author | hoelzl |
Mon, 14 Mar 2011 14:37:35 +0100 | |
changeset 41970 | 47d6e13d1710 |
parent 41550 | efa734d9b221 |
child 43335 | 9f8766a8ebe0 |
permissions | -rw-r--r-- |
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1 |
(* Title: HOL/Transcendental.thy |
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2 |
Author: Jacques D. Fleuriot, University of Cambridge, University of Edinburgh |
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3 |
Author: Lawrence C Paulson |
12196 | 4 |
*) |
5 |
||
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6 |
header{*Power Series, Transcendental Functions etc.*} |
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7 |
|
15131 | 8 |
theory Transcendental |
25600 | 9 |
imports Fact Series Deriv NthRoot |
15131 | 10 |
begin |
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11 |
|
29164 | 12 |
subsection {* Properties of Power Series *} |
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13 |
|
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14 |
lemma lemma_realpow_diff: |
31017 | 15 |
fixes y :: "'a::monoid_mult" |
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16 |
shows "p \<le> n \<Longrightarrow> y ^ (Suc n - p) = (y ^ (n - p)) * y" |
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17 |
proof - |
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18 |
assume "p \<le> n" |
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19 |
hence "Suc n - p = Suc (n - p)" by (rule Suc_diff_le) |
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declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
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20 |
thus ?thesis by (simp add: power_commutes) |
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21 |
qed |
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converting Hyperreal/Transcendental to Isar script
paulson
parents:
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22 |
|
89840837108e
converting Hyperreal/Transcendental to Isar script
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23 |
lemma lemma_realpow_diff_sumr: |
31017 | 24 |
fixes y :: "'a::{comm_semiring_0,monoid_mult}" shows |
41970 | 25 |
"(\<Sum>p=0..<Suc n. (x ^ p) * y ^ (Suc n - p)) = |
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26 |
y * (\<Sum>p=0..<Suc n. (x ^ p) * y ^ (n - p))" |
29163 | 27 |
by (simp add: setsum_right_distrib lemma_realpow_diff mult_ac |
33549 | 28 |
del: setsum_op_ivl_Suc) |
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29 |
|
15229 | 30 |
lemma lemma_realpow_diff_sumr2: |
31017 | 31 |
fixes y :: "'a::{comm_ring,monoid_mult}" shows |
41970 | 32 |
"x ^ (Suc n) - y ^ (Suc n) = |
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33 |
(x - y) * (\<Sum>p=0..<Suc n. (x ^ p) * y ^ (n - p))" |
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34 |
apply (induct n, simp) |
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35 |
apply (simp del: setsum_op_ivl_Suc) |
15561 | 36 |
apply (subst setsum_op_ivl_Suc) |
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37 |
apply (subst lemma_realpow_diff_sumr) |
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38 |
apply (simp add: right_distrib del: setsum_op_ivl_Suc) |
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new theory Algebras.thy for generic algebraic structures
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39 |
apply (subst mult_left_commute [of "x - y"]) |
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40 |
apply (erule subst) |
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declare power_Suc [simp]; remove redundant type-specific versions of power_Suc
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41 |
apply (simp add: algebra_simps) |
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42 |
done |
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43 |
|
15229 | 44 |
lemma lemma_realpow_rev_sumr: |
41970 | 45 |
"(\<Sum>p=0..<Suc n. (x ^ p) * (y ^ (n - p))) = |
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46 |
(\<Sum>p=0..<Suc n. (x ^ (n - p)) * (y ^ p))" |
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47 |
apply (rule setsum_reindex_cong [where f="\<lambda>i. n - i"]) |
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48 |
apply (rule inj_onI, simp) |
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49 |
apply auto |
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50 |
apply (rule_tac x="n - x" in image_eqI, simp, simp) |
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51 |
done |
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
52 |
|
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
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53 |
text{*Power series has a `circle` of convergence, i.e. if it sums for @{term |
89840837108e
converting Hyperreal/Transcendental to Isar script
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parents:
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54 |
x}, then it sums absolutely for @{term z} with @{term "\<bar>z\<bar> < \<bar>x\<bar>"}.*} |
89840837108e
converting Hyperreal/Transcendental to Isar script
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55 |
|
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converting Hyperreal/Transcendental to Isar script
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56 |
lemma powser_insidea: |
31017 | 57 |
fixes x z :: "'a::{real_normed_field,banach}" |
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58 |
assumes 1: "summable (\<lambda>n. f n * x ^ n)" |
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59 |
assumes 2: "norm z < norm x" |
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60 |
shows "summable (\<lambda>n. norm (f n * z ^ n))" |
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61 |
proof - |
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62 |
from 2 have x_neq_0: "x \<noteq> 0" by clarsimp |
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63 |
from 1 have "(\<lambda>n. f n * x ^ n) ----> 0" |
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64 |
by (rule summable_LIMSEQ_zero) |
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65 |
hence "convergent (\<lambda>n. f n * x ^ n)" |
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66 |
by (rule convergentI) |
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67 |
hence "Cauchy (\<lambda>n. f n * x ^ n)" |
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68 |
by (simp add: Cauchy_convergent_iff) |
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parents:
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69 |
hence "Bseq (\<lambda>n. f n * x ^ n)" |
389cd9c8cfe1
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huffman
parents:
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diff
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|
70 |
by (rule Cauchy_Bseq) |
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71 |
then obtain K where 3: "0 < K" and 4: "\<forall>n. norm (f n * x ^ n) \<le> K" |
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parents:
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72 |
by (simp add: Bseq_def, safe) |
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parents:
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73 |
have "\<exists>N. \<forall>n\<ge>N. norm (norm (f n * z ^ n)) \<le> |
ffef77eed382
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parents:
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74 |
K * norm (z ^ n) * inverse (norm (x ^ n))" |
20849
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parents:
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75 |
proof (intro exI allI impI) |
389cd9c8cfe1
rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
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changeset
|
76 |
fix n::nat assume "0 \<le> n" |
23082
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parents:
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diff
changeset
|
77 |
have "norm (norm (f n * z ^ n)) * norm (x ^ n) = |
ffef77eed382
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huffman
parents:
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diff
changeset
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78 |
norm (f n * x ^ n) * norm (z ^ n)" |
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parents:
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79 |
by (simp add: norm_mult abs_mult) |
ffef77eed382
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parents:
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diff
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80 |
also have "\<dots> \<le> K * norm (z ^ n)" |
ffef77eed382
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parents:
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diff
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81 |
by (simp only: mult_right_mono 4 norm_ge_zero) |
ffef77eed382
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huffman
parents:
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diff
changeset
|
82 |
also have "\<dots> = K * norm (z ^ n) * (inverse (norm (x ^ n)) * norm (x ^ n))" |
20849
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rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
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diff
changeset
|
83 |
by (simp add: x_neq_0) |
23082
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generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
84 |
also have "\<dots> = K * norm (z ^ n) * inverse (norm (x ^ n)) * norm (x ^ n)" |
20849
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rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
20692
diff
changeset
|
85 |
by (simp only: mult_assoc) |
23082
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parents:
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diff
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|
86 |
finally show "norm (norm (f n * z ^ n)) \<le> |
ffef77eed382
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parents:
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diff
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87 |
K * norm (z ^ n) * inverse (norm (x ^ n))" |
20849
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rewrite proofs of powser_insidea and termdiffs_aux
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parents:
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diff
changeset
|
88 |
by (simp add: mult_le_cancel_right x_neq_0) |
389cd9c8cfe1
rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
20692
diff
changeset
|
89 |
qed |
23082
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generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
90 |
moreover have "summable (\<lambda>n. K * norm (z ^ n) * inverse (norm (x ^ n)))" |
20849
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rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
20692
diff
changeset
|
91 |
proof - |
23082
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generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
92 |
from 2 have "norm (norm (z * inverse x)) < 1" |
ffef77eed382
generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
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diff
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|
93 |
using x_neq_0 |
ffef77eed382
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parents:
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diff
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|
94 |
by (simp add: nonzero_norm_divide divide_inverse [symmetric]) |
ffef77eed382
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huffman
parents:
23069
diff
changeset
|
95 |
hence "summable (\<lambda>n. norm (z * inverse x) ^ n)" |
20849
389cd9c8cfe1
rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
20692
diff
changeset
|
96 |
by (rule summable_geometric) |
23082
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generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
97 |
hence "summable (\<lambda>n. K * norm (z * inverse x) ^ n)" |
20849
389cd9c8cfe1
rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
20692
diff
changeset
|
98 |
by (rule summable_mult) |
23082
ffef77eed382
generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
99 |
thus "summable (\<lambda>n. K * norm (z ^ n) * inverse (norm (x ^ n)))" |
ffef77eed382
generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
100 |
using x_neq_0 |
ffef77eed382
generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
101 |
by (simp add: norm_mult nonzero_norm_inverse power_mult_distrib |
ffef77eed382
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huffman
parents:
23069
diff
changeset
|
102 |
power_inverse norm_power mult_assoc) |
20849
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rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
20692
diff
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|
103 |
qed |
23082
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huffman
parents:
23069
diff
changeset
|
104 |
ultimately show "summable (\<lambda>n. norm (f n * z ^ n))" |
20849
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rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
20692
diff
changeset
|
105 |
by (rule summable_comparison_test) |
389cd9c8cfe1
rewrite proofs of powser_insidea and termdiffs_aux
huffman
parents:
20692
diff
changeset
|
106 |
qed |
15077
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converting Hyperreal/Transcendental to Isar script
paulson
parents:
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diff
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|
107 |
|
15229 | 108 |
lemma powser_inside: |
31017 | 109 |
fixes f :: "nat \<Rightarrow> 'a::{real_normed_field,banach}" shows |
41970 | 110 |
"[| summable (%n. f(n) * (x ^ n)); norm z < norm x |] |
15077
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converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
111 |
==> summable (%n. f(n) * (z ^ n))" |
23082
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parents:
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|
112 |
by (rule powser_insidea [THEN summable_norm_cancel]) |
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converting Hyperreal/Transcendental to Isar script
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parents:
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|
113 |
|
29803
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
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diff
changeset
|
114 |
lemma sum_split_even_odd: fixes f :: "nat \<Rightarrow> real" shows |
41970 | 115 |
"(\<Sum> i = 0 ..< 2 * n. if even i then f i else g i) = |
29803
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
29695
diff
changeset
|
116 |
(\<Sum> i = 0 ..< n. f (2 * i)) + (\<Sum> i = 0 ..< n. g (2 * i + 1))" |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
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diff
changeset
|
117 |
proof (induct n) |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
29695
diff
changeset
|
118 |
case (Suc n) |
41970 | 119 |
have "(\<Sum> i = 0 ..< 2 * Suc n. if even i then f i else g i) = |
29803
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
29695
diff
changeset
|
120 |
(\<Sum> i = 0 ..< n. f (2 * i)) + (\<Sum> i = 0 ..< n. g (2 * i + 1)) + (f (2 * n) + g (2 * n + 1))" |
30082
43c5b7bfc791
make more proofs work whether or not One_nat_def is a simp rule
huffman
parents:
29803
diff
changeset
|
121 |
using Suc.hyps 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:
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diff
changeset
|
122 |
also have "\<dots> = (\<Sum> i = 0 ..< Suc n. f (2 * i)) + (\<Sum> i = 0 ..< Suc n. g (2 * i + 1))" by auto |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
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diff
changeset
|
123 |
finally show ?case . |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
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changeset
|
124 |
qed auto |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
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diff
changeset
|
125 |
|
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
29695
diff
changeset
|
126 |
lemma sums_if': fixes g :: "nat \<Rightarrow> real" assumes "g sums x" |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
29695
diff
changeset
|
127 |
shows "(\<lambda> n. if even n then 0 else g ((n - 1) div 2)) sums x" |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
29695
diff
changeset
|
128 |
unfolding sums_def |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
29695
diff
changeset
|
129 |
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
|
130 |
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
|
131 |
from `g sums x`[unfolded sums_def, THEN LIMSEQ_D, OF this] |
c56a5571f60a
Added derivation lemmas for power series and theorems for the pi, arcus tangens and logarithm series
hoelzl
parents:
29695
diff
changeset
|
132 |
obtain no where no_eq: "\<And> n. n \<ge> no \<Longrightarrow> (norm (setsum g { 0..<n } - 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
|
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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 319 |
subsection {* Term-by-Term Differentiability of Power Series *} |
23043 | 320 |
|
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 | 329 |
lemma sums_Suc_imp: |
330 |
assumes f: "f 0 = 0" |
|
331 |
shows "(\<lambda>n. f (Suc n)) sums s \<Longrightarrow> (\<lambda>n. f n) sums s" |
|
332 |
unfolding sums_def |
|
333 |
apply (rule LIMSEQ_imp_Suc) |
|
334 |
apply (subst setsum_shift_lb_Suc0_0_upt [where f=f, OF f, symmetric]) |
|
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 | 338 |
lemma diffs_equiv: |
41970 | 339 |
fixes x :: "'a::{real_normed_vector, ring_1}" |
340 |
shows "summable (%n. (diffs c)(n) * (x ^ n)) ==> |
|
341 |
(%n. of_nat n * c(n) * (x ^ (n - Suc 0))) sums |
|
15546 | 342 |
(\<Sum>n. (diffs c)(n) * (x ^ n))" |
29163 | 343 |
unfolding diffs_def |
344 |
apply (drule summable_sums) |
|
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 | 349 |
fixes z :: "'a :: {monoid_mult,comm_ring}" shows |
41970 | 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 | 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 | 358 |
lemma lemma_termdiff2: |
31017 | 359 |
fixes h :: "'a :: {field}" |
20860 | 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 | 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 | 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 | 367 |
apply (cases "n", simp) |
368 |
apply (simp add: lemma_realpow_diff_sumr2 h |
|
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 | 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 | 373 |
apply simp |
374 |
apply (simp only: lemma_termdiff1 setsum_right_distrib) |
|
375 |
apply (rule setsum_cong [OF refl]) |
|
15539 | 376 |
apply (simp add: diff_minus [symmetric] less_iff_Suc_add) |
20860 | 377 |
apply (clarify) |
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 | 380 |
apply (subst mult_assoc [symmetric], subst power_add [symmetric]) |
381 |
apply (simp add: mult_ac) |
|
382 |
done |
|
383 |
||
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 | 394 |
lemma lemma_termdiff3: |
31017 | 395 |
fixes h z :: "'a::{real_normed_field}" |
20860 | 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 | 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 | 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 | 407 |
apply (rule mult_commute) |
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 | 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 | 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 | 420 |
apply (intro |
23082
ffef77eed382
generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
421 |
order_trans [OF norm_setsum] |
20860 | 422 |
real_setsum_nat_ivl_bounded2 |
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 | 425 |
zero_le_power K) |
426 |
apply (rule le_Kn, simp) |
|
427 |
done |
|
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 | 430 |
by (simp only: mult_assoc) |
431 |
finally show ?thesis . |
|
432 |
qed |
|
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
433 |
|
20860 | 434 |
lemma lemma_termdiff4: |
31017 | 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 | 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 | 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 | 441 |
proof (safe) |
442 |
let ?h = "of_real (k / 2)::'a" |
|
443 |
have "?h \<noteq> 0" and "norm ?h < k" using k by simp_all |
|
444 |
hence "norm (f ?h) \<le> K * norm ?h" by (rule le) |
|
445 |
hence "0 \<le> K * norm ?h" by (rule order_trans [OF norm_ge_zero]) |
|
446 |
hence zero_le_K: "0 \<le> K" using k by (simp add: zero_le_mult_iff) |
|
447 |
||
20860 | 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 | 450 |
proof (cases) |
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 | 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 | 455 |
next |
456 |
assume K_neq_zero: "K \<noteq> 0" |
|
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 | 459 |
proof (rule exI, safe) |
460 |
from k r K show "0 < min k (r * inverse K / 2)" |
|
461 |
by (simp add: mult_pos_pos positive_imp_inverse_positive) |
|
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 | 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 | 469 |
by (rule mult_strict_left_mono) |
470 |
also have "\<dots> = r / 2" |
|
471 |
using K_neq_zero by simp |
|
472 |
also have "r / 2 < r" |
|
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 | 475 |
qed |
476 |
qed |
|
477 |
qed |
|
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
478 |
|
15229 | 479 |
lemma lemma_termdiff5: |
31017 | 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 | 482 |
assumes k: "0 < (k::real)" |
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 | 485 |
shows "(\<lambda>h. suminf (g h)) -- 0 --> 0" |
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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 518 |
by (rule order_le_less_trans) |
519 |
hence r_neq_0: "r \<noteq> 0" by simp |
|
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 | 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 | 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 | 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 | 541 |
by (rule diffs_equiv [THEN sums_summable]) |
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 | 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 | 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 | 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 | 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 | 564 |
apply (simp (no_asm) add: mult_assoc [symmetric]) |
565 |
apply (rule lemma_termdiff3) |
|
566 |
apply (rule h) |
|
567 |
apply (rule r1 [THEN order_less_imp_le]) |
|
568 |
apply (rule xh [THEN order_less_imp_le]) |
|
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 | 573 |
lemma termdiffs: |
31017 | 574 |
fixes K x :: "'a::{real_normed_field,banach}" |
20860 | 575 |
assumes 1: "summable (\<lambda>n. c n * K ^ n)" |
576 |
assumes 2: "summable (\<lambda>n. (diffs c) n * K ^ n)" |
|
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 | 579 |
shows "DERIV (\<lambda>x. \<Sum>n. c n * x ^ n) x :> (\<Sum>n. (diffs c) n * x ^ n)" |
29163 | 580 |
unfolding deriv_def |
581 |
proof (rule LIM_zero_cancel) |
|
20860 | 582 |
show "(\<lambda>h. (suminf (\<lambda>n. c n * (x + h) ^ n) - suminf (\<lambda>n. c n * x ^ n)) / h |
583 |
- suminf (\<lambda>n. diffs c n * x ^ n)) -- 0 --> 0" |
|
584 |
proof (rule LIM_equal2) |
|
29163 | 585 |
show "0 < norm K - norm x" using 4 by (simp add: less_diff_eq) |
20860 | 586 |
next |
23082
ffef77eed382
generalize powerseries and termdiffs lemmas using axclasses
huffman
parents:
23069
diff
changeset
|
587 |
fix h :: 'a |
20860 | 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 | 593 |
have A: "summable (\<lambda>n. c n * x ^ n)" |
594 |
by (rule powser_inside [OF 1 4]) |
|
595 |
have B: "summable (\<lambda>n. c n * (x + h) ^ n)" |
|
596 |
by (rule powser_inside [OF 1 5]) |
|
597 |
have C: "summable (\<lambda>n. diffs c n * x ^ n)" |
|
598 |
by (rule powser_inside [OF 2 4]) |
|
599 |
show "((\<Sum>n. c n * (x + h) ^ n) - (\<Sum>n. c n * x ^ n)) / h |
|
41970 | 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 | 602 |
apply (subst sums_unique [OF diffs_equiv [OF C]]) |
603 |
apply (subst suminf_diff [OF B A]) |
|
604 |
apply (subst suminf_divide [symmetric]) |
|
605 |
apply (rule summable_diff [OF B A]) |
|
606 |
apply (subst suminf_diff) |
|
607 |
apply (rule summable_divide) |
|
608 |
apply (rule summable_diff [OF B A]) |
|
609 |
apply (rule sums_summable [OF diffs_equiv [OF C]]) |
|
29163 | 610 |
apply (rule arg_cong [where f="suminf"], rule ext) |
29667 | 611 |
apply (simp add: algebra_simps) |
20860 | 612 |
done |
613 |
next |
|
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 | 616 |
by (rule termdiffs_aux [OF 3 4]) |
617 |
qed |
|
618 |
qed |
|
619 |
||
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
620 |
|
29695 | 621 |
subsection{* Some properties of factorials *} |
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 | 624 |
by auto |
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 | 627 |
by auto |
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 | 630 |
by simp |
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 | 633 |
by (auto simp add: positive_imp_inverse_positive) |
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 | 636 |
by (auto intro: order_less_imp_le) |
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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 735 |
also have "\<dots> < r /3 + r/3 + r/3" |
36842 | 736 |
using `?diff_part < r/3` `?L_part \<le> r/3` and `?f'_part < r/3` |
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 | 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 | 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 | 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 | 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 | 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 | 820 |
|
29164 | 821 |
subsection {* Exponential Function *} |
23043 | 822 |
|
823 |
definition |
|
31017 | 824 |
exp :: "'a \<Rightarrow> 'a::{real_normed_field,banach}" where |
25062 | 825 |
"exp x = (\<Sum>n. x ^ n /\<^sub>R real (fact n))" |
23043 | 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 | 828 |
fixes x :: "'a::{real_normed_algebra_1,banach}" |
25062 | 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 | 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 | 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 | 858 |
fixes x :: "'a::{real_normed_algebra_1,banach}" |
25062 | 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 | 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 | 864 |
fix n show "norm (x ^ n /\<^sub>R real (fact n)) \<le> norm x ^ n /\<^sub>R real (fact n)" |
35216 | 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 | 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 | 870 |
|
25062 | 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 | 873 |
|
874 |
||
41970 | 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 | 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 | 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 | 900 |
subsubsection {* Properties of the Exponential Function *} |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
901 |
|
23278 | 902 |
lemma powser_zero: |
31017 | 903 |
fixes f :: "nat \<Rightarrow> 'a::{real_normed_algebra_1}" |
23278 | 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 | 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 | 911 |
lemma exp_zero [simp]: "exp 0 = 1" |
912 |
unfolding exp_def by (simp add: scaleR_conv_of_real powser_zero) |
|
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 | 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 | 920 |
fixes x y :: "'a::{real_field}" |
25062 | 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 | 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 | 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 | 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 | 944 |
also have "\<dots> = (\<Sum>i=0..n. real (Suc i) *\<^sub>R (S x (Suc i) * S y (n-i))) |
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 | 947 |
also have "(\<Sum>i=0..n. real (Suc i) *\<^sub>R (S x (Suc i) * S y (n-i))) = |
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 | 950 |
also have "(\<Sum>i=0..n. real (Suc n-i) *\<^sub>R (S x i * S y (Suc n-i))) = |
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 | 953 |
also have "(\<Sum>i=0..Suc n. real i *\<^sub>R (S x i * S y (Suc n-i))) + |
954 |
(\<Sum>i=0..Suc n. real (Suc n-i) *\<^sub>R (S x i * S y (Suc n-i))) = |
|
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 | 958 |
also have "\<dots> = real (Suc n) *\<^sub>R (\<Sum>i=0..Suc n. S x i * S y (Suc n-i))" |
23127 | 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 | 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 | 969 |
lemma mult_exp_exp: "exp x * exp y = exp (x + y)" |
970 |
by (rule exp_add [symmetric]) |
|
971 |
||
23241 | 972 |
lemma exp_of_real: "exp (of_real x) = of_real (exp x)" |
973 |
unfolding exp_def |
|
974 |
apply (subst of_real.suminf) |
|
975 |
apply (rule summable_exp_generic) |
|
976 |
apply (simp add: scaleR_conv_of_real) |
|
977 |
done |
|
978 |
||
29170 | 979 |
lemma exp_not_eq_zero [simp]: "exp x \<noteq> 0" |
980 |
proof |
|
981 |
have "exp x * exp (- x) = 1" by (simp add: mult_exp_exp) |
|
982 |
also assume "exp x = 0" |
|
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 | 986 |
lemma exp_minus: "exp (- x) = inverse (exp x)" |
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 | 989 |
lemma exp_diff: "exp (x - y) = exp x / exp y" |
990 |
unfolding diff_minus divide_inverse |
|
991 |
by (simp add: exp_add exp_minus) |
|
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
992 |
|
29167 | 993 |
|
994 |
subsubsection {* Properties of the Exponential Function on Reals *} |
|
995 |
||
29170 | 996 |
text {* Comparisons of @{term "exp x"} with zero. *} |
29167 | 997 |
|
998 |
text{*Proof: because every exponential can be seen as a square.*} |
|
999 |
lemma exp_ge_zero [simp]: "0 \<le> exp (x::real)" |
|
1000 |
proof - |
|
1001 |
have "0 \<le> exp (x/2) * exp (x/2)" by simp |
|
1002 |
thus ?thesis by (simp add: exp_add [symmetric]) |
|
1003 |
qed |
|
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 | 1008 |
lemma not_exp_less_zero [simp]: "\<not> exp (x::real) < 0" |
1009 |
by (simp add: not_less) |
|
1010 |
||
1011 |
lemma not_exp_le_zero [simp]: "\<not> exp (x::real) \<le> 0" |
|
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 | 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 | 1022 |
text {* Strict monotonicity of exponential. *} |
1023 |
||
1024 |
lemma exp_ge_add_one_self_aux: "0 \<le> (x::real) ==> (1 + x) \<le> exp(x)" |
|
1025 |
apply (drule order_le_imp_less_or_eq, auto) |
|
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 | 1028 |
apply (rule_tac [2] n = 2 and f = "(%n. inverse (real (fact n)) * x ^ n)" in series_pos_le) |
1029 |
apply (auto intro: summable_exp simp add: numeral_2_eq_2 zero_le_mult_iff) |
|
1030 |
done |
|
1031 |
||
1032 |
lemma exp_gt_one: "0 < (x::real) \<Longrightarrow> 1 < exp x" |
|
1033 |
proof - |
|
1034 |
assume x: "0 < x" |
|
1035 |
hence "1 < 1 + x" by simp |
|
1036 |
also from x have "1 + x \<le> exp x" |
|
1037 |
by (simp add: exp_ge_add_one_self_aux) |
|
1038 |
finally show ?thesis . |
|
1039 |
qed |
|
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 | 1052 |
apply (simp add: linorder_not_le [symmetric]) |
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 | 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 | 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 | 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 | 1065 |
text {* Comparisons of @{term "exp x"} with one. *} |
1066 |
||
1067 |
lemma one_less_exp_iff [simp]: "1 < exp (x::real) \<longleftrightarrow> 0 < x" |
|
1068 |
using exp_less_cancel_iff [where x=0 and y=x] by simp |
|
1069 |
||
1070 |
lemma exp_less_one_iff [simp]: "exp (x::real) < 1 \<longleftrightarrow> x < 0" |
|
1071 |
using exp_less_cancel_iff [where x=x and y=0] by simp |
|
1072 |
||
1073 |
lemma one_le_exp_iff [simp]: "1 \<le> exp (x::real) \<longleftrightarrow> 0 \<le> x" |
|
1074 |
using exp_le_cancel_iff [where x=0 and y=x] by simp |
|
1075 |
||
1076 |
lemma exp_le_one_iff [simp]: "exp (x::real) \<le> 1 \<longleftrightarrow> x \<le> 0" |
|
1077 |
using exp_le_cancel_iff [where x=x and y=0] by simp |
|
1078 |
||
1079 |
lemma exp_eq_one_iff [simp]: "exp (x::real) = 1 \<longleftrightarrow> x = 0" |
|
1080 |
using exp_inj_iff [where x=x and y=0] by simp |
|
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 | 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 | 1101 |
subsection {* Natural Logarithm *} |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
1102 |
|
23043 | 1103 |
definition |
1104 |
ln :: "real => real" where |
|
1105 |
"ln x = (THE u. exp u = x)" |
|
1106 |
||
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 | 1113 |
lemma exp_ln_iff [simp]: "exp (ln x) = x \<longleftrightarrow> 0 < x" |
1114 |
apply (rule iffI) |
|
1115 |
apply (erule subst, rule exp_gt_zero) |
|
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 | 1119 |
lemma ln_unique: "exp y = x \<Longrightarrow> ln x = y" |
1120 |
by (erule subst, rule ln_exp) |
|
1121 |
||
1122 |
lemma ln_one [simp]: "ln 1 = 0" |
|
1123 |
by (rule ln_unique, simp) |
|
1124 |
||
1125 |
lemma ln_mult: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln (x * y) = ln x + ln y" |
|
1126 |
by (rule ln_unique, simp add: exp_add) |
|
1127 |
||
1128 |
lemma ln_inverse: "0 < x \<Longrightarrow> ln (inverse x) = - ln x" |
|
1129 |
by (rule ln_unique, simp add: exp_minus) |
|
1130 |
||
1131 |
lemma ln_div: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln (x / y) = ln x - ln y" |
|
1132 |
by (rule ln_unique, simp add: exp_diff) |
|
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
1133 |
|
29171 | 1134 |
lemma ln_realpow: "0 < x \<Longrightarrow> ln (x ^ n) = real n * ln x" |
1135 |
by (rule ln_unique, simp add: exp_real_of_nat_mult) |
|
1136 |
||
1137 |
lemma ln_less_cancel_iff [simp]: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln x < ln y \<longleftrightarrow> x < y" |
|
1138 |
by (subst exp_less_cancel_iff [symmetric], simp) |
|
1139 |
||
1140 |
lemma ln_le_cancel_iff [simp]: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln x \<le> ln y \<longleftrightarrow> x \<le> y" |
|
1141 |
by (simp add: linorder_not_less [symmetric]) |
|
1142 |
||
1143 |
lemma ln_inj_iff [simp]: "\<lbrakk>0 < x; 0 < y\<rbrakk> \<Longrightarrow> ln x = ln y \<longleftrightarrow> x = y" |
|
1144 |
by (simp add: order_eq_iff) |
|
1145 |
||
1146 |
lemma ln_add_one_self_le_self [simp]: "0 \<le> x \<Longrightarrow> ln (1 + x) \<le> x" |
|
1147 |
apply (rule exp_le_cancel_iff [THEN iffD1]) |
|
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 | 1151 |
lemma ln_less_self [simp]: "0 < x \<Longrightarrow> ln x < x" |
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 | 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 | 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 | 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 | 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 | 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 | 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 | 1218 |
lemma DERIV_ln_divide: "0 < x ==> DERIV ln x :> 1 / x" |
1219 |
by (rule DERIV_ln[THEN DERIV_cong], simp, simp add: divide_inverse) |
|
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 | 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 | 1254 |
subsection {* Sine and Cosine *} |
1255 |
||
1256 |
definition |
|
31271 | 1257 |
sin_coeff :: "nat \<Rightarrow> real" where |
1258 |
"sin_coeff = (\<lambda>n. if even n then 0 else -1 ^ ((n - Suc 0) div 2) / real (fact n))" |
|
1259 |
||
1260 |
definition |
|
1261 |
cos_coeff :: "nat \<Rightarrow> real" where |
|
1262 |
"cos_coeff = (\<lambda>n. if even n then (-1 ^ (n div 2)) / real (fact n) else 0)" |
|
1263 |
||
1264 |
definition |
|
29164 | 1265 |
sin :: "real => real" where |
31271 | 1266 |
"sin x = (\<Sum>n. sin_coeff n * x ^ n)" |
1267 |
||
29164 | 1268 |
definition |
1269 |
cos :: "real => real" where |
|
31271 | 1270 |
"cos x = (\<Sum>n. cos_coeff n * x ^ n)" |
1271 |
||
1272 |
lemma summable_sin: "summable (\<lambda>n. sin_coeff n * x ^ n)" |
|
1273 |
unfolding sin_coeff_def |
|
29164 | 1274 |
apply (rule_tac g = "(%n. inverse (real (fact n)) * \<bar>x\<bar> ^ n)" in summable_comparison_test) |
1275 |
apply (rule_tac [2] summable_exp) |
|
1276 |
apply (rule_tac x = 0 in exI) |
|
1277 |
apply (auto simp add: divide_inverse abs_mult power_abs [symmetric] zero_le_mult_iff) |
|
1278 |
done |
|
1279 |
||
31271 | 1280 |
lemma summable_cos: "summable (\<lambda>n. cos_coeff n * x ^ n)" |
1281 |
unfolding cos_coeff_def |
|
29164 | 1282 |
apply (rule_tac g = "(%n. inverse (real (fact n)) * \<bar>x\<bar> ^ n)" in summable_comparison_test) |
1283 |
apply (rule_tac [2] summable_exp) |
|
1284 |
apply (rule_tac x = 0 in exI) |
|
1285 |
apply (auto simp add: divide_inverse abs_mult power_abs [symmetric] zero_le_mult_iff) |
|
1286 |
done |
|
1287 |
||
1288 |
lemma lemma_STAR_sin: |
|
41970 | 1289 |
"(if even n then 0 |
29164 | 1290 |
else -1 ^ ((n - Suc 0) div 2)/(real (fact n))) * 0 ^ n = 0" |
1291 |
by (induct "n", auto) |
|
1292 |
||
1293 |
lemma lemma_STAR_cos: |
|
41970 | 1294 |
"0 < n --> |
29164 | 1295 |
-1 ^ (n div 2)/(real (fact n)) * 0 ^ n = 0" |
1296 |
by (induct "n", auto) |
|
1297 |
||
1298 |
lemma lemma_STAR_cos1: |
|
41970 | 1299 |
"0 < n --> |
29164 | 1300 |
(-1) ^ (n div 2)/(real (fact n)) * 0 ^ n = 0" |
1301 |
by (induct "n", auto) |
|
1302 |
||
1303 |
lemma lemma_STAR_cos2: |
|
41970 | 1304 |
"(\<Sum>n=1..<n. if even n then -1 ^ (n div 2)/(real (fact n)) * 0 ^ n |
29164 | 1305 |
else 0) = 0" |
1306 |
apply (induct "n") |
|
1307 |
apply (case_tac [2] "n", auto) |
|
1308 |
done |
|
1309 |
||
31271 | 1310 |
lemma sin_converges: "(\<lambda>n. sin_coeff n * x ^ n) sums sin(x)" |
29164 | 1311 |
unfolding sin_def by (rule summable_sin [THEN summable_sums]) |
1312 |
||
31271 | 1313 |
lemma cos_converges: "(\<lambda>n. cos_coeff n * x ^ n) sums cos(x)" |
29164 | 1314 |
unfolding cos_def by (rule summable_cos [THEN summable_sums]) |
1315 |
||
31271 | 1316 |
lemma sin_fdiffs: "diffs sin_coeff = cos_coeff" |
1317 |
unfolding sin_coeff_def cos_coeff_def |
|
41970 | 1318 |
by (auto intro!: ext |
29164 | 1319 |
simp add: diffs_def divide_inverse real_of_nat_def of_nat_mult |
1320 |
simp del: mult_Suc of_nat_Suc) |
|
1321 |
||
31271 | 1322 |
lemma sin_fdiffs2: "diffs sin_coeff n = cos_coeff n" |
29164 | 1323 |
by (simp only: sin_fdiffs) |
1324 |
||
31271 | 1325 |
lemma cos_fdiffs: "diffs cos_coeff = (\<lambda>n. - sin_coeff n)" |
1326 |
unfolding sin_coeff_def cos_coeff_def |
|
41970 | 1327 |
by (auto intro!: ext |
29164 | 1328 |
simp add: diffs_def divide_inverse odd_Suc_mult_two_ex real_of_nat_def of_nat_mult |
1329 |
simp del: mult_Suc of_nat_Suc) |
|
1330 |
||
31271 | 1331 |
lemma cos_fdiffs2: "diffs cos_coeff n = - sin_coeff n" |
29164 | 1332 |
by (simp only: cos_fdiffs) |
1333 |
||
1334 |
text{*Now at last we can get the derivatives of exp, sin and cos*} |
|
1335 |
||
31271 | 1336 |
lemma lemma_sin_minus: "- sin x = (\<Sum>n. - (sin_coeff n * x ^ n))" |
29164 | 1337 |
by (auto intro!: sums_unique sums_minus sin_converges) |
1338 |
||
31271 | 1339 |
lemma lemma_sin_ext: "sin = (\<lambda>x. \<Sum>n. sin_coeff n * x ^ n)" |
29164 | 1340 |
by (auto intro!: ext simp add: sin_def) |
1341 |
||
31271 | 1342 |
lemma lemma_cos_ext: "cos = (\<lambda>x. \<Sum>n. cos_coeff n * x ^ n)" |
29164 | 1343 |
by (auto intro!: ext simp add: cos_def) |
1344 |
||
1345 |
lemma DERIV_sin [simp]: "DERIV sin x :> cos(x)" |
|
1346 |
apply (simp add: cos_def) |
|
1347 |
apply (subst lemma_sin_ext) |
|
1348 |
apply (auto simp add: sin_fdiffs2 [symmetric]) |
|
1349 |
apply (rule_tac K = "1 + \<bar>x\<bar>" in termdiffs) |
|
1350 |
apply (auto intro: sin_converges cos_converges sums_summable intro!: sums_minus [THEN sums_summable] simp add: cos_fdiffs sin_fdiffs) |
|
1351 |
done |
|
1352 |
||
1353 |
lemma DERIV_cos [simp]: "DERIV cos x :> -sin(x)" |
|
1354 |
apply (subst lemma_cos_ext) |
|
1355 |
apply (auto simp add: lemma_sin_minus cos_fdiffs2 [symmetric] minus_mult_left) |
|
1356 |
apply (rule_tac K = "1 + \<bar>x\<bar>" in termdiffs) |
|
1357 |
apply (auto intro: sin_converges cos_converges sums_summable intro!: sums_minus [THEN sums_summable] simp add: cos_fdiffs sin_fdiffs diffs_minus) |
|
1358 |
done |
|
1359 |
||
1360 |
lemma isCont_sin [simp]: "isCont sin x" |
|
1361 |
by (rule DERIV_sin [THEN DERIV_isCont]) |
|
1362 |
||
1363 |
lemma isCont_cos [simp]: "isCont cos x" |
|
1364 |
by (rule DERIV_cos [THEN DERIV_isCont]) |
|
1365 |
||
1366 |
||
31880 | 1367 |
declare |
1368 |
DERIV_exp[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros] |
|
1369 |
DERIV_ln[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros] |
|
1370 |
DERIV_sin[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros] |
|
1371 |
DERIV_cos[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros] |
|
1372 |
||
29164 | 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 | 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 | 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 | 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 | 1424 |
lemma DERIV_cos_cos_mult3 [simp]: |
1425 |
"DERIV (%x. cos(x)*cos(x)) x :> -(2 * cos(x) * sin(x))" |
|
31881 | 1426 |
by (auto intro!: DERIV_intros) |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
1427 |
|
41970 | 1428 |
lemma DERIV_sin_circle_all: |
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 | 1431 |
by (auto intro!: DERIV_intros) |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
1432 |
|
15229 | 1433 |
lemma DERIV_sin_circle_all_zero [simp]: |
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 | 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 | 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 | 1462 |
lemma abs_sin_le_one [simp]: "\<bar>sin x\<bar> \<le> 1" |
23097 | 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 | 1466 |
apply (insert abs_sin_le_one [of x]) |
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 | 1471 |
apply (insert abs_sin_le_one [of x]) |
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 | 1475 |
lemma abs_cos_le_one [simp]: "\<bar>cos x\<bar> \<le> 1" |
23097 | 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 | 1479 |
apply (insert abs_cos_le_one [of x]) |
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 | 1484 |
apply (insert abs_cos_le_one [of x]) |
22998 | 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 | 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 | 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 | 1496 |
lemma DERIV_fun_exp: |
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 | 1503 |
lemma DERIV_fun_sin: |
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 | 1510 |
lemma DERIV_fun_cos: |
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 | 1518 |
lemma lemma_DERIV_sin_cos_add: |
41970 | 1519 |
"\<forall>x. |
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 | 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 | 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 | 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 | 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 | 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 | 1544 |
by (auto intro!: DERIV_intros simp add: algebra_simps) |
1545 |
||
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
1546 |
|
41970 | 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 | 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 | 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 | 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 | 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 | 1580 |
subsection {* The Constant Pi *} |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
1581 |
|
23043 | 1582 |
definition |
1583 |
pi :: "real" where |
|
23053 | 1584 |
"pi = 2 * (THE x. 0 \<le> (x::real) & x \<le> 2 & cos x = 0)" |
23043 | 1585 |
|
41970 | 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 | 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 | 1593 |
have "(\<lambda>n. \<Sum>k = n * 2..<n * 2 + 2. sin_coeff k * x ^ k) sums sin x" |
23176 | 1594 |
unfolding sin_def |
41970 | 1595 |
by (rule sin_converges [THEN sums_summable, THEN sums_group], simp) |
31271 | 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 | 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 | 1603 |
-1 ^ k / real (fact (2 * k + 1)) * x ^ (2 * k + 1)) |
23177 | 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 | 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 | 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 | 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 | 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 | 1618 |
apply (subgoal_tac "6 * (x * (x * x) / real (Suc (Suc (Suc (Suc (Suc (Suc 0))))))) < 6 * x") |
1619 |
apply (simp only: mult_less_cancel_left, simp) |
|
15539 | 1620 |
apply (simp (no_asm_simp) add: numeral_2_eq_2 [symmetric] mult_assoc [symmetric]) |
41970 | 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 | 1623 |
apply (auto simp add: real_0_less_add_iff real_of_nat_Suc simp del: fact_Suc) |
1624 |
apply (subst fact_Suc) |
|
1625 |
apply (subst fact_Suc) |
|
1626 |
apply (subst fact_Suc) |
|
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 | 1632 |
apply (simp (no_asm) add: divide_inverse del: fact_Suc) |
1633 |
apply (auto simp add: mult_assoc [symmetric] simp del: fact_Suc) |
|
41970 | 1634 |
apply (rule_tac c="real (Suc (Suc (4*m)))" in mult_less_imp_less_right) |
32047 | 1635 |
apply (auto simp add: mult_assoc simp del: fact_Suc) |
41970 | 1636 |
apply (rule_tac c="real (Suc (Suc (Suc (4*m))))" in mult_less_imp_less_right) |
32047 | 1637 |
apply (auto simp add: mult_assoc mult_less_cancel_left simp del: fact_Suc) |
41970 | 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 | 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 | 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 | 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 | 1659 |
have "(\<lambda>n. \<Sum>k = n * 2..<n * 2 + 2. cos_coeff k * x ^ k) sums cos x" |
23176 | 1660 |
unfolding cos_def |
41970 | 1661 |
by (rule cos_converges [THEN sums_summable, THEN sums_group], simp) |
31271 | 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 | 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 | 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 | 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 | 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 | 1691 |
apply (rule neg_less_iff_less [THEN iffD1]) |
15539 | 1692 |
apply (frule sums_unique, auto) |
1693 |
apply (rule_tac y = |
|
23177 | 1694 |
"\<Sum>n=0..< Suc(Suc(Suc 0)). - (-1 ^ n / (real(fact (2*n))) * 2 ^ (2*n))" |
15481 | 1695 |
in order_less_trans) |
32047 | 1696 |
apply (simp (no_asm) add: fact_num_eq_if_nat realpow_num_eq_if del: fact_Suc) |
15561 | 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 | 1701 |
apply (simp (no_asm) add: divide_inverse real_0_less_add_iff mult_assoc [symmetric] |
32047 | 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 | 1705 |
apply (simp (no_asm) add: mult_assoc [symmetric] del: fact_Suc) |
41970 | 1706 |
apply (subst fact_lemma) |
32047 | 1707 |
apply (subst fact_Suc [of "Suc (Suc (Suc (Suc (Suc (Suc (Suc (4 * d)))))))"]) |
15481 | 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 | 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 | 1715 |
|
1716 |
lemmas cos_two_neq_zero [simp] = cos_two_less_zero [THEN less_imp_neq] |
|
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 | 1733 |
|
23053 | 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 | 1738 |
by (simp add: pi_half cos_is_zero [THEN theI']) |
1739 |
||
1740 |
lemma pi_half_gt_zero [simp]: "0 < pi / 2" |
|
1741 |
apply (rule order_le_neq_trans) |
|
1742 |
apply (simp add: pi_half cos_is_zero [THEN theI']) |
|
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 | 1746 |
lemmas pi_half_neq_zero [simp] = pi_half_gt_zero [THEN less_imp_neq, symmetric] |
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 | 1749 |
lemma pi_half_less_two [simp]: "pi / 2 < 2" |
1750 |
apply (rule order_le_neq_trans) |
|
1751 |
apply (simp add: pi_half cos_is_zero [THEN theI']) |
|
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 | 1754 |
|
1755 |
lemmas pi_half_neq_two [simp] = pi_half_less_two [THEN less_imp_neq] |
|
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 | 1759 |
by (insert pi_half_gt_zero, simp) |
1760 |
||
1761 |
lemma pi_ge_zero [simp]: "0 \<le> pi" |
|
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 | 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 | 1767 |
lemma pi_not_less_zero [simp]: "\<not> pi < 0" |
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 | 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 | 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 | 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 | 1792 |
by (simp add: diff_minus cos_add) |
23053 | 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 | 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 | 1800 |
by (simp add: diff_minus sin_add) |
23053 | 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 | 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 | 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 | 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 | 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 | 1823 |
lemma cos_npi2 [simp]: "cos (pi * real n) = -1 ^ n" |
1824 |
proof - |
|
1825 |
have "cos (pi * real n) = cos (real n * pi)" by (simp only: mult_commute) |
|
41970 | 1826 |
also have "... = -1 ^ n" by (rule cos_npi) |
15383 | 1827 |
finally show ?thesis . |
1828 |
qed |
|
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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 1931 |
apply (rule_tac a = "x - (pi/2)" in ex1I) |
23286 | 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 | 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 | 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 | 1942 |
prefer 2 apply (erule LeastI) |
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 | 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 | 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 | 1950 |
lemma cos_zero_lemma: |
41970 | 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 | 1954 |
apply (subgoal_tac "0 \<le> x - real n * pi & |
15086 | 1955 |
(x - real n * pi) \<le> pi & (cos (x - real n * pi) = 0) ") |
29667 | 1956 |
apply (auto simp add: algebra_simps real_of_nat_Suc) |
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 | 1964 |
apply (rule_tac x = "Suc (2 * n)" in exI) |
29667 | 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 | 1968 |
lemma sin_zero_lemma: |
41970 | 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 | 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 | 1979 |
lemma cos_zero_iff: |
41970 | 1980 |
"(cos x = 0) = |
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 | 1986 |
apply (cut_tac x="-x" in cos_zero_lemma, simp, simp) |
1987 |
apply (force simp add: minus_equation_iff [of x]) |
|
1988 |
apply (auto simp only: odd_Suc_mult_two_ex real_of_nat_Suc left_distrib) |
|
15539 | 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 | 1993 |
lemma sin_zero_iff: |
41970 | 1994 |
"(sin x = 0) = |
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 | 2001 |
apply (force simp add: minus_equation_iff [of x]) |
15539 | 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 | 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 | 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 | 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 | 2044 |
have "0 \<le> y + pi / 2" and "y + pi / 2 \<le> x + pi / 2" and "x + pi /2 \<le> pi" |
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 | 2049 |
subsection {* Tangent *} |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
2050 |
|
23043 | 2051 |
definition |
2052 |
tan :: "real => real" where |
|
2053 |
"tan x = (sin x)/(cos x)" |
|
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 | 2070 |
lemma lemma_tan_add1: |
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 | 2073 |
apply (simp add: tan_def divide_inverse) |
41970 | 2074 |
apply (auto simp del: inverse_mult_distrib |
15229 | 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 | 2077 |
apply (auto simp del: inverse_mult_distrib |
15229 | 2078 |
simp add: mult_assoc left_diff_distrib cos_add) |
29667 | 2079 |
done |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
2080 |
|
41970 | 2081 |
lemma add_tan_eq: |
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 | 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 | 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 | 2090 |
lemma tan_add: |
41970 | 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 | 2097 |
lemma tan_double: |
41970 | 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 | 2100 |
apply (insert tan_add [of x x]) |
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 | 2106 |
by (simp add: tan_def zero_less_divide_iff sin_gt_zero2 cos_gt_zero_pi) |
2107 |
||
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 | 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 | 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 | 2143 |
apply (simp add: divide_inverse [symmetric]) |
22613 | 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 | 2147 |
apply (simp_all add: divide_inverse [symmetric]) |
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 | 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 | 2159 |
apply (drule_tac x = "(pi/2) - e" in spec) |
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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 2268 |
|
2269 |
subsection {* Inverse Trigonometric Functions *} |
|
2270 |
||
2271 |
definition |
|
2272 |
arcsin :: "real => real" where |
|
2273 |
"arcsin y = (THE x. -(pi/2) \<le> x & x \<le> pi/2 & sin x = y)" |
|
2274 |
||
2275 |
definition |
|
2276 |
arccos :: "real => real" where |
|
2277 |
"arccos y = (THE x. 0 \<le> x & x \<le> pi & cos x = y)" |
|
2278 |
||
41970 | 2279 |
definition |
23043 | 2280 |
arctan :: "real => real" where |
2281 |
"arctan y = (THE x. -(pi/2) < x & x < pi/2 & tan x = y)" |
|
2282 |
||
15229 | 2283 |
lemma arcsin: |
41970 | 2284 |
"[| -1 \<le> y; y \<le> 1 |] |
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 | 2287 |
unfolding arcsin_def by (rule theI' [OF sin_total]) |
2288 |
||
2289 |
lemma arcsin_pi: |
|
41970 | 2290 |
"[| -1 \<le> y; y \<le> 1 |] |
23011 | 2291 |
==> -(pi/2) \<le> arcsin y & arcsin y \<le> pi & sin(arcsin y) = y" |
2292 |
apply (drule (1) arcsin) |
|
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 | 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 | 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 | 2326 |
lemma arccos: |
41970 | 2327 |
"[| -1 \<le> y; y \<le> 1 |] |
22975 | 2328 |
==> 0 \<le> arccos y & arccos y \<le> pi & cos(arccos y) = y" |
23011 | 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 | 2331 |
lemma cos_arccos [simp]: "[| -1 \<le> y; y \<le> 1 |] ==> cos(arccos y) = y" |
2332 |
by (blast dest: arccos) |
|
41970 | 2333 |
|
22975 | 2334 |
lemma arccos_bounded: "[| -1 \<le> y; y \<le> 1 |] ==> 0 \<le> arccos y & arccos y \<le> pi" |
2335 |
by (blast dest: arccos) |
|
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
2336 |
|
22975 | 2337 |
lemma arccos_lbound: "[| -1 \<le> y; y \<le> 1 |] ==> 0 \<le> arccos y" |
2338 |
by (blast dest: arccos) |
|
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
2339 |
|
22975 | 2340 |
lemma arccos_ubound: "[| -1 \<le> y; y \<le> 1 |] ==> arccos y \<le> pi" |
2341 |
by (blast dest: arccos) |
|
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
2342 |
|
22975 | 2343 |
lemma arccos_lt_bounded: |
41970 | 2344 |
"[| -1 < y; y < 1 |] |
22975 | 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 | 2348 |
apply (frule arccos_bounded, auto) |
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 | 2354 |
lemma arccos_cos: "[|0 \<le> x; x \<le> pi |] ==> arccos(cos x) = x" |
2355 |
apply (simp add: arccos_def) |
|
23011 | 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 | 2359 |
lemma arccos_cos2: "[|x \<le> 0; -pi \<le> x |] ==> arccos(cos x) = -x" |
2360 |
apply (simp add: arccos_def) |
|
23011 | 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 | 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 | 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 | 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 | 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 | 2426 |
apply (auto dest: field_power_not_zero |
41970 | 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 | 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 | 2503 |
declare |
2504 |
DERIV_arcsin[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros] |
|
2505 |
DERIV_arccos[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros] |
|
2506 |
DERIV_arctan[THEN DERIV_chain2, THEN DERIV_cong, DERIV_intros] |
|
2507 |
||
23043 | 2508 |
subsection {* More Theorems about Sin and Cos *} |
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 | 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 | 2585 |
by (auto intro!: DERIV_intros) |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
2586 |
|
15383 | 2587 |
lemma sin_cos_npi [simp]: "sin (real (Suc (2 * n)) * pi / 2) = (-1) ^ n" |
2588 |
proof - |
|
2589 |
have "sin ((real n + 1/2) * pi) = cos (real n * pi)" |
|
29667 | 2590 |
by (auto simp add: algebra_simps sin_add) |
15383 | 2591 |
thus ?thesis |
41970 | 2592 |
by (simp add: real_of_nat_Suc left_distrib add_divide_distrib |
15383 | 2593 |
mult_commute [of pi]) |
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 | 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 | 2616 |
by (auto intro!: DERIV_intros) |
15077
89840837108e
converting Hyperreal/Transcendental to Isar script
paulson
parents:
15013
diff
changeset
|
2617 |
|
15081 | 2618 |
lemma sin_zero_abs_cos_one: "sin x = 0 ==> \<bar>cos x\<bar> = 1" |
15539 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 2899 |
unfolding Suc_eq_plus1[symmetric] power_Suc2 mult_zero_right arctan_zero_zero suminf_zero by auto |
41970 | 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 | 2907 |
by (rule suminf_eq_arctan_bounded[where x="0" and a="-\<bar>x\<bar>" and b="\<bar>x\<bar>", symmetric]) |
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 | 2911 |
by (rule suminf_eq_arctan_bounded[where x="x" and a="-\<bar>x\<bar>" and b="\<bar>x\<bar>"]) |
2912 |
(simp_all only: `\<bar>x\<bar> < r` `-\<bar>x\<bar> < \<bar>x\<bar>` neg_less_iff_less) |
|
41970 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 | 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 |