pi" unfolding minus_le_self_iff by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2690
      hence "-(pi/4) \<le> pi/4" and "-(pi/4) \<le> -(pi/4)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2691
      ultimately show ?thesis by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2692
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2693
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2694
  then obtain x' where "-(pi/4) \<le> x'" and "x' \<le> pi/4" and "tan x' = x" by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2695
  hence "-(pi/2) < x'" and "x' < pi/2" using order_le_less_trans[OF `x' \<le> pi/4` `pi / 4 < pi / 2`] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2696
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2697
  have "cos x' \<noteq> 0" using cos_gt_zero_pi[THEN less_imp_neq] and `-(pi/2) < x'` and `x' < pi/2` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2698
  moreover have "cos y' \<noteq> 0" using cos_gt_zero_pi[THEN less_imp_neq] and `-(pi/4) < y'` and `y' < pi/4` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2699
  ultimately have "cos x' * cos y' \<noteq> 0" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2700
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2701
  have divide_nonzero_divide: "\<And> A B C :: real. C \<noteq> 0 \<Longrightarrow> (A / C) / (B / C) = A / B" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2702
  have divide_mult_commute: "\<And> A B C D :: real. A * B / (C * D) = (A / C) * (B / D)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2703
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2704
  have "tan (x' + y') = sin (x' + y') / (cos x' * cos y' - sin x' * sin y')" unfolding tan_def cos_add ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2705
  also have "\<dots> = (tan x' + tan y') / ((cos x' * cos y' - sin x' * sin y') / (cos x' * cos y'))" unfolding add_tan_eq[OF `cos x' \<noteq> 0` `cos y' \<noteq> 0`] divide_nonzero_divide[OF `cos x' * cos y' \<noteq> 0`] ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2706
  also have "\<dots> = (tan x' + tan y') / (1 - tan x' * tan y')" unfolding tan_def diff_divide_distrib divide_self[OF `cos x' * cos y' \<noteq> 0`] unfolding divide_mult_commute ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2707
  finally have tan_eq: "tan (x' + y') = (x + y) / (1 - x * y)" unfolding `tan y' = y` `tan x' = x` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2708
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2709
  have "arctan (tan (x' + y')) = x' + y'" using `-(pi/4) < y'` `-(pi/4) \<le> x'` `y' < pi/4` and `x' \<le> pi/4` by (auto intro!: arctan_tan)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2710
  moreover have "arctan (tan (x')) = x'" using `-(pi/2) < x'` and `x' < pi/2` by (auto intro!: arctan_tan)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2711
  moreover have "arctan (tan (y')) = y'" using `-(pi/4) < y'` and `y' < pi/4` by (auto intro!: arctan_tan)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2712
  ultimately have "arctan x + arctan y = arctan (tan (x' + y'))" unfolding `tan y' = y` [symmetric] `tan x' = x`[symmetric] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2713
  thus "arctan x + arctan y = arctan ((x + y) / (1 - x * y))" unfolding tan_eq .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2714
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2715
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2716
lemma arctan1_eq_pi4: "arctan 1 = pi / 4" unfolding tan_45[symmetric] by (rule arctan_tan, auto simp add: m2pi_less_pi)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2717
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2718
theorem machin: "pi / 4 = 4 * arctan (1/5) - arctan (1 / 239)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2719
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2720
  have "\<bar>1 / 5\<bar> < (1 :: real)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2721
  from arctan_add[OF less_imp_le[OF this] this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2722
  have "2 * arctan (1 / 5) = arctan (5 / 12)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2723
  moreover
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2724
  have "\<bar>5 / 12\<bar> < (1 :: real)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2725
  from arctan_add[OF less_imp_le[OF this] this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2726
  have "2 * arctan (5 / 12) = arctan (120 / 119)" by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2727
  moreover
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2728
  have "\<bar>1\<bar> \<le> (1::real)" and "\<bar>1 / 239\<bar> < (1::real)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2729
  from arctan_add[OF this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2730
  have "arctan 1 + arctan (1 / 239) = arctan (120 / 119)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2731
  ultimately have "arctan 1 + arctan (1 / 239) = 4 * arctan (1 / 5)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2732
  thus ?thesis unfolding arctan1_eq_pi4 by algebra
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2733
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2734
subsection {* Introducing the arcus tangens power series *}
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2735
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2736
lemma monoseq_arctan_series: fixes x :: real
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2737
  assumes "\<bar>x\<bar> \<le> 1" shows "monoseq (\<lambda> n. 1 / real (n*2+1) * x^(n*2+1))" (is "monoseq ?a")
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2738
proof (cases "x = 0") case True thus ?thesis unfolding monoseq_def One_nat_def by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2739
next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2740
  case False
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2741
  have "norm x \<le> 1" and "x \<le> 1" and "-1 \<le> x" using assms by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2742
  show "monoseq ?a"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2743
  proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2744
    { fix n fix x :: real assume "0 \<le> x" and "x \<le> 1"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2745
      have "1 / real (Suc (Suc n * 2)) * x ^ Suc (Suc n * 2) \<le> 1 / real (Suc (n * 2)) * x ^ Suc (n * 2)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2746
      proof (rule mult_mono)
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2747
        show "1 / real (Suc (Suc n * 2)) \<le> 1 / real (Suc (n * 2))" by (rule frac_le) simp_all
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2748
        show "0 \<le> 1 / real (Suc (n * 2))" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2749
        show "x ^ Suc (Suc n * 2) \<le> x ^ Suc (n * 2)" by (rule power_decreasing) (simp_all add: `0 \<le> x` `x \<le> 1`)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2750
        show "0 \<le> x ^ Suc (Suc n * 2)" by (rule zero_le_power) (simp add: `0 \<le> x`)
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2751
      qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2752
    } note mono = this
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2753
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2754
    show ?thesis
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2755
    proof (cases "0 \<le> x")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2756
      case True from mono[OF this `x \<le> 1`, THEN allI]
31790
05c92381363c corrected and unified thm names
nipkow
parents: 31338
diff changeset
  2757
      show ?thesis unfolding Suc_eq_plus1[symmetric] by (rule mono_SucI2)
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2758
    next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2759
      case False hence "0 \<le> -x" and "-x \<le> 1" using `-1 \<le> x` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2760
      from mono[OF this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2761
      have "\<And>n. 1 / real (Suc (Suc n * 2)) * x ^ Suc (Suc n * 2) \<ge> 1 / real (Suc (n * 2)) * x ^ Suc (n * 2)" using `0 \<le> -x` by auto
31790
05c92381363c corrected and unified thm names
nipkow
parents: 31338
diff changeset
  2762
      thus ?thesis unfolding Suc_eq_plus1[symmetric] by (rule mono_SucI1[OF allI])
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2763
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2764
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2765
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2766
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2767
lemma zeroseq_arctan_series: fixes x :: real
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2768
  assumes "\<bar>x\<bar> \<le> 1" shows "(\<lambda> n. 1 / real (n*2+1) * x^(n*2+1)) ----> 0" (is "?a ----> 0")
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2769
proof (cases "x = 0") case True thus ?thesis unfolding One_nat_def by (auto simp add: LIMSEQ_const)
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2770
next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2771
  case False
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2772
  have "norm x \<le> 1" and "x \<le> 1" and "-1 \<le> x" using assms by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2773
  show "?a ----> 0"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2774
  proof (cases "\<bar>x\<bar> < 1")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2775
    case True hence "norm x < 1" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2776
    from LIMSEQ_mult[OF LIMSEQ_inverse_real_of_nat LIMSEQ_power_zero[OF `norm x < 1`, THEN LIMSEQ_Suc]]
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2777
    have "(\<lambda>n. 1 / real (n + 1) * x ^ (n + 1)) ----> 0"
31790
05c92381363c corrected and unified thm names
nipkow
parents: 31338
diff changeset
  2778
      unfolding inverse_eq_divide Suc_eq_plus1 by simp
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2779
    then show ?thesis using pos2 by (rule LIMSEQ_linear)
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2780
  next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2781
    case False hence "x = -1 \<or> x = 1" using `\<bar>x\<bar> \<le> 1` by auto
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2782
    hence n_eq: "\<And> n. x ^ (n * 2 + 1) = x" unfolding One_nat_def by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2783
    from LIMSEQ_mult[OF LIMSEQ_inverse_real_of_nat[THEN LIMSEQ_linear, OF pos2, unfolded inverse_eq_divide] LIMSEQ_const[of x]]
31790
05c92381363c corrected and unified thm names
nipkow
parents: 31338
diff changeset
  2784
    show ?thesis unfolding n_eq Suc_eq_plus1 by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2785
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2786
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2787
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2788
lemma summable_arctan_series: fixes x :: real and n :: nat
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2789
  assumes "\<bar>x\<bar> \<le> 1" shows "summable (\<lambda> k. (-1)^k * (1 / real (k*2+1) * x ^ (k*2+1)))" (is "summable (?c x)")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2790
  by (rule summable_Leibniz(1), rule zeroseq_arctan_series[OF assms], rule monoseq_arctan_series[OF assms])
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2791
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2792
lemma less_one_imp_sqr_less_one: fixes x :: real assumes "\<bar>x\<bar> < 1" shows "x^2 < 1"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2793
proof -
38642
8fa437809c67 dropped type classes mult_mono and mult_mono1; tuned names of technical rule duplicates
haftmann
parents: 37887
diff changeset
  2794
  from mult_left_mono[OF less_imp_le[OF `\<bar>x\<bar> < 1`] abs_ge_zero[of x]]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2795
  have "\<bar> x^2 \<bar> < 1" using `\<bar> x \<bar> < 1` unfolding numeral_2_eq_2 power_Suc2 by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2796
  thus ?thesis using zero_le_power2 by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2797
qed
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2798
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2799
lemma DERIV_arctan_series: assumes "\<bar> x \<bar> < 1"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2800
  shows "DERIV (\<lambda> x'. \<Sum> k. (-1)^k * (1 / real (k*2+1) * x' ^ (k*2+1))) x :> (\<Sum> k. (-1)^k * x^(k*2))" (is "DERIV ?arctan _ :> ?Int")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2801
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2802
  let "?f n" = "if even n then (-1)^(n div 2) * 1 / real (Suc n) else 0"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2804
  { fix n :: nat assume "even n" hence "2 * (n div 2) = n" by presburger } note n_even=this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2805
  have if_eq: "\<And> n x'. ?f n * real (Suc n) * x'^n = (if even n then (-1)^(n div 2) * x'^(2 * (n div 2)) else 0)" using n_even by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2806
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2807
  { fix x :: real assume "\<bar>x\<bar> < 1" hence "x^2 < 1" by (rule less_one_imp_sqr_less_one)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2808
    have "summable (\<lambda> n. -1 ^ n * (x^2) ^n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2809
      by (rule summable_Leibniz(1), auto intro!: LIMSEQ_realpow_zero monoseq_realpow `x^2 < 1` order_less_imp_le[OF `x^2 < 1`])
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2810
    hence "summable (\<lambda> n. -1 ^ n * x^(2*n))" unfolding power_mult .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2811
  } note summable_Integral = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2812
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2813
  { fix f :: "nat \<Rightarrow> real"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2814
    have "\<And> x. f sums x = (\<lambda> n. if even n then f (n div 2) else 0) sums x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2815
    proof
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2816
      fix x :: real assume "f sums x"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2817
      from sums_if[OF sums_zero this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2818
      show "(\<lambda> n. if even n then f (n div 2) else 0) sums x" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2819
    next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2820
      fix x :: real assume "(\<lambda> n. if even n then f (n div 2) else 0) sums x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2821
      from LIMSEQ_linear[OF this[unfolded sums_def] pos2, unfolded sum_split_even_odd[unfolded mult_commute]]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2822
      show "f sums x" unfolding sums_def by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2823
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2824
    hence "op sums f = op sums (\<lambda> n. if even n then f (n div 2) else 0)" ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2825
  } note sums_even = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2826
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2827
  have Int_eq: "(\<Sum> n. ?f n * real (Suc n) * x^n) = ?Int" unfolding if_eq mult_commute[of _ 2] suminf_def sums_even[of "\<lambda> n. -1 ^ n * x ^ (2 * n)", symmetric]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2828
    by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2829
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2830
  { fix x :: real
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2831
    have if_eq': "\<And> n. (if even n then -1 ^ (n div 2) * 1 / real (Suc n) else 0) * x ^ Suc n =
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2832
      (if even n then -1 ^ (n div 2) * (1 / real (Suc (2 * (n div 2))) * x ^ Suc (2 * (n div 2))) else 0)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2833
      using n_even by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2834
    have idx_eq: "\<And> n. n * 2 + 1 = Suc (2 * n)" by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2835
    have "(\<Sum> n. ?f n * x^(Suc n)) = ?arctan x" unfolding if_eq' idx_eq suminf_def sums_even[of "\<lambda> n. -1 ^ n * (1 / real (Suc (2 * n)) * x ^ Suc (2 * n))", symmetric]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2836
      by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2837
  } note arctan_eq = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2838
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2839
  have "DERIV (\<lambda> x. \<Sum> n. ?f n * x^(Suc n)) x :> (\<Sum> n. ?f n * real (Suc n) * x^n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2840
  proof (rule DERIV_power_series')
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2841
    show "x \<in> {- 1 <..< 1}" using `\<bar> x \<bar> < 1` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2842
    { fix x' :: real assume x'_bounds: "x' \<in> {- 1 <..< 1}"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2843
      hence "\<bar>x'\<bar> < 1" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2844
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2845
      let ?S = "\<Sum> n. (-1)^n * x'^(2 * n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2846
      show "summable (\<lambda> n. ?f n * real (Suc n) * x'^n)" unfolding if_eq
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2847
        by (rule sums_summable[where l="0 + ?S"], rule sums_if, rule sums_zero, rule summable_sums, rule summable_Integral[OF `\<bar>x'\<bar> < 1`])
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2848
    }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2849
  qed auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2850
  thus ?thesis unfolding Int_eq arctan_eq .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2851
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2852
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2853
lemma arctan_series: assumes "\<bar> x \<bar> \<le> 1"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2854
  shows "arctan x = (\<Sum> k. (-1)^k * (1 / real (k*2+1) * x ^ (k*2+1)))" (is "_ = suminf (\<lambda> n. ?c x n)")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2855
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2856
  let "?c' x n" = "(-1)^n * x^(n*2)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2857
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2858
  { fix r x :: real assume "0 < r" and "r < 1" and "\<bar> x \<bar> < r"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2859
    have "\<bar>x\<bar> < 1" using `r < 1` and `\<bar>x\<bar> < r` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2860
    from DERIV_arctan_series[OF this]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2861
    have "DERIV (\<lambda> x. suminf (?c x)) x :> (suminf (?c' x))" .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2862
  } note DERIV_arctan_suminf = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2863
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2864
  { fix x :: real assume "\<bar>x\<bar> \<le> 1" note summable_Leibniz[OF zeroseq_arctan_series[OF this] monoseq_arctan_series[OF this]] }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2865
  note arctan_series_borders = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2866
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2867
  { fix x :: real assume "\<bar>x\<bar> < 1" have "arctan x = (\<Sum> k. ?c x k)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2868
  proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2869
    obtain r where "\<bar>x\<bar> < r" and "r < 1" using dense[OF `\<bar>x\<bar> < 1`] by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2870
    hence "0 < r" and "-r < x" and "x < r" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2871
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2872
    have suminf_eq_arctan_bounded: "\<And> x a b. \<lbrakk> -r < a ; b < r ; a < b ; a \<le> x ; x \<le> b \<rbrakk> \<Longrightarrow> suminf (?c x) - arctan x = suminf (?c a) - arctan a"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2873
    proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2874
      fix x a b assume "-r < a" and "b < r" and "a < b" and "a \<le> x" and "x \<le> b"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2875
      hence "\<bar>x\<bar> < r" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2876
      show "suminf (?c x) - arctan x = suminf (?c a) - arctan a"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2877
      proof (rule DERIV_isconst2[of "a" "b"])
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2878
        show "a < b" and "a \<le> x" and "x \<le> b" using `a < b` `a \<le> x` `x \<le> b` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2879
        have "\<forall> x. -r < x \<and> x < r \<longrightarrow> DERIV (\<lambda> x. suminf (?c x) - arctan x) x :> 0"
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2880
        proof (rule allI, rule impI)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2881
          fix x assume "-r < x \<and> x < r" hence "\<bar>x\<bar> < r" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2882
          hence "\<bar>x\<bar> < 1" using `r < 1` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2883
          have "\<bar> - (x^2) \<bar> < 1" using less_one_imp_sqr_less_one[OF `\<bar>x\<bar> < 1`] by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2884
          hence "(\<lambda> n. (- (x^2)) ^ n) sums (1 / (1 - (- (x^2))))" unfolding real_norm_def[symmetric] by (rule geometric_sums)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2885
          hence "(?c' x) sums (1 / (1 - (- (x^2))))" unfolding power_mult_distrib[symmetric] power_mult nat_mult_commute[of _ 2] by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2886
          hence suminf_c'_eq_geom: "inverse (1 + x^2) = suminf (?c' x)" using sums_unique unfolding inverse_eq_divide by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2887
          have "DERIV (\<lambda> x. suminf (?c x)) x :> (inverse (1 + x^2))" unfolding suminf_c'_eq_geom
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2888
            by (rule DERIV_arctan_suminf[OF `0 < r` `r < 1` `\<bar>x\<bar> < r`])
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2889
          from DERIV_add_minus[OF this DERIV_arctan]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2890
          show "DERIV (\<lambda> x. suminf (?c x) - arctan x) x :> 0" unfolding diff_minus by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2891
        qed
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2892
        hence DERIV_in_rball: "\<forall> y. a \<le> y \<and> y \<le> b \<longrightarrow> DERIV (\<lambda> x. suminf (?c x) - arctan x) y :> 0" using `-r < a` `b < r` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2893
        thus "\<forall> y. a < y \<and> y < b \<longrightarrow> DERIV (\<lambda> x. suminf (?c x) - arctan x) y :> 0" using `\<bar>x\<bar> < r` by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2894
        show "\<forall> y. a \<le> y \<and> y \<le> b \<longrightarrow> isCont (\<lambda> x. suminf (?c x) - arctan x) y" using DERIV_in_rball DERIV_isCont by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2895
      qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2896
    qed
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2897
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2898
    have suminf_arctan_zero: "suminf (?c 0) - arctan 0 = 0"
31790
05c92381363c corrected and unified thm names
nipkow
parents: 31338
diff changeset
  2899
      unfolding Suc_eq_plus1[symmetric] power_Suc2 mult_zero_right arctan_zero_zero suminf_zero by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2900
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2901
    have "suminf (?c x) - arctan x = 0"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2902
    proof (cases "x = 0")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2903
      case True thus ?thesis using suminf_arctan_zero by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2904
    next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2905
      case False hence "0 < \<bar>x\<bar>" and "- \<bar>x\<bar> < \<bar>x\<bar>" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2906
      have "suminf (?c (-\<bar>x\<bar>)) - arctan (-\<bar>x\<bar>) = suminf (?c 0) - arctan 0"
35038
a1d93ce94235 more precise proofs
haftmann
parents: 35028
diff changeset
  2907
        by (rule suminf_eq_arctan_bounded[where x="0" and a="-\<bar>x\<bar>" and b="\<bar>x\<bar>", symmetric])
a1d93ce94235 more precise proofs
haftmann
parents: 35028
diff changeset
  2908
          (simp_all only: `\<bar>x\<bar> < r` `-\<bar>x\<bar> < \<bar>x\<bar>` neg_less_iff_less)
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2909
      moreover
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2910
      have "suminf (?c x) - arctan x = suminf (?c (-\<bar>x\<bar>)) - arctan (-\<bar>x\<bar>)"
35038
a1d93ce94235 more precise proofs
haftmann
parents: 35028
diff changeset
  2911
        by (rule suminf_eq_arctan_bounded[where x="x" and a="-\<bar>x\<bar>" and b="\<bar>x\<bar>"])
a1d93ce94235 more precise proofs
haftmann
parents: 35028
diff changeset
  2912
          (simp_all only: `\<bar>x\<bar> < r` `-\<bar>x\<bar> < \<bar>x\<bar>` neg_less_iff_less)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2913
      ultimately
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2914
      show ?thesis using suminf_arctan_zero by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2915
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2916
    thus ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2917
  qed } note when_less_one = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2918
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2919
  show "arctan x = suminf (\<lambda> n. ?c x n)"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2920
  proof (cases "\<bar>x\<bar> < 1")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2921
    case True thus ?thesis by (rule when_less_one)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2922
  next case False hence "\<bar>x\<bar> = 1" using `\<bar>x\<bar> \<le> 1` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2923
    let "?a x n" = "\<bar>1 / real (n*2+1) * x^(n*2+1)\<bar>"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2924
    let "?diff x n" = "\<bar> arctan x - (\<Sum> i = 0..<n. ?c x i)\<bar>"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2925
    { fix n :: nat
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2926
      have "0 < (1 :: real)" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2927
      moreover
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2928
      { fix x :: real assume "0 < x" and "x < 1" hence "\<bar>x\<bar> \<le> 1" and "\<bar>x\<bar> < 1" by auto
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2929
        from `0 < x` have "0 < 1 / real (0 * 2 + (1::nat)) * x ^ (0 * 2 + 1)" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2930
        note bounds = mp[OF arctan_series_borders(2)[OF `\<bar>x\<bar> \<le> 1`] this, unfolded when_less_one[OF `\<bar>x\<bar> < 1`, symmetric], THEN spec]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2931
        have "0 < 1 / real (n*2+1) * x^(n*2+1)" by (rule mult_pos_pos, auto simp only: zero_less_power[OF `0 < x`], auto)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2932
        hence a_pos: "?a x n = 1 / real (n*2+1) * x^(n*2+1)" by (rule abs_of_pos)
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2933
        have "?diff x n \<le> ?a x n"
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2934
        proof (cases "even n")
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2935
          case True hence sgn_pos: "(-1)^n = (1::real)" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2936
          from `even n` obtain m where "2 * m = n" unfolding even_mult_two_ex by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2937
          from bounds[of m, unfolded this atLeastAtMost_iff]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2938
          have "\<bar>arctan x - (\<Sum>i = 0..<n. (?c x i))\<bar> \<le> (\<Sum>i = 0..<n + 1. (?c x i)) - (\<Sum>i = 0..<n. (?c x i))" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2939
          also have "\<dots> = ?c x n" unfolding One_nat_def by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2940
          also have "\<dots> = ?a x n" unfolding sgn_pos a_pos by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2941
          finally show ?thesis .
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2942
        next
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2943
          case False hence sgn_neg: "(-1)^n = (-1::real)" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2944
          from `odd n` obtain m where m_def: "2 * m + 1 = n" unfolding odd_Suc_mult_two_ex by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2945
          hence m_plus: "2 * (m + 1) = n + 1" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2946
          from bounds[of "m + 1", unfolded this atLeastAtMost_iff, THEN conjunct1] bounds[of m, unfolded m_def atLeastAtMost_iff, THEN conjunct2]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2947
          have "\<bar>arctan x - (\<Sum>i = 0..<n. (?c x i))\<bar> \<le> (\<Sum>i = 0..<n. (?c x i)) - (\<Sum>i = 0..<n+1. (?c x i))" by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2948
          also have "\<dots> = - ?c x n" unfolding One_nat_def by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2949
          also have "\<dots> = ?a x n" unfolding sgn_neg a_pos by auto
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2950
          finally show ?thesis .
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2951
        qed
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2952
        hence "0 \<le> ?a x n - ?diff x n" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2953
      }
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2954
      hence "\<forall> x \<in> { 0 <..< 1 }. 0 \<le> ?a x n - ?diff x n" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2955
      moreover have "\<And>x. isCont (\<lambda> x. ?a x n - ?diff x n) x"
37887
2ae085b07f2f diff_minus subsumes diff_def
haftmann
parents: 36974
diff changeset
  2956
        unfolding diff_minus divide_inverse
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2957
        by (auto intro!: isCont_add isCont_rabs isCont_ident isCont_minus isCont_arctan isCont_inverse isCont_mult isCont_power isCont_const isCont_setsum)
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2958
      ultimately have "0 \<le> ?a 1 n - ?diff 1 n" by (rule LIM_less_bound)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2959
      hence "?diff 1 n \<le> ?a 1 n" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2960
    }
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2961
    have "?a 1 ----> 0"
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2962
      unfolding LIMSEQ_rabs_zero power_one divide_inverse One_nat_def
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2963
      by (auto intro!: LIMSEQ_mult LIMSEQ_linear LIMSEQ_inverse_real_of_nat)
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2964
    have "?diff 1 ----> 0"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2965
    proof (rule LIMSEQ_I)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2966
      fix r :: real assume "0 < r"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2967
      obtain N :: nat where N_I: "\<And> n. N \<le> n \<Longrightarrow> ?a 1 n < r" using LIMSEQ_D[OF `?a 1 ----> 0` `0 < r`] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2968
      { fix n assume "N \<le> n" from `?diff 1 n \<le> ?a 1 n` N_I[OF this]
32960
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents: 32047
diff changeset
  2969
        have "norm (?diff 1 n - 0) < r" by auto }
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2970
      thus "\<exists> N. \<forall> n \<ge> N. norm (?diff 1 n - 0) < r" by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2971
    qed
37887
2ae085b07f2f diff_minus subsumes diff_def
haftmann
parents: 36974
diff changeset
  2972
    from this[unfolded LIMSEQ_rabs_zero diff_minus add_commute[of "arctan 1"], THEN LIMSEQ_add_const, of "- arctan 1", THEN LIMSEQ_minus]
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2973
    have "(?c 1) sums (arctan 1)" unfolding sums_def by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2974
    hence "arctan 1 = (\<Sum> i. ?c 1 i)" by (rule sums_unique)
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2975
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2976
    show ?thesis
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2977
    proof (cases "x = 1", simp add: `arctan 1 = (\<Sum> i. ?c 1 i)`)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2978
      assume "x \<noteq> 1" hence "x = -1" using `\<bar>x\<bar> = 1` by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2979
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2980
      have "- (pi / 2) < 0" using pi_gt_zero by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2981
      have "- (2 * pi) < 0" using pi_gt_zero by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2982
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  2983
      have c_minus_minus: "\<And> i. ?c (- 1) i = - ?c 1 i" unfolding One_nat_def by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  2984
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2985
      have "arctan (- 1) = arctan (tan (-(pi / 4)))" unfolding tan_45 tan_minus ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2986
      also have "\<dots> = - (pi / 4)" by (rule arctan_tan, auto simp add: order_less_trans[OF `- (pi / 2) < 0` pi_gt_zero])
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2987
      also have "\<dots> = - (arctan (tan (pi / 4)))" unfolding neg_equal_iff_equal by (rule arctan_tan[symmetric], auto simp add: order_less_trans[OF `- (2 * pi) < 0` pi_gt_zero])
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2988
      also have "\<dots> = - (arctan 1)" unfolding tan_45 ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2989
      also have "\<dots> = - (\<Sum> i. ?c 1 i)" using `arctan 1 = (\<Sum> i. ?c 1 i)` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2990
      also have "\<dots> = (\<Sum> i. ?c (- 1) i)" using suminf_minus[OF sums_summable[OF `(?c 1) sums (arctan 1)`]] unfolding c_minus_minus by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2991
      finally show ?thesis using `x = -1` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2992
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2993
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2994
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2995
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2996
lemma arctan_half: fixes x :: real
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2997
  shows "arctan x = 2 * arctan (x / (1 + sqrt(1 + x^2)))"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2998
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  2999
  obtain y where low: "- (pi / 2) < y" and high: "y < pi / 2" and y_eq: "tan y = x" using tan_total by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3000
  hence low2: "- (pi / 2) < y / 2" and high2: "y / 2 < pi / 2" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3001
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3002
  have divide_nonzero_divide: "\<And> A B C :: real. C \<noteq> 0 \<Longrightarrow> A / B = (A / C) / (B / C)" by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  3003
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3004
  have "0 < cos y" using cos_gt_zero_pi[OF low high] .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3005
  hence "cos y \<noteq> 0" and cos_sqrt: "sqrt ((cos y) ^ 2) = cos y" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3006
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3007
  have "1 + (tan y)^2 = 1 + sin y^2 / cos y^2" unfolding tan_def power_divide ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3008
  also have "\<dots> = cos y^2 / cos y^2 + sin y^2 / cos y^2" using `cos y \<noteq> 0` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3009
  also have "\<dots> = 1 / cos y^2" unfolding add_divide_distrib[symmetric] sin_cos_squared_add2 ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3010
  finally have "1 + (tan y)^2 = 1 / cos y^2" .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3011
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3012
  have "sin y / (cos y + 1) = tan y / ((cos y + 1) / cos y)" unfolding tan_def divide_nonzero_divide[OF `cos y \<noteq> 0`, symmetric] ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3013
  also have "\<dots> = tan y / (1 + 1 / cos y)" using `cos y \<noteq> 0` unfolding add_divide_distrib by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3014
  also have "\<dots> = tan y / (1 + 1 / sqrt(cos y^2))" unfolding cos_sqrt ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3015
  also have "\<dots> = tan y / (1 + sqrt(1 / cos y^2))" unfolding real_sqrt_divide by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3016
  finally have eq: "sin y / (cos y + 1) = tan y / (1 + sqrt(1 + (tan y)^2))" unfolding `1 + (tan y)^2 = 1 / cos y^2` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3017
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3018
  have "arctan x = y" using arctan_tan low high y_eq by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3019
  also have "\<dots> = 2 * (arctan (tan (y/2)))" using arctan_tan[OF low2 high2] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3020
  also have "\<dots> = 2 * (arctan (sin y / (cos y + 1)))" unfolding tan_half[OF low2 high2] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3021
  finally show ?thesis unfolding eq `tan y = x` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3022
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3023
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3024
lemma arctan_monotone: assumes "x < y"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3025
  shows "arctan x < arctan y"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3026
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3027
  obtain z where "-(pi / 2) < z" and "z < pi / 2" and "tan z = x" using tan_total by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3028
  obtain w where "-(pi / 2) < w" and "w < pi / 2" and "tan w = y" using tan_total by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3029
  have "z < w" unfolding tan_monotone'[OF `-(pi / 2) < z` `z < pi / 2` `-(pi / 2) < w` `w < pi / 2`] `tan z = x` `tan w = y` using `x < y` .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3030
  thus ?thesis
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3031
    unfolding `tan z = x`[symmetric] arctan_tan[OF `-(pi / 2) < z` `z < pi / 2`]
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3032
    unfolding `tan w = y`[symmetric] arctan_tan[OF `-(pi / 2) < w` `w < pi / 2`] .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3033
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3034
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3035
lemma arctan_monotone': assumes "x \<le> y" shows "arctan x \<le> arctan y"
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  3036
proof (cases "x = y")
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3037
  case False hence "x < y" using `x \<le> y` by auto from arctan_monotone[OF this] show ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3038
qed auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3039
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  3040
lemma arctan_minus: "arctan (- x) = - arctan x"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3041
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3042
  obtain y where "- (pi / 2) < y" and "y < pi / 2" and "tan y = x" using tan_total by blast
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  3043
  thus ?thesis unfolding `tan y = x`[symmetric] tan_minus[symmetric] using arctan_tan[of y] arctan_tan[of "-y"] by auto
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3044
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3045
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3046
lemma arctan_inverse: assumes "x \<noteq> 0" shows "arctan (1 / x) = sgn x * pi / 2 - arctan x"
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3047
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3048
  obtain y where "- (pi / 2) < y" and "y < pi / 2" and "tan y = x" using tan_total by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3049
  hence "y = arctan x" unfolding `tan y = x`[symmetric] using arctan_tan by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3050
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3051
  { fix y x :: real assume "0 < y" and "y < pi /2" and "y = arctan x" and "tan y = x" hence "- (pi / 2) < y" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3052
    have "tan y > 0" using tan_monotone'[OF _ _ `- (pi / 2) < y` `y < pi / 2`, of 0] tan_zero `0 < y` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3053
    hence "x > 0" using `tan y = x` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3054
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3055
    have "- (pi / 2) < pi / 2 - y" using `y > 0` `y < pi / 2` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3056
    moreover have "pi / 2 - y < pi / 2" using `y > 0` `y < pi / 2` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3057
    ultimately have "arctan (1 / x) = pi / 2 - y" unfolding `tan y = x`[symmetric] tan_inverse using arctan_tan by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3058
    hence "arctan (1 / x) = sgn x * pi / 2 - arctan x" unfolding `y = arctan x` real_sgn_pos[OF `x > 0`] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3059
  } note pos_y = this
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3060
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3061
  show ?thesis
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3062
  proof (cases "y > 0")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3063
    case True from pos_y[OF this `y < pi / 2` `y = arctan x` `tan y = x`] show ?thesis .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3064
  next
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3065
    case False hence "y \<le> 0" by auto
41970
47d6e13d1710 generalize infinite sums
hoelzl
parents: 41550
diff changeset
  3066
    moreover have "y \<noteq> 0"
29803
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3067
    proof (rule ccontr)
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3068
      assume "\<not> y \<noteq> 0" hence "y = 0" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3069
      have "x = 0" unfolding `tan y = x`[symmetric] `y = 0` tan_zero ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3070
      thus False using `x \<noteq> 0` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3071
    qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3072
    ultimately have "y < 0" by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3073
    hence "0 < - y" and "-y < pi / 2" using `- (pi / 2) < y` by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3074
    moreover have "-y = arctan (-x)" unfolding arctan_minus `y = arctan x` ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3075
    moreover have "tan (-y) = -x" unfolding tan_minus `tan y = x` ..
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3076
    ultimately have "arctan (1 / -x) = sgn (-x) * pi / 2 - arctan (-x)" using pos_y by blast
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3077
    hence "arctan (- (1 / x)) = - (sgn x * pi / 2 - arctan x)" unfolding arctan_minus[of x] divide_minus_right sgn_minus by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3078
    thus ?thesis unfolding arctan_minus neg_equal_iff_equal .
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3079
  qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3080
qed
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3081
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3082
theorem pi_series: "pi / 4 = (\<Sum> k. (-1)^k * 1 / real (k*2+1))" (is "_ = ?SUM")
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3083
proof -
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3084
  have "pi / 4 = arctan 1" using arctan1_eq_pi4 by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3085
  also have "\<dots> = ?SUM" using arctan_series[of 1] by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3086
  finally show ?thesis by auto
c56a5571f60a Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents: 29695
diff changeset
  3087
qed
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3088
22978
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3089
subsection {* Existence of Polar Coordinates *}
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3090
22978
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3091
lemma cos_x_y_le_one: "\<bar>x / sqrt (x\<twosuperior> + y\<twosuperior>)\<bar> \<le> 1"
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3092
apply (rule power2_le_imp_le [OF _ zero_le_one])
35216
7641e8d831d2 get rid of many duplicate simp rule warnings
huffman
parents: 35213
diff changeset
  3093
apply (simp add: power_divide divide_le_eq not_sum_power2_lt_zero)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3094
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3095
22978
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3096
lemma cos_arccos_abs: "\<bar>y\<bar> \<le> 1 \<Longrightarrow> cos (arccos y) = y"
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3097
by (simp add: abs_le_iff)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3098
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  3099
lemma sin_arccos_abs: "\<bar>y\<bar> \<le> 1 \<Longrightarrow> sin (arccos y) = sqrt (1 - y\<twosuperior>)"
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  3100
by (simp add: sin_arccos abs_le_iff)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3101
22978
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3102
lemmas cos_arccos_lemma1 = cos_arccos_abs [OF cos_x_y_le_one]
15228
4d332d10fa3d revised simprules for division
paulson
parents: 15140
diff changeset
  3103
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  3104
lemmas sin_arccos_lemma1 = sin_arccos_abs [OF cos_x_y_le_one]
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3105
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  3106
lemma polar_ex1:
22978
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3107
     "0 < y ==> \<exists>r a. x = r * cos a & y = r * sin a"
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  3108
apply (rule_tac x = "sqrt (x\<twosuperior> + y\<twosuperior>)" in exI)
22978
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3109
apply (rule_tac x = "arccos (x / sqrt (x\<twosuperior> + y\<twosuperior>))" in exI)
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3110
apply (simp add: cos_arccos_lemma1)
23045
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  3111
apply (simp add: sin_arccos_lemma1)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  3112
apply (simp add: power_divide)
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  3113
apply (simp add: real_sqrt_mult [symmetric])
95e04f335940 add lemmas about inverse functions; cleaned up proof of polar_ex
huffman
parents: 23043
diff changeset
  3114
apply (simp add: right_diff_distrib)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3115
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3116
15229
1eb23f805c06 new simprules for abs and for things like a/b<1
paulson
parents: 15228
diff changeset
  3117
lemma polar_ex2:
22978
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3118
     "y < 0 ==> \<exists>r a. x = r * cos a & y = r * sin a"
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3119
apply (insert polar_ex1 [where x=x and y="-y"], simp, clarify)
33667
958dc9f03611 A little rationalisation
paulson
parents: 33549
diff changeset
  3120
apply (metis cos_minus minus_minus minus_mult_right sin_minus)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3121
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3122
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3123
lemma polar_Ex: "\<exists>r a. x = r * cos a & y = r * sin a"
22978
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3124
apply (rule_tac x=0 and y=y in linorder_cases)
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3125
apply (erule polar_ex1)
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3126
apply (rule_tac x=x in exI, rule_tac x=0 in exI, simp)
1cd8cc21a7c3 clean up polar_Ex proofs; remove unnecessary lemmas
huffman
parents: 22977
diff changeset
  3127
apply (erule polar_ex2)
15077
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3128
done
89840837108e converting Hyperreal/Transcendental to Isar script
paulson
parents: 15013
diff changeset
  3129
30082
43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule
huffman
parents: 29803
diff changeset
  3130
end