src/HOL/Deriv.thy
author wenzelm
Thu Jul 02 17:34:14 2009 +0200 (2009-07-02)
changeset 31902 862ae16a799d
parent 31899 1a7ade46061b
child 33654 abf780db30ea
permissions -rw-r--r--
renamed NamedThmsFun to Named_Thms;
simplified/unified names of instances of Named_Thms;
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(*  Title       : Deriv.thy
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    Author      : Jacques D. Fleuriot
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    Copyright   : 1998  University of Cambridge
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    Conversion to Isar and new proofs by Lawrence C Paulson, 2004
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    GMVT by Benjamin Porter, 2005
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*)
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header{* Differentiation *}
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theory Deriv
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imports Lim
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begin
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text{*Standard Definitions*}
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definition
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  deriv :: "['a::real_normed_field \<Rightarrow> 'a, 'a, 'a] \<Rightarrow> bool"
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    --{*Differentiation: D is derivative of function f at x*}
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          ("(DERIV (_)/ (_)/ :> (_))" [1000, 1000, 60] 60) where
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  "DERIV f x :> D = ((%h. (f(x + h) - f x) / h) -- 0 --> D)"
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consts
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  Bolzano_bisect :: "[real*real=>bool, real, real, nat] => (real*real)"
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primrec
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  "Bolzano_bisect P a b 0 = (a,b)"
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  "Bolzano_bisect P a b (Suc n) =
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      (let (x,y) = Bolzano_bisect P a b n
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       in if P(x, (x+y)/2) then ((x+y)/2, y)
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                            else (x, (x+y)/2))"
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subsection {* Derivatives *}
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lemma DERIV_iff: "(DERIV f x :> D) = ((%h. (f(x + h) - f(x))/h) -- 0 --> D)"
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by (simp add: deriv_def)
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lemma DERIV_D: "DERIV f x :> D ==> (%h. (f(x + h) - f(x))/h) -- 0 --> D"
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by (simp add: deriv_def)
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lemma DERIV_const [simp]: "DERIV (\<lambda>x. k) x :> 0"
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by (simp add: deriv_def)
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lemma DERIV_ident [simp]: "DERIV (\<lambda>x. x) x :> 1"
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by (simp add: deriv_def cong: LIM_cong)
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lemma add_diff_add:
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  fixes a b c d :: "'a::ab_group_add"
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  shows "(a + c) - (b + d) = (a - b) + (c - d)"
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by simp
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lemma DERIV_add:
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  "\<lbrakk>DERIV f x :> D; DERIV g x :> E\<rbrakk> \<Longrightarrow> DERIV (\<lambda>x. f x + g x) x :> D + E"
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by (simp only: deriv_def add_diff_add add_divide_distrib LIM_add)
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lemma DERIV_minus:
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  "DERIV f x :> D \<Longrightarrow> DERIV (\<lambda>x. - f x) x :> - D"
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by (simp only: deriv_def minus_diff_minus divide_minus_left LIM_minus)
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lemma DERIV_diff:
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  "\<lbrakk>DERIV f x :> D; DERIV g x :> E\<rbrakk> \<Longrightarrow> DERIV (\<lambda>x. f x - g x) x :> D - E"
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by (simp only: diff_def DERIV_add DERIV_minus)
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lemma DERIV_add_minus:
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  "\<lbrakk>DERIV f x :> D; DERIV g x :> E\<rbrakk> \<Longrightarrow> DERIV (\<lambda>x. f x + - g x) x :> D + - E"
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by (simp only: DERIV_add DERIV_minus)
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lemma DERIV_isCont: "DERIV f x :> D \<Longrightarrow> isCont f x"
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proof (unfold isCont_iff)
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  assume "DERIV f x :> D"
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  hence "(\<lambda>h. (f(x+h) - f(x)) / h) -- 0 --> D"
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    by (rule DERIV_D)
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  hence "(\<lambda>h. (f(x+h) - f(x)) / h * h) -- 0 --> D * 0"
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    by (intro LIM_mult LIM_ident)
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  hence "(\<lambda>h. (f(x+h) - f(x)) * (h / h)) -- 0 --> 0"
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    by simp
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  hence "(\<lambda>h. f(x+h) - f(x)) -- 0 --> 0"
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    by (simp cong: LIM_cong)
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  thus "(\<lambda>h. f(x+h)) -- 0 --> f(x)"
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    by (simp add: LIM_def dist_norm)
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qed
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lemma DERIV_mult_lemma:
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  fixes a b c d :: "'a::real_field"
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  shows "(a * b - c * d) / h = a * ((b - d) / h) + ((a - c) / h) * d"
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by (simp add: diff_minus add_divide_distrib [symmetric] ring_distribs)
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lemma DERIV_mult':
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  assumes f: "DERIV f x :> D"
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  assumes g: "DERIV g x :> E"
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  shows "DERIV (\<lambda>x. f x * g x) x :> f x * E + D * g x"
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proof (unfold deriv_def)
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  from f have "isCont f x"
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    by (rule DERIV_isCont)
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  hence "(\<lambda>h. f(x+h)) -- 0 --> f x"
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    by (simp only: isCont_iff)
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  hence "(\<lambda>h. f(x+h) * ((g(x+h) - g x) / h) +
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              ((f(x+h) - f x) / h) * g x)
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          -- 0 --> f x * E + D * g x"
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    by (intro LIM_add LIM_mult LIM_const DERIV_D f g)
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  thus "(\<lambda>h. (f(x+h) * g(x+h) - f x * g x) / h)
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         -- 0 --> f x * E + D * g x"
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    by (simp only: DERIV_mult_lemma)
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qed
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lemma DERIV_mult:
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     "[| DERIV f x :> Da; DERIV g x :> Db |]
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      ==> DERIV (%x. f x * g x) x :> (Da * g(x)) + (Db * f(x))"
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by (drule (1) DERIV_mult', simp only: mult_commute add_commute)
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lemma DERIV_unique:
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      "[| DERIV f x :> D; DERIV f x :> E |] ==> D = E"
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apply (simp add: deriv_def)
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apply (blast intro: LIM_unique)
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done
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text{*Differentiation of finite sum*}
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lemma DERIV_setsum:
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  assumes "finite S"
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  and "\<And> n. n \<in> S \<Longrightarrow> DERIV (%x. f x n) x :> (f' x n)"
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  shows "DERIV (%x. setsum (f x) S) x :> setsum (f' x) S"
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  using assms by induct (auto intro!: DERIV_add)
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lemma DERIV_sumr [rule_format (no_asm)]:
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     "(\<forall>r. m \<le> r & r < (m + n) --> DERIV (%x. f r x) x :> (f' r x))
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      --> DERIV (%x. \<Sum>n=m..<n::nat. f n x :: real) x :> (\<Sum>r=m..<n. f' r x)"
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  by (auto intro: DERIV_setsum)
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text{*Alternative definition for differentiability*}
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lemma DERIV_LIM_iff:
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  fixes f :: "'a::{real_normed_vector,inverse} \<Rightarrow> 'a" shows
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     "((%h. (f(a + h) - f(a)) / h) -- 0 --> D) =
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      ((%x. (f(x)-f(a)) / (x-a)) -- a --> D)"
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apply (rule iffI)
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apply (drule_tac k="- a" in LIM_offset)
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apply (simp add: diff_minus)
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apply (drule_tac k="a" in LIM_offset)
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apply (simp add: add_commute)
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done
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lemma DERIV_iff2: "(DERIV f x :> D) = ((%z. (f(z) - f(x)) / (z-x)) -- x --> D)"
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by (simp add: deriv_def diff_minus [symmetric] DERIV_LIM_iff)
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lemma inverse_diff_inverse:
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  "\<lbrakk>(a::'a::division_ring) \<noteq> 0; b \<noteq> 0\<rbrakk>
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   \<Longrightarrow> inverse a - inverse b = - (inverse a * (a - b) * inverse b)"
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by (simp add: algebra_simps)
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lemma DERIV_inverse_lemma:
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  "\<lbrakk>a \<noteq> 0; b \<noteq> (0::'a::real_normed_field)\<rbrakk>
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   \<Longrightarrow> (inverse a - inverse b) / h
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     = - (inverse a * ((a - b) / h) * inverse b)"
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by (simp add: inverse_diff_inverse)
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lemma DERIV_inverse':
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  assumes der: "DERIV f x :> D"
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  assumes neq: "f x \<noteq> 0"
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  shows "DERIV (\<lambda>x. inverse (f x)) x :> - (inverse (f x) * D * inverse (f x))"
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    (is "DERIV _ _ :> ?E")
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proof (unfold DERIV_iff2)
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  from der have lim_f: "f -- x --> f x"
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    by (rule DERIV_isCont [unfolded isCont_def])
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  from neq have "0 < norm (f x)" by simp
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  with LIM_D [OF lim_f] obtain s
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    where s: "0 < s"
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    and less_fx: "\<And>z. \<lbrakk>z \<noteq> x; norm (z - x) < s\<rbrakk>
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                  \<Longrightarrow> norm (f z - f x) < norm (f x)"
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    by fast
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  show "(\<lambda>z. (inverse (f z) - inverse (f x)) / (z - x)) -- x --> ?E"
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  proof (rule LIM_equal2 [OF s])
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    fix z
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    assume "z \<noteq> x" "norm (z - x) < s"
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    hence "norm (f z - f x) < norm (f x)" by (rule less_fx)
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    hence "f z \<noteq> 0" by auto
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    thus "(inverse (f z) - inverse (f x)) / (z - x) =
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          - (inverse (f z) * ((f z - f x) / (z - x)) * inverse (f x))"
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      using neq by (rule DERIV_inverse_lemma)
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  next
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    from der have "(\<lambda>z. (f z - f x) / (z - x)) -- x --> D"
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      by (unfold DERIV_iff2)
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    thus "(\<lambda>z. - (inverse (f z) * ((f z - f x) / (z - x)) * inverse (f x)))
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          -- x --> ?E"
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      by (intro LIM_mult LIM_inverse LIM_minus LIM_const lim_f neq)
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  qed
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qed
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lemma DERIV_divide:
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  "\<lbrakk>DERIV f x :> D; DERIV g x :> E; g x \<noteq> 0\<rbrakk>
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   \<Longrightarrow> DERIV (\<lambda>x. f x / g x) x :> (D * g x - f x * E) / (g x * g x)"
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apply (subgoal_tac "f x * - (inverse (g x) * E * inverse (g x)) +
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          D * inverse (g x) = (D * g x - f x * E) / (g x * g x)")
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apply (erule subst)
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apply (unfold divide_inverse)
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apply (erule DERIV_mult')
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apply (erule (1) DERIV_inverse')
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apply (simp add: ring_distribs nonzero_inverse_mult_distrib)
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apply (simp add: mult_ac)
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done
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lemma DERIV_power_Suc:
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  fixes f :: "'a \<Rightarrow> 'a::{real_normed_field}"
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  assumes f: "DERIV f x :> D"
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  shows "DERIV (\<lambda>x. f x ^ Suc n) x :> (1 + of_nat n) * (D * f x ^ n)"
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proof (induct n)
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case 0
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  show ?case by (simp add: f)
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case (Suc k)
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  from DERIV_mult' [OF f Suc] show ?case
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    apply (simp only: of_nat_Suc ring_distribs mult_1_left)
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    apply (simp only: power_Suc algebra_simps)
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    done
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qed
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lemma DERIV_power:
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  fixes f :: "'a \<Rightarrow> 'a::{real_normed_field}"
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  assumes f: "DERIV f x :> D"
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  shows "DERIV (\<lambda>x. f x ^ n) x :> of_nat n * (D * f x ^ (n - Suc 0))"
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by (cases "n", simp, simp add: DERIV_power_Suc f del: power_Suc)
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text {* Caratheodory formulation of derivative at a point *}
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lemma CARAT_DERIV:
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     "(DERIV f x :> l) =
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      (\<exists>g. (\<forall>z. f z - f x = g z * (z-x)) & isCont g x & g x = l)"
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      (is "?lhs = ?rhs")
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proof
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  assume der: "DERIV f x :> l"
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  show "\<exists>g. (\<forall>z. f z - f x = g z * (z-x)) \<and> isCont g x \<and> g x = l"
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  proof (intro exI conjI)
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    let ?g = "(%z. if z = x then l else (f z - f x) / (z-x))"
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    show "\<forall>z. f z - f x = ?g z * (z-x)" by simp
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    show "isCont ?g x" using der
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      by (simp add: isCont_iff DERIV_iff diff_minus
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               cong: LIM_equal [rule_format])
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    show "?g x = l" by simp
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  qed
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next
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  assume "?rhs"
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  then obtain g where
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    "(\<forall>z. f z - f x = g z * (z-x))" and "isCont g x" and "g x = l" by blast
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  thus "(DERIV f x :> l)"
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     by (auto simp add: isCont_iff DERIV_iff cong: LIM_cong)
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qed
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lemma DERIV_chain':
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  assumes f: "DERIV f x :> D"
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  assumes g: "DERIV g (f x) :> E"
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  shows "DERIV (\<lambda>x. g (f x)) x :> E * D"
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proof (unfold DERIV_iff2)
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  obtain d where d: "\<forall>y. g y - g (f x) = d y * (y - f x)"
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    and cont_d: "isCont d (f x)" and dfx: "d (f x) = E"
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    using CARAT_DERIV [THEN iffD1, OF g] by fast
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  from f have "f -- x --> f x"
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    by (rule DERIV_isCont [unfolded isCont_def])
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  with cont_d have "(\<lambda>z. d (f z)) -- x --> d (f x)"
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    by (rule isCont_LIM_compose)
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  hence "(\<lambda>z. d (f z) * ((f z - f x) / (z - x)))
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          -- x --> d (f x) * D"
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    by (rule LIM_mult [OF _ f [unfolded DERIV_iff2]])
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  thus "(\<lambda>z. (g (f z) - g (f x)) / (z - x)) -- x --> E * D"
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    by (simp add: d dfx real_scaleR_def)
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qed
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text {*
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 Let's do the standard proof, though theorem
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 @{text "LIM_mult2"} follows from a NS proof
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*}
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lemma DERIV_cmult:
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      "DERIV f x :> D ==> DERIV (%x. c * f x) x :> c*D"
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by (drule DERIV_mult' [OF DERIV_const], simp)
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text {* Standard version *}
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lemma DERIV_chain: "[| DERIV f (g x) :> Da; DERIV g x :> Db |] ==> DERIV (f o g) x :> Da * Db"
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by (drule (1) DERIV_chain', simp add: o_def real_scaleR_def mult_commute)
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lemma DERIV_chain2: "[| DERIV f (g x) :> Da; DERIV g x :> Db |] ==> DERIV (%x. f (g x)) x :> Da * Db"
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by (auto dest: DERIV_chain simp add: o_def)
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text {* Derivative of linear multiplication *}
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lemma DERIV_cmult_Id [simp]: "DERIV (op * c) x :> c"
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by (cut_tac c = c and x = x in DERIV_ident [THEN DERIV_cmult], simp)
huffman@21164
   286
huffman@21164
   287
lemma DERIV_pow: "DERIV (%x. x ^ n) x :> real n * (x ^ (n - Suc 0))"
huffman@23069
   288
apply (cut_tac DERIV_power [OF DERIV_ident])
huffman@21164
   289
apply (simp add: real_scaleR_def real_of_nat_def)
huffman@21164
   290
done
huffman@21164
   291
wenzelm@31899
   292
text {* Power of @{text "-1"} *}
huffman@21164
   293
huffman@21784
   294
lemma DERIV_inverse:
haftmann@31017
   295
  fixes x :: "'a::{real_normed_field}"
huffman@21784
   296
  shows "x \<noteq> 0 ==> DERIV (%x. inverse(x)) x :> (-(inverse x ^ Suc (Suc 0)))"
huffman@30273
   297
by (drule DERIV_inverse' [OF DERIV_ident]) simp
huffman@21164
   298
wenzelm@31899
   299
text {* Derivative of inverse *}
huffman@21784
   300
lemma DERIV_inverse_fun:
haftmann@31017
   301
  fixes x :: "'a::{real_normed_field}"
huffman@21784
   302
  shows "[| DERIV f x :> d; f(x) \<noteq> 0 |]
huffman@21784
   303
      ==> DERIV (%x. inverse(f x)) x :> (- (d * inverse(f(x) ^ Suc (Suc 0))))"
huffman@30273
   304
by (drule (1) DERIV_inverse') (simp add: mult_ac nonzero_inverse_mult_distrib)
huffman@21164
   305
wenzelm@31899
   306
text {* Derivative of quotient *}
huffman@21784
   307
lemma DERIV_quotient:
haftmann@31017
   308
  fixes x :: "'a::{real_normed_field}"
huffman@21784
   309
  shows "[| DERIV f x :> d; DERIV g x :> e; g(x) \<noteq> 0 |]
huffman@21784
   310
       ==> DERIV (%y. f(y) / (g y)) x :> (d*g(x) - (e*f(x))) / (g(x) ^ Suc (Suc 0))"
huffman@30273
   311
by (drule (2) DERIV_divide) (simp add: mult_commute)
huffman@21164
   312
huffman@29975
   313
lemma lemma_DERIV_subst: "[| DERIV f x :> D; D = E |] ==> DERIV f x :> E"
huffman@29975
   314
by auto
huffman@29975
   315
wenzelm@31899
   316
text {* @{text "DERIV_intros"} *}
wenzelm@31899
   317
ML {*
wenzelm@31902
   318
structure Deriv_Intros = Named_Thms
wenzelm@31899
   319
(
wenzelm@31899
   320
  val name = "DERIV_intros"
wenzelm@31899
   321
  val description = "DERIV introduction rules"
wenzelm@31899
   322
)
wenzelm@31899
   323
*}
hoelzl@31880
   324
wenzelm@31902
   325
setup Deriv_Intros.setup
hoelzl@31880
   326
hoelzl@31880
   327
lemma DERIV_cong: "\<lbrakk> DERIV f x :> X ; X = Y \<rbrakk> \<Longrightarrow> DERIV f x :> Y"
hoelzl@31880
   328
  by simp
hoelzl@31880
   329
hoelzl@31880
   330
declare
hoelzl@31880
   331
  DERIV_const[THEN DERIV_cong, DERIV_intros]
hoelzl@31880
   332
  DERIV_ident[THEN DERIV_cong, DERIV_intros]
hoelzl@31880
   333
  DERIV_add[THEN DERIV_cong, DERIV_intros]
hoelzl@31880
   334
  DERIV_minus[THEN DERIV_cong, DERIV_intros]
hoelzl@31880
   335
  DERIV_mult[THEN DERIV_cong, DERIV_intros]
hoelzl@31880
   336
  DERIV_diff[THEN DERIV_cong, DERIV_intros]
hoelzl@31880
   337
  DERIV_inverse'[THEN DERIV_cong, DERIV_intros]
hoelzl@31880
   338
  DERIV_divide[THEN DERIV_cong, DERIV_intros]
hoelzl@31880
   339
  DERIV_power[where 'a=real, THEN DERIV_cong,
hoelzl@31880
   340
              unfolded real_of_nat_def[symmetric], DERIV_intros]
hoelzl@31880
   341
  DERIV_setsum[THEN DERIV_cong, DERIV_intros]
huffman@22984
   342
wenzelm@31899
   343
huffman@22984
   344
subsection {* Differentiability predicate *}
huffman@21164
   345
huffman@29169
   346
definition
huffman@29169
   347
  differentiable :: "['a::real_normed_field \<Rightarrow> 'a, 'a] \<Rightarrow> bool"
huffman@29169
   348
    (infixl "differentiable" 60) where
huffman@29169
   349
  "f differentiable x = (\<exists>D. DERIV f x :> D)"
huffman@29169
   350
huffman@29169
   351
lemma differentiableE [elim?]:
huffman@29169
   352
  assumes "f differentiable x"
huffman@29169
   353
  obtains df where "DERIV f x :> df"
huffman@29169
   354
  using prems unfolding differentiable_def ..
huffman@29169
   355
huffman@21164
   356
lemma differentiableD: "f differentiable x ==> \<exists>D. DERIV f x :> D"
huffman@21164
   357
by (simp add: differentiable_def)
huffman@21164
   358
huffman@21164
   359
lemma differentiableI: "DERIV f x :> D ==> f differentiable x"
huffman@21164
   360
by (force simp add: differentiable_def)
huffman@21164
   361
huffman@29169
   362
lemma differentiable_ident [simp]: "(\<lambda>x. x) differentiable x"
huffman@29169
   363
  by (rule DERIV_ident [THEN differentiableI])
huffman@29169
   364
huffman@29169
   365
lemma differentiable_const [simp]: "(\<lambda>z. a) differentiable x"
huffman@29169
   366
  by (rule DERIV_const [THEN differentiableI])
huffman@21164
   367
huffman@29169
   368
lemma differentiable_compose:
huffman@29169
   369
  assumes f: "f differentiable (g x)"
huffman@29169
   370
  assumes g: "g differentiable x"
huffman@29169
   371
  shows "(\<lambda>x. f (g x)) differentiable x"
huffman@29169
   372
proof -
huffman@29169
   373
  from `f differentiable (g x)` obtain df where "DERIV f (g x) :> df" ..
huffman@29169
   374
  moreover
huffman@29169
   375
  from `g differentiable x` obtain dg where "DERIV g x :> dg" ..
huffman@29169
   376
  ultimately
huffman@29169
   377
  have "DERIV (\<lambda>x. f (g x)) x :> df * dg" by (rule DERIV_chain2)
huffman@29169
   378
  thus ?thesis by (rule differentiableI)
huffman@29169
   379
qed
huffman@29169
   380
huffman@29169
   381
lemma differentiable_sum [simp]:
huffman@21164
   382
  assumes "f differentiable x"
huffman@21164
   383
  and "g differentiable x"
huffman@21164
   384
  shows "(\<lambda>x. f x + g x) differentiable x"
huffman@21164
   385
proof -
huffman@29169
   386
  from `f differentiable x` obtain df where "DERIV f x :> df" ..
huffman@29169
   387
  moreover
huffman@29169
   388
  from `g differentiable x` obtain dg where "DERIV g x :> dg" ..
huffman@29169
   389
  ultimately
huffman@29169
   390
  have "DERIV (\<lambda>x. f x + g x) x :> df + dg" by (rule DERIV_add)
huffman@29169
   391
  thus ?thesis by (rule differentiableI)
huffman@29169
   392
qed
huffman@29169
   393
huffman@29169
   394
lemma differentiable_minus [simp]:
huffman@29169
   395
  assumes "f differentiable x"
huffman@29169
   396
  shows "(\<lambda>x. - f x) differentiable x"
huffman@29169
   397
proof -
huffman@29169
   398
  from `f differentiable x` obtain df where "DERIV f x :> df" ..
huffman@29169
   399
  hence "DERIV (\<lambda>x. - f x) x :> - df" by (rule DERIV_minus)
huffman@29169
   400
  thus ?thesis by (rule differentiableI)
huffman@21164
   401
qed
huffman@21164
   402
huffman@29169
   403
lemma differentiable_diff [simp]:
huffman@21164
   404
  assumes "f differentiable x"
huffman@29169
   405
  assumes "g differentiable x"
huffman@21164
   406
  shows "(\<lambda>x. f x - g x) differentiable x"
huffman@29169
   407
  unfolding diff_minus using prems by simp
huffman@29169
   408
huffman@29169
   409
lemma differentiable_mult [simp]:
huffman@29169
   410
  assumes "f differentiable x"
huffman@29169
   411
  assumes "g differentiable x"
huffman@29169
   412
  shows "(\<lambda>x. f x * g x) differentiable x"
huffman@21164
   413
proof -
huffman@29169
   414
  from `f differentiable x` obtain df where "DERIV f x :> df" ..
huffman@21164
   415
  moreover
huffman@29169
   416
  from `g differentiable x` obtain dg where "DERIV g x :> dg" ..
huffman@29169
   417
  ultimately
huffman@29169
   418
  have "DERIV (\<lambda>x. f x * g x) x :> df * g x + dg * f x" by (rule DERIV_mult)
huffman@29169
   419
  thus ?thesis by (rule differentiableI)
huffman@21164
   420
qed
huffman@21164
   421
huffman@29169
   422
lemma differentiable_inverse [simp]:
huffman@29169
   423
  assumes "f differentiable x" and "f x \<noteq> 0"
huffman@29169
   424
  shows "(\<lambda>x. inverse (f x)) differentiable x"
huffman@21164
   425
proof -
huffman@29169
   426
  from `f differentiable x` obtain df where "DERIV f x :> df" ..
huffman@29169
   427
  hence "DERIV (\<lambda>x. inverse (f x)) x :> - (inverse (f x) * df * inverse (f x))"
huffman@29169
   428
    using `f x \<noteq> 0` by (rule DERIV_inverse')
huffman@29169
   429
  thus ?thesis by (rule differentiableI)
huffman@21164
   430
qed
huffman@21164
   431
huffman@29169
   432
lemma differentiable_divide [simp]:
huffman@29169
   433
  assumes "f differentiable x"
huffman@29169
   434
  assumes "g differentiable x" and "g x \<noteq> 0"
huffman@29169
   435
  shows "(\<lambda>x. f x / g x) differentiable x"
huffman@29169
   436
  unfolding divide_inverse using prems by simp
huffman@29169
   437
huffman@29169
   438
lemma differentiable_power [simp]:
haftmann@31017
   439
  fixes f :: "'a::{real_normed_field} \<Rightarrow> 'a"
huffman@29169
   440
  assumes "f differentiable x"
huffman@29169
   441
  shows "(\<lambda>x. f x ^ n) differentiable x"
huffman@30273
   442
  by (induct n, simp, simp add: prems)
huffman@29169
   443
huffman@22984
   444
huffman@21164
   445
subsection {* Nested Intervals and Bisection *}
huffman@21164
   446
huffman@21164
   447
text{*Lemmas about nested intervals and proof by bisection (cf.Harrison).
huffman@21164
   448
     All considerably tidied by lcp.*}
huffman@21164
   449
huffman@21164
   450
lemma lemma_f_mono_add [rule_format (no_asm)]: "(\<forall>n. (f::nat=>real) n \<le> f (Suc n)) --> f m \<le> f(m + no)"
huffman@21164
   451
apply (induct "no")
huffman@21164
   452
apply (auto intro: order_trans)
huffman@21164
   453
done
huffman@21164
   454
huffman@21164
   455
lemma f_inc_g_dec_Beq_f: "[| \<forall>n. f(n) \<le> f(Suc n);
huffman@21164
   456
         \<forall>n. g(Suc n) \<le> g(n);
huffman@21164
   457
         \<forall>n. f(n) \<le> g(n) |]
huffman@21164
   458
      ==> Bseq (f :: nat \<Rightarrow> real)"
huffman@21164
   459
apply (rule_tac k = "f 0" and K = "g 0" in BseqI2, rule allI)
huffman@21164
   460
apply (induct_tac "n")
huffman@21164
   461
apply (auto intro: order_trans)
huffman@21164
   462
apply (rule_tac y = "g (Suc na)" in order_trans)
huffman@21164
   463
apply (induct_tac [2] "na")
huffman@21164
   464
apply (auto intro: order_trans)
huffman@21164
   465
done
huffman@21164
   466
huffman@21164
   467
lemma f_inc_g_dec_Beq_g: "[| \<forall>n. f(n) \<le> f(Suc n);
huffman@21164
   468
         \<forall>n. g(Suc n) \<le> g(n);
huffman@21164
   469
         \<forall>n. f(n) \<le> g(n) |]
huffman@21164
   470
      ==> Bseq (g :: nat \<Rightarrow> real)"
huffman@21164
   471
apply (subst Bseq_minus_iff [symmetric])
huffman@21164
   472
apply (rule_tac g = "%x. - (f x)" in f_inc_g_dec_Beq_f)
huffman@21164
   473
apply auto
huffman@21164
   474
done
huffman@21164
   475
huffman@21164
   476
lemma f_inc_imp_le_lim:
huffman@21164
   477
  fixes f :: "nat \<Rightarrow> real"
huffman@21164
   478
  shows "\<lbrakk>\<forall>n. f n \<le> f (Suc n); convergent f\<rbrakk> \<Longrightarrow> f n \<le> lim f"
huffman@21164
   479
apply (rule linorder_not_less [THEN iffD1])
huffman@21164
   480
apply (auto simp add: convergent_LIMSEQ_iff LIMSEQ_iff monoseq_Suc)
huffman@21164
   481
apply (drule real_less_sum_gt_zero)
huffman@21164
   482
apply (drule_tac x = "f n + - lim f" in spec, safe)
huffman@21164
   483
apply (drule_tac P = "%na. no\<le>na --> ?Q na" and x = "no + n" in spec, auto)
huffman@21164
   484
apply (subgoal_tac "lim f \<le> f (no + n) ")
huffman@21164
   485
apply (drule_tac no=no and m=n in lemma_f_mono_add)
huffman@21164
   486
apply (auto simp add: add_commute)
huffman@21164
   487
apply (induct_tac "no")
huffman@21164
   488
apply simp
huffman@21164
   489
apply (auto intro: order_trans simp add: diff_minus abs_if)
huffman@21164
   490
done
huffman@21164
   491
huffman@31404
   492
lemma lim_uminus:
huffman@31404
   493
  fixes g :: "nat \<Rightarrow> 'a::real_normed_vector"
huffman@31404
   494
  shows "convergent g ==> lim (%x. - g x) = - (lim g)"
huffman@21164
   495
apply (rule LIMSEQ_minus [THEN limI])
huffman@21164
   496
apply (simp add: convergent_LIMSEQ_iff)
huffman@21164
   497
done
huffman@21164
   498
huffman@21164
   499
lemma g_dec_imp_lim_le:
huffman@21164
   500
  fixes g :: "nat \<Rightarrow> real"
huffman@21164
   501
  shows "\<lbrakk>\<forall>n. g (Suc n) \<le> g(n); convergent g\<rbrakk> \<Longrightarrow> lim g \<le> g n"
huffman@21164
   502
apply (subgoal_tac "- (g n) \<le> - (lim g) ")
huffman@21164
   503
apply (cut_tac [2] f = "%x. - (g x)" in f_inc_imp_le_lim)
huffman@21164
   504
apply (auto simp add: lim_uminus convergent_minus_iff [symmetric])
huffman@21164
   505
done
huffman@21164
   506
huffman@21164
   507
lemma lemma_nest: "[| \<forall>n. f(n) \<le> f(Suc n);
huffman@21164
   508
         \<forall>n. g(Suc n) \<le> g(n);
huffman@21164
   509
         \<forall>n. f(n) \<le> g(n) |]
huffman@21164
   510
      ==> \<exists>l m :: real. l \<le> m &  ((\<forall>n. f(n) \<le> l) & f ----> l) &
huffman@21164
   511
                            ((\<forall>n. m \<le> g(n)) & g ----> m)"
huffman@21164
   512
apply (subgoal_tac "monoseq f & monoseq g")
huffman@21164
   513
prefer 2 apply (force simp add: LIMSEQ_iff monoseq_Suc)
huffman@21164
   514
apply (subgoal_tac "Bseq f & Bseq g")
huffman@21164
   515
prefer 2 apply (blast intro: f_inc_g_dec_Beq_f f_inc_g_dec_Beq_g)
huffman@21164
   516
apply (auto dest!: Bseq_monoseq_convergent simp add: convergent_LIMSEQ_iff)
huffman@21164
   517
apply (rule_tac x = "lim f" in exI)
huffman@21164
   518
apply (rule_tac x = "lim g" in exI)
huffman@21164
   519
apply (auto intro: LIMSEQ_le)
huffman@21164
   520
apply (auto simp add: f_inc_imp_le_lim g_dec_imp_lim_le convergent_LIMSEQ_iff)
huffman@21164
   521
done
huffman@21164
   522
huffman@21164
   523
lemma lemma_nest_unique: "[| \<forall>n. f(n) \<le> f(Suc n);
huffman@21164
   524
         \<forall>n. g(Suc n) \<le> g(n);
huffman@21164
   525
         \<forall>n. f(n) \<le> g(n);
huffman@21164
   526
         (%n. f(n) - g(n)) ----> 0 |]
huffman@21164
   527
      ==> \<exists>l::real. ((\<forall>n. f(n) \<le> l) & f ----> l) &
huffman@21164
   528
                ((\<forall>n. l \<le> g(n)) & g ----> l)"
huffman@21164
   529
apply (drule lemma_nest, auto)
huffman@21164
   530
apply (subgoal_tac "l = m")
huffman@21164
   531
apply (drule_tac [2] X = f in LIMSEQ_diff)
huffman@21164
   532
apply (auto intro: LIMSEQ_unique)
huffman@21164
   533
done
huffman@21164
   534
huffman@21164
   535
text{*The universal quantifiers below are required for the declaration
huffman@21164
   536
  of @{text Bolzano_nest_unique} below.*}
huffman@21164
   537
huffman@21164
   538
lemma Bolzano_bisect_le:
huffman@21164
   539
 "a \<le> b ==> \<forall>n. fst (Bolzano_bisect P a b n) \<le> snd (Bolzano_bisect P a b n)"
huffman@21164
   540
apply (rule allI)
huffman@21164
   541
apply (induct_tac "n")
huffman@21164
   542
apply (auto simp add: Let_def split_def)
huffman@21164
   543
done
huffman@21164
   544
huffman@21164
   545
lemma Bolzano_bisect_fst_le_Suc: "a \<le> b ==>
huffman@21164
   546
   \<forall>n. fst(Bolzano_bisect P a b n) \<le> fst (Bolzano_bisect P a b (Suc n))"
huffman@21164
   547
apply (rule allI)
huffman@21164
   548
apply (induct_tac "n")
huffman@21164
   549
apply (auto simp add: Bolzano_bisect_le Let_def split_def)
huffman@21164
   550
done
huffman@21164
   551
huffman@21164
   552
lemma Bolzano_bisect_Suc_le_snd: "a \<le> b ==>
huffman@21164
   553
   \<forall>n. snd(Bolzano_bisect P a b (Suc n)) \<le> snd (Bolzano_bisect P a b n)"
huffman@21164
   554
apply (rule allI)
huffman@21164
   555
apply (induct_tac "n")
huffman@21164
   556
apply (auto simp add: Bolzano_bisect_le Let_def split_def)
huffman@21164
   557
done
huffman@21164
   558
huffman@21164
   559
lemma eq_divide_2_times_iff: "((x::real) = y / (2 * z)) = (2 * x = y/z)"
huffman@21164
   560
apply (auto)
huffman@21164
   561
apply (drule_tac f = "%u. (1/2) *u" in arg_cong)
huffman@21164
   562
apply (simp)
huffman@21164
   563
done
huffman@21164
   564
huffman@21164
   565
lemma Bolzano_bisect_diff:
huffman@21164
   566
     "a \<le> b ==>
huffman@21164
   567
      snd(Bolzano_bisect P a b n) - fst(Bolzano_bisect P a b n) =
huffman@21164
   568
      (b-a) / (2 ^ n)"
huffman@21164
   569
apply (induct "n")
huffman@21164
   570
apply (auto simp add: eq_divide_2_times_iff add_divide_distrib Let_def split_def)
huffman@21164
   571
done
huffman@21164
   572
huffman@21164
   573
lemmas Bolzano_nest_unique =
huffman@21164
   574
    lemma_nest_unique
huffman@21164
   575
    [OF Bolzano_bisect_fst_le_Suc Bolzano_bisect_Suc_le_snd Bolzano_bisect_le]
huffman@21164
   576
huffman@21164
   577
huffman@21164
   578
lemma not_P_Bolzano_bisect:
huffman@21164
   579
  assumes P:    "!!a b c. [| P(a,b); P(b,c); a \<le> b; b \<le> c|] ==> P(a,c)"
huffman@21164
   580
      and notP: "~ P(a,b)"
huffman@21164
   581
      and le:   "a \<le> b"
huffman@21164
   582
  shows "~ P(fst(Bolzano_bisect P a b n), snd(Bolzano_bisect P a b n))"
huffman@21164
   583
proof (induct n)
huffman@23441
   584
  case 0 show ?case using notP by simp
huffman@21164
   585
 next
huffman@21164
   586
  case (Suc n)
huffman@21164
   587
  thus ?case
huffman@21164
   588
 by (auto simp del: surjective_pairing [symmetric]
huffman@21164
   589
             simp add: Let_def split_def Bolzano_bisect_le [OF le]
huffman@21164
   590
     P [of "fst (Bolzano_bisect P a b n)" _ "snd (Bolzano_bisect P a b n)"])
huffman@21164
   591
qed
huffman@21164
   592
huffman@21164
   593
(*Now we re-package P_prem as a formula*)
huffman@21164
   594
lemma not_P_Bolzano_bisect':
huffman@21164
   595
     "[| \<forall>a b c. P(a,b) & P(b,c) & a \<le> b & b \<le> c --> P(a,c);
huffman@21164
   596
         ~ P(a,b);  a \<le> b |] ==>
huffman@21164
   597
      \<forall>n. ~ P(fst(Bolzano_bisect P a b n), snd(Bolzano_bisect P a b n))"
huffman@21164
   598
by (blast elim!: not_P_Bolzano_bisect [THEN [2] rev_notE])
huffman@21164
   599
huffman@21164
   600
huffman@21164
   601
huffman@21164
   602
lemma lemma_BOLZANO:
huffman@21164
   603
     "[| \<forall>a b c. P(a,b) & P(b,c) & a \<le> b & b \<le> c --> P(a,c);
huffman@21164
   604
         \<forall>x. \<exists>d::real. 0 < d &
huffman@21164
   605
                (\<forall>a b. a \<le> x & x \<le> b & (b-a) < d --> P(a,b));
huffman@21164
   606
         a \<le> b |]
huffman@21164
   607
      ==> P(a,b)"
huffman@21164
   608
apply (rule Bolzano_nest_unique [where P1=P, THEN exE], assumption+)
huffman@21164
   609
apply (rule LIMSEQ_minus_cancel)
huffman@21164
   610
apply (simp (no_asm_simp) add: Bolzano_bisect_diff LIMSEQ_divide_realpow_zero)
huffman@21164
   611
apply (rule ccontr)
huffman@21164
   612
apply (drule not_P_Bolzano_bisect', assumption+)
huffman@21164
   613
apply (rename_tac "l")
huffman@21164
   614
apply (drule_tac x = l in spec, clarify)
huffman@31336
   615
apply (simp add: LIMSEQ_iff)
huffman@21164
   616
apply (drule_tac P = "%r. 0<r --> ?Q r" and x = "d/2" in spec)
huffman@21164
   617
apply (drule_tac P = "%r. 0<r --> ?Q r" and x = "d/2" in spec)
huffman@21164
   618
apply (drule real_less_half_sum, auto)
huffman@21164
   619
apply (drule_tac x = "fst (Bolzano_bisect P a b (no + noa))" in spec)
huffman@21164
   620
apply (drule_tac x = "snd (Bolzano_bisect P a b (no + noa))" in spec)
huffman@21164
   621
apply safe
huffman@21164
   622
apply (simp_all (no_asm_simp))
huffman@21164
   623
apply (rule_tac y = "abs (fst (Bolzano_bisect P a b (no + noa)) - l) + abs (snd (Bolzano_bisect P a b (no + noa)) - l)" in order_le_less_trans)
huffman@21164
   624
apply (simp (no_asm_simp) add: abs_if)
huffman@21164
   625
apply (rule real_sum_of_halves [THEN subst])
huffman@21164
   626
apply (rule add_strict_mono)
huffman@21164
   627
apply (simp_all add: diff_minus [symmetric])
huffman@21164
   628
done
huffman@21164
   629
huffman@21164
   630
huffman@21164
   631
lemma lemma_BOLZANO2: "((\<forall>a b c. (a \<le> b & b \<le> c & P(a,b) & P(b,c)) --> P(a,c)) &
huffman@21164
   632
       (\<forall>x. \<exists>d::real. 0 < d &
huffman@21164
   633
                (\<forall>a b. a \<le> x & x \<le> b & (b-a) < d --> P(a,b))))
huffman@21164
   634
      --> (\<forall>a b. a \<le> b --> P(a,b))"
huffman@21164
   635
apply clarify
huffman@21164
   636
apply (blast intro: lemma_BOLZANO)
huffman@21164
   637
done
huffman@21164
   638
huffman@21164
   639
huffman@21164
   640
subsection {* Intermediate Value Theorem *}
huffman@21164
   641
huffman@21164
   642
text {*Prove Contrapositive by Bisection*}
huffman@21164
   643
huffman@21164
   644
lemma IVT: "[| f(a::real) \<le> (y::real); y \<le> f(b);
huffman@21164
   645
         a \<le> b;
huffman@21164
   646
         (\<forall>x. a \<le> x & x \<le> b --> isCont f x) |]
huffman@21164
   647
      ==> \<exists>x. a \<le> x & x \<le> b & f(x) = y"
huffman@21164
   648
apply (rule contrapos_pp, assumption)
huffman@21164
   649
apply (cut_tac P = "% (u,v) . a \<le> u & u \<le> v & v \<le> b --> ~ (f (u) \<le> y & y \<le> f (v))" in lemma_BOLZANO2)
huffman@21164
   650
apply safe
huffman@21164
   651
apply simp_all
huffman@31338
   652
apply (simp add: isCont_iff LIM_eq)
huffman@21164
   653
apply (rule ccontr)
huffman@21164
   654
apply (subgoal_tac "a \<le> x & x \<le> b")
huffman@21164
   655
 prefer 2
huffman@21164
   656
 apply simp
huffman@21164
   657
 apply (drule_tac P = "%d. 0<d --> ?P d" and x = 1 in spec, arith)
huffman@21164
   658
apply (drule_tac x = x in spec)+
huffman@21164
   659
apply simp
huffman@21164
   660
apply (drule_tac P = "%r. ?P r --> (\<exists>s>0. ?Q r s) " and x = "\<bar>y - f x\<bar>" in spec)
huffman@21164
   661
apply safe
huffman@21164
   662
apply simp
huffman@21164
   663
apply (drule_tac x = s in spec, clarify)
huffman@21164
   664
apply (cut_tac x = "f x" and y = y in linorder_less_linear, safe)
huffman@21164
   665
apply (drule_tac x = "ba-x" in spec)
huffman@21164
   666
apply (simp_all add: abs_if)
huffman@21164
   667
apply (drule_tac x = "aa-x" in spec)
huffman@21164
   668
apply (case_tac "x \<le> aa", simp_all)
huffman@21164
   669
done
huffman@21164
   670
huffman@21164
   671
lemma IVT2: "[| f(b::real) \<le> (y::real); y \<le> f(a);
huffman@21164
   672
         a \<le> b;
huffman@21164
   673
         (\<forall>x. a \<le> x & x \<le> b --> isCont f x)
huffman@21164
   674
      |] ==> \<exists>x. a \<le> x & x \<le> b & f(x) = y"
huffman@21164
   675
apply (subgoal_tac "- f a \<le> -y & -y \<le> - f b", clarify)
huffman@21164
   676
apply (drule IVT [where f = "%x. - f x"], assumption)
huffman@21164
   677
apply (auto intro: isCont_minus)
huffman@21164
   678
done
huffman@21164
   679
huffman@21164
   680
(*HOL style here: object-level formulations*)
huffman@21164
   681
lemma IVT_objl: "(f(a::real) \<le> (y::real) & y \<le> f(b) & a \<le> b &
huffman@21164
   682
      (\<forall>x. a \<le> x & x \<le> b --> isCont f x))
huffman@21164
   683
      --> (\<exists>x. a \<le> x & x \<le> b & f(x) = y)"
huffman@21164
   684
apply (blast intro: IVT)
huffman@21164
   685
done
huffman@21164
   686
huffman@21164
   687
lemma IVT2_objl: "(f(b::real) \<le> (y::real) & y \<le> f(a) & a \<le> b &
huffman@21164
   688
      (\<forall>x. a \<le> x & x \<le> b --> isCont f x))
huffman@21164
   689
      --> (\<exists>x. a \<le> x & x \<le> b & f(x) = y)"
huffman@21164
   690
apply (blast intro: IVT2)
huffman@21164
   691
done
huffman@21164
   692
huffman@29975
   693
huffman@29975
   694
subsection {* Boundedness of continuous functions *}
huffman@29975
   695
huffman@21164
   696
text{*By bisection, function continuous on closed interval is bounded above*}
huffman@21164
   697
huffman@21164
   698
lemma isCont_bounded:
huffman@21164
   699
     "[| a \<le> b; \<forall>x. a \<le> x & x \<le> b --> isCont f x |]
huffman@21164
   700
      ==> \<exists>M::real. \<forall>x::real. a \<le> x & x \<le> b --> f(x) \<le> M"
huffman@21164
   701
apply (cut_tac P = "% (u,v) . a \<le> u & u \<le> v & v \<le> b --> (\<exists>M. \<forall>x. u \<le> x & x \<le> v --> f x \<le> M)" in lemma_BOLZANO2)
huffman@21164
   702
apply safe
huffman@21164
   703
apply simp_all
huffman@21164
   704
apply (rename_tac x xa ya M Ma)
huffman@21164
   705
apply (cut_tac x = M and y = Ma in linorder_linear, safe)
huffman@21164
   706
apply (rule_tac x = Ma in exI, clarify)
huffman@21164
   707
apply (cut_tac x = xb and y = xa in linorder_linear, force)
huffman@21164
   708
apply (rule_tac x = M in exI, clarify)
huffman@21164
   709
apply (cut_tac x = xb and y = xa in linorder_linear, force)
huffman@21164
   710
apply (case_tac "a \<le> x & x \<le> b")
huffman@21164
   711
apply (rule_tac [2] x = 1 in exI)
huffman@21164
   712
prefer 2 apply force
huffman@31338
   713
apply (simp add: LIM_eq isCont_iff)
huffman@21164
   714
apply (drule_tac x = x in spec, auto)
huffman@21164
   715
apply (erule_tac V = "\<forall>M. \<exists>x. a \<le> x & x \<le> b & ~ f x \<le> M" in thin_rl)
huffman@21164
   716
apply (drule_tac x = 1 in spec, auto)
huffman@21164
   717
apply (rule_tac x = s in exI, clarify)
huffman@21164
   718
apply (rule_tac x = "\<bar>f x\<bar> + 1" in exI, clarify)
huffman@21164
   719
apply (drule_tac x = "xa-x" in spec)
huffman@21164
   720
apply (auto simp add: abs_ge_self)
huffman@21164
   721
done
huffman@21164
   722
huffman@21164
   723
text{*Refine the above to existence of least upper bound*}
huffman@21164
   724
huffman@21164
   725
lemma lemma_reals_complete: "((\<exists>x. x \<in> S) & (\<exists>y. isUb UNIV S (y::real))) -->
huffman@21164
   726
      (\<exists>t. isLub UNIV S t)"
huffman@21164
   727
by (blast intro: reals_complete)
huffman@21164
   728
huffman@21164
   729
lemma isCont_has_Ub: "[| a \<le> b; \<forall>x. a \<le> x & x \<le> b --> isCont f x |]
huffman@21164
   730
         ==> \<exists>M::real. (\<forall>x::real. a \<le> x & x \<le> b --> f(x) \<le> M) &
huffman@21164
   731
                   (\<forall>N. N < M --> (\<exists>x. a \<le> x & x \<le> b & N < f(x)))"
huffman@21164
   732
apply (cut_tac S = "Collect (%y. \<exists>x. a \<le> x & x \<le> b & y = f x)"
huffman@21164
   733
        in lemma_reals_complete)
huffman@21164
   734
apply auto
huffman@21164
   735
apply (drule isCont_bounded, assumption)
huffman@21164
   736
apply (auto simp add: isUb_def leastP_def isLub_def setge_def setle_def)
huffman@21164
   737
apply (rule exI, auto)
huffman@21164
   738
apply (auto dest!: spec simp add: linorder_not_less)
huffman@21164
   739
done
huffman@21164
   740
huffman@21164
   741
text{*Now show that it attains its upper bound*}
huffman@21164
   742
huffman@21164
   743
lemma isCont_eq_Ub:
huffman@21164
   744
  assumes le: "a \<le> b"
huffman@21164
   745
      and con: "\<forall>x::real. a \<le> x & x \<le> b --> isCont f x"
huffman@21164
   746
  shows "\<exists>M::real. (\<forall>x. a \<le> x & x \<le> b --> f(x) \<le> M) &
huffman@21164
   747
             (\<exists>x. a \<le> x & x \<le> b & f(x) = M)"
huffman@21164
   748
proof -
huffman@21164
   749
  from isCont_has_Ub [OF le con]
huffman@21164
   750
  obtain M where M1: "\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> f x \<le> M"
huffman@21164
   751
             and M2: "!!N. N<M ==> \<exists>x. a \<le> x \<and> x \<le> b \<and> N < f x"  by blast
huffman@21164
   752
  show ?thesis
huffman@21164
   753
  proof (intro exI, intro conjI)
huffman@21164
   754
    show " \<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> f x \<le> M" by (rule M1)
huffman@21164
   755
    show "\<exists>x. a \<le> x \<and> x \<le> b \<and> f x = M"
huffman@21164
   756
    proof (rule ccontr)
huffman@21164
   757
      assume "\<not> (\<exists>x. a \<le> x \<and> x \<le> b \<and> f x = M)"
huffman@21164
   758
      with M1 have M3: "\<forall>x. a \<le> x & x \<le> b --> f x < M"
huffman@21164
   759
        by (fastsimp simp add: linorder_not_le [symmetric])
huffman@21164
   760
      hence "\<forall>x. a \<le> x & x \<le> b --> isCont (%x. inverse (M - f x)) x"
huffman@21164
   761
        by (auto simp add: isCont_inverse isCont_diff con)
huffman@21164
   762
      from isCont_bounded [OF le this]
huffman@21164
   763
      obtain k where k: "!!x. a \<le> x & x \<le> b --> inverse (M - f x) \<le> k" by auto
huffman@21164
   764
      have Minv: "!!x. a \<le> x & x \<le> b --> 0 < inverse (M - f (x))"
nipkow@29667
   765
        by (simp add: M3 algebra_simps)
huffman@21164
   766
      have "!!x. a \<le> x & x \<le> b --> inverse (M - f x) < k+1" using k
huffman@21164
   767
        by (auto intro: order_le_less_trans [of _ k])
huffman@21164
   768
      with Minv
huffman@21164
   769
      have "!!x. a \<le> x & x \<le> b --> inverse(k+1) < inverse(inverse(M - f x))"
huffman@21164
   770
        by (intro strip less_imp_inverse_less, simp_all)
huffman@21164
   771
      hence invlt: "!!x. a \<le> x & x \<le> b --> inverse(k+1) < M - f x"
huffman@21164
   772
        by simp
huffman@21164
   773
      have "M - inverse (k+1) < M" using k [of a] Minv [of a] le
huffman@21164
   774
        by (simp, arith)
huffman@21164
   775
      from M2 [OF this]
huffman@21164
   776
      obtain x where ax: "a \<le> x & x \<le> b & M - inverse(k+1) < f x" ..
huffman@21164
   777
      thus False using invlt [of x] by force
huffman@21164
   778
    qed
huffman@21164
   779
  qed
huffman@21164
   780
qed
huffman@21164
   781
huffman@21164
   782
huffman@21164
   783
text{*Same theorem for lower bound*}
huffman@21164
   784
huffman@21164
   785
lemma isCont_eq_Lb: "[| a \<le> b; \<forall>x. a \<le> x & x \<le> b --> isCont f x |]
huffman@21164
   786
         ==> \<exists>M::real. (\<forall>x::real. a \<le> x & x \<le> b --> M \<le> f(x)) &
huffman@21164
   787
                   (\<exists>x. a \<le> x & x \<le> b & f(x) = M)"
huffman@21164
   788
apply (subgoal_tac "\<forall>x. a \<le> x & x \<le> b --> isCont (%x. - (f x)) x")
huffman@21164
   789
prefer 2 apply (blast intro: isCont_minus)
huffman@21164
   790
apply (drule_tac f = "(%x. - (f x))" in isCont_eq_Ub)
huffman@21164
   791
apply safe
huffman@21164
   792
apply auto
huffman@21164
   793
done
huffman@21164
   794
huffman@21164
   795
huffman@21164
   796
text{*Another version.*}
huffman@21164
   797
huffman@21164
   798
lemma isCont_Lb_Ub: "[|a \<le> b; \<forall>x. a \<le> x & x \<le> b --> isCont f x |]
huffman@21164
   799
      ==> \<exists>L M::real. (\<forall>x::real. a \<le> x & x \<le> b --> L \<le> f(x) & f(x) \<le> M) &
huffman@21164
   800
          (\<forall>y. L \<le> y & y \<le> M --> (\<exists>x. a \<le> x & x \<le> b & (f(x) = y)))"
huffman@21164
   801
apply (frule isCont_eq_Lb)
huffman@21164
   802
apply (frule_tac [2] isCont_eq_Ub)
huffman@21164
   803
apply (assumption+, safe)
huffman@21164
   804
apply (rule_tac x = "f x" in exI)
huffman@21164
   805
apply (rule_tac x = "f xa" in exI, simp, safe)
huffman@21164
   806
apply (cut_tac x = x and y = xa in linorder_linear, safe)
huffman@21164
   807
apply (cut_tac f = f and a = x and b = xa and y = y in IVT_objl)
huffman@21164
   808
apply (cut_tac [2] f = f and a = xa and b = x and y = y in IVT2_objl, safe)
huffman@21164
   809
apply (rule_tac [2] x = xb in exI)
huffman@21164
   810
apply (rule_tac [4] x = xb in exI, simp_all)
huffman@21164
   811
done
huffman@21164
   812
huffman@21164
   813
huffman@29975
   814
subsection {* Local extrema *}
huffman@29975
   815
huffman@21164
   816
text{*If @{term "0 < f'(x)"} then @{term x} is Locally Strictly Increasing At The Right*}
huffman@21164
   817
huffman@21164
   818
lemma DERIV_left_inc:
huffman@21164
   819
  fixes f :: "real => real"
huffman@21164
   820
  assumes der: "DERIV f x :> l"
huffman@21164
   821
      and l:   "0 < l"
huffman@21164
   822
  shows "\<exists>d > 0. \<forall>h > 0. h < d --> f(x) < f(x + h)"
huffman@21164
   823
proof -
huffman@21164
   824
  from l der [THEN DERIV_D, THEN LIM_D [where r = "l"]]
huffman@21164
   825
  have "\<exists>s > 0. (\<forall>z. z \<noteq> 0 \<and> \<bar>z\<bar> < s \<longrightarrow> \<bar>(f(x+z) - f x) / z - l\<bar> < l)"
huffman@21164
   826
    by (simp add: diff_minus)
huffman@21164
   827
  then obtain s
huffman@21164
   828
        where s:   "0 < s"
huffman@21164
   829
          and all: "!!z. z \<noteq> 0 \<and> \<bar>z\<bar> < s \<longrightarrow> \<bar>(f(x+z) - f x) / z - l\<bar> < l"
huffman@21164
   830
    by auto
huffman@21164
   831
  thus ?thesis
huffman@21164
   832
  proof (intro exI conjI strip)
huffman@23441
   833
    show "0<s" using s .
huffman@21164
   834
    fix h::real
huffman@21164
   835
    assume "0 < h" "h < s"
huffman@21164
   836
    with all [of h] show "f x < f (x+h)"
huffman@21164
   837
    proof (simp add: abs_if pos_less_divide_eq diff_minus [symmetric]
huffman@21164
   838
    split add: split_if_asm)
huffman@21164
   839
      assume "~ (f (x+h) - f x) / h < l" and h: "0 < h"
huffman@21164
   840
      with l
huffman@21164
   841
      have "0 < (f (x+h) - f x) / h" by arith
huffman@21164
   842
      thus "f x < f (x+h)"
huffman@21164
   843
  by (simp add: pos_less_divide_eq h)
huffman@21164
   844
    qed
huffman@21164
   845
  qed
huffman@21164
   846
qed
huffman@21164
   847
huffman@21164
   848
lemma DERIV_left_dec:
huffman@21164
   849
  fixes f :: "real => real"
huffman@21164
   850
  assumes der: "DERIV f x :> l"
huffman@21164
   851
      and l:   "l < 0"
huffman@21164
   852
  shows "\<exists>d > 0. \<forall>h > 0. h < d --> f(x) < f(x-h)"
huffman@21164
   853
proof -
huffman@21164
   854
  from l der [THEN DERIV_D, THEN LIM_D [where r = "-l"]]
huffman@21164
   855
  have "\<exists>s > 0. (\<forall>z. z \<noteq> 0 \<and> \<bar>z\<bar> < s \<longrightarrow> \<bar>(f(x+z) - f x) / z - l\<bar> < -l)"
huffman@21164
   856
    by (simp add: diff_minus)
huffman@21164
   857
  then obtain s
huffman@21164
   858
        where s:   "0 < s"
huffman@21164
   859
          and all: "!!z. z \<noteq> 0 \<and> \<bar>z\<bar> < s \<longrightarrow> \<bar>(f(x+z) - f x) / z - l\<bar> < -l"
huffman@21164
   860
    by auto
huffman@21164
   861
  thus ?thesis
huffman@21164
   862
  proof (intro exI conjI strip)
huffman@23441
   863
    show "0<s" using s .
huffman@21164
   864
    fix h::real
huffman@21164
   865
    assume "0 < h" "h < s"
huffman@21164
   866
    with all [of "-h"] show "f x < f (x-h)"
huffman@21164
   867
    proof (simp add: abs_if pos_less_divide_eq diff_minus [symmetric]
huffman@21164
   868
    split add: split_if_asm)
huffman@21164
   869
      assume " - ((f (x-h) - f x) / h) < l" and h: "0 < h"
huffman@21164
   870
      with l
huffman@21164
   871
      have "0 < (f (x-h) - f x) / h" by arith
huffman@21164
   872
      thus "f x < f (x-h)"
huffman@21164
   873
  by (simp add: pos_less_divide_eq h)
huffman@21164
   874
    qed
huffman@21164
   875
  qed
huffman@21164
   876
qed
huffman@21164
   877
huffman@21164
   878
lemma DERIV_local_max:
huffman@21164
   879
  fixes f :: "real => real"
huffman@21164
   880
  assumes der: "DERIV f x :> l"
huffman@21164
   881
      and d:   "0 < d"
huffman@21164
   882
      and le:  "\<forall>y. \<bar>x-y\<bar> < d --> f(y) \<le> f(x)"
huffman@21164
   883
  shows "l = 0"
huffman@21164
   884
proof (cases rule: linorder_cases [of l 0])
huffman@23441
   885
  case equal thus ?thesis .
huffman@21164
   886
next
huffman@21164
   887
  case less
huffman@21164
   888
  from DERIV_left_dec [OF der less]
huffman@21164
   889
  obtain d' where d': "0 < d'"
huffman@21164
   890
             and lt: "\<forall>h > 0. h < d' \<longrightarrow> f x < f (x-h)" by blast
huffman@21164
   891
  from real_lbound_gt_zero [OF d d']
huffman@21164
   892
  obtain e where "0 < e \<and> e < d \<and> e < d'" ..
huffman@21164
   893
  with lt le [THEN spec [where x="x-e"]]
huffman@21164
   894
  show ?thesis by (auto simp add: abs_if)
huffman@21164
   895
next
huffman@21164
   896
  case greater
huffman@21164
   897
  from DERIV_left_inc [OF der greater]
huffman@21164
   898
  obtain d' where d': "0 < d'"
huffman@21164
   899
             and lt: "\<forall>h > 0. h < d' \<longrightarrow> f x < f (x + h)" by blast
huffman@21164
   900
  from real_lbound_gt_zero [OF d d']
huffman@21164
   901
  obtain e where "0 < e \<and> e < d \<and> e < d'" ..
huffman@21164
   902
  with lt le [THEN spec [where x="x+e"]]
huffman@21164
   903
  show ?thesis by (auto simp add: abs_if)
huffman@21164
   904
qed
huffman@21164
   905
huffman@21164
   906
huffman@21164
   907
text{*Similar theorem for a local minimum*}
huffman@21164
   908
lemma DERIV_local_min:
huffman@21164
   909
  fixes f :: "real => real"
huffman@21164
   910
  shows "[| DERIV f x :> l; 0 < d; \<forall>y. \<bar>x-y\<bar> < d --> f(x) \<le> f(y) |] ==> l = 0"
huffman@21164
   911
by (drule DERIV_minus [THEN DERIV_local_max], auto)
huffman@21164
   912
huffman@21164
   913
huffman@21164
   914
text{*In particular, if a function is locally flat*}
huffman@21164
   915
lemma DERIV_local_const:
huffman@21164
   916
  fixes f :: "real => real"
huffman@21164
   917
  shows "[| DERIV f x :> l; 0 < d; \<forall>y. \<bar>x-y\<bar> < d --> f(x) = f(y) |] ==> l = 0"
huffman@21164
   918
by (auto dest!: DERIV_local_max)
huffman@21164
   919
huffman@29975
   920
huffman@29975
   921
subsection {* Rolle's Theorem *}
huffman@29975
   922
huffman@21164
   923
text{*Lemma about introducing open ball in open interval*}
huffman@21164
   924
lemma lemma_interval_lt:
huffman@21164
   925
     "[| a < x;  x < b |]
huffman@21164
   926
      ==> \<exists>d::real. 0 < d & (\<forall>y. \<bar>x-y\<bar> < d --> a < y & y < b)"
chaieb@27668
   927
huffman@22998
   928
apply (simp add: abs_less_iff)
huffman@21164
   929
apply (insert linorder_linear [of "x-a" "b-x"], safe)
huffman@21164
   930
apply (rule_tac x = "x-a" in exI)
huffman@21164
   931
apply (rule_tac [2] x = "b-x" in exI, auto)
huffman@21164
   932
done
huffman@21164
   933
huffman@21164
   934
lemma lemma_interval: "[| a < x;  x < b |] ==>
huffman@21164
   935
        \<exists>d::real. 0 < d &  (\<forall>y. \<bar>x-y\<bar> < d --> a \<le> y & y \<le> b)"
huffman@21164
   936
apply (drule lemma_interval_lt, auto)
huffman@21164
   937
apply (auto intro!: exI)
huffman@21164
   938
done
huffman@21164
   939
huffman@21164
   940
text{*Rolle's Theorem.
huffman@21164
   941
   If @{term f} is defined and continuous on the closed interval
huffman@21164
   942
   @{text "[a,b]"} and differentiable on the open interval @{text "(a,b)"},
huffman@21164
   943
   and @{term "f(a) = f(b)"},
huffman@21164
   944
   then there exists @{text "x0 \<in> (a,b)"} such that @{term "f'(x0) = 0"}*}
huffman@21164
   945
theorem Rolle:
huffman@21164
   946
  assumes lt: "a < b"
huffman@21164
   947
      and eq: "f(a) = f(b)"
huffman@21164
   948
      and con: "\<forall>x. a \<le> x & x \<le> b --> isCont f x"
huffman@21164
   949
      and dif [rule_format]: "\<forall>x. a < x & x < b --> f differentiable x"
huffman@21784
   950
  shows "\<exists>z::real. a < z & z < b & DERIV f z :> 0"
huffman@21164
   951
proof -
huffman@21164
   952
  have le: "a \<le> b" using lt by simp
huffman@21164
   953
  from isCont_eq_Ub [OF le con]
huffman@21164
   954
  obtain x where x_max: "\<forall>z. a \<le> z \<and> z \<le> b \<longrightarrow> f z \<le> f x"
huffman@21164
   955
             and alex: "a \<le> x" and xleb: "x \<le> b"
huffman@21164
   956
    by blast
huffman@21164
   957
  from isCont_eq_Lb [OF le con]
huffman@21164
   958
  obtain x' where x'_min: "\<forall>z. a \<le> z \<and> z \<le> b \<longrightarrow> f x' \<le> f z"
huffman@21164
   959
              and alex': "a \<le> x'" and x'leb: "x' \<le> b"
huffman@21164
   960
    by blast
huffman@21164
   961
  show ?thesis
huffman@21164
   962
  proof cases
huffman@21164
   963
    assume axb: "a < x & x < b"
huffman@21164
   964
        --{*@{term f} attains its maximum within the interval*}
chaieb@27668
   965
    hence ax: "a<x" and xb: "x<b" by arith + 
huffman@21164
   966
    from lemma_interval [OF ax xb]
huffman@21164
   967
    obtain d where d: "0<d" and bound: "\<forall>y. \<bar>x-y\<bar> < d \<longrightarrow> a \<le> y \<and> y \<le> b"
huffman@21164
   968
      by blast
huffman@21164
   969
    hence bound': "\<forall>y. \<bar>x-y\<bar> < d \<longrightarrow> f y \<le> f x" using x_max
huffman@21164
   970
      by blast
huffman@21164
   971
    from differentiableD [OF dif [OF axb]]
huffman@21164
   972
    obtain l where der: "DERIV f x :> l" ..
huffman@21164
   973
    have "l=0" by (rule DERIV_local_max [OF der d bound'])
huffman@21164
   974
        --{*the derivative at a local maximum is zero*}
huffman@21164
   975
    thus ?thesis using ax xb der by auto
huffman@21164
   976
  next
huffman@21164
   977
    assume notaxb: "~ (a < x & x < b)"
huffman@21164
   978
    hence xeqab: "x=a | x=b" using alex xleb by arith
huffman@21164
   979
    hence fb_eq_fx: "f b = f x" by (auto simp add: eq)
huffman@21164
   980
    show ?thesis
huffman@21164
   981
    proof cases
huffman@21164
   982
      assume ax'b: "a < x' & x' < b"
huffman@21164
   983
        --{*@{term f} attains its minimum within the interval*}
chaieb@27668
   984
      hence ax': "a<x'" and x'b: "x'<b" by arith+ 
huffman@21164
   985
      from lemma_interval [OF ax' x'b]
huffman@21164
   986
      obtain d where d: "0<d" and bound: "\<forall>y. \<bar>x'-y\<bar> < d \<longrightarrow> a \<le> y \<and> y \<le> b"
huffman@21164
   987
  by blast
huffman@21164
   988
      hence bound': "\<forall>y. \<bar>x'-y\<bar> < d \<longrightarrow> f x' \<le> f y" using x'_min
huffman@21164
   989
  by blast
huffman@21164
   990
      from differentiableD [OF dif [OF ax'b]]
huffman@21164
   991
      obtain l where der: "DERIV f x' :> l" ..
huffman@21164
   992
      have "l=0" by (rule DERIV_local_min [OF der d bound'])
huffman@21164
   993
        --{*the derivative at a local minimum is zero*}
huffman@21164
   994
      thus ?thesis using ax' x'b der by auto
huffman@21164
   995
    next
huffman@21164
   996
      assume notax'b: "~ (a < x' & x' < b)"
huffman@21164
   997
        --{*@{term f} is constant througout the interval*}
huffman@21164
   998
      hence x'eqab: "x'=a | x'=b" using alex' x'leb by arith
huffman@21164
   999
      hence fb_eq_fx': "f b = f x'" by (auto simp add: eq)
huffman@21164
  1000
      from dense [OF lt]
huffman@21164
  1001
      obtain r where ar: "a < r" and rb: "r < b" by blast
huffman@21164
  1002
      from lemma_interval [OF ar rb]
huffman@21164
  1003
      obtain d where d: "0<d" and bound: "\<forall>y. \<bar>r-y\<bar> < d \<longrightarrow> a \<le> y \<and> y \<le> b"
huffman@21164
  1004
  by blast
huffman@21164
  1005
      have eq_fb: "\<forall>z. a \<le> z --> z \<le> b --> f z = f b"
huffman@21164
  1006
      proof (clarify)
huffman@21164
  1007
        fix z::real
huffman@21164
  1008
        assume az: "a \<le> z" and zb: "z \<le> b"
huffman@21164
  1009
        show "f z = f b"
huffman@21164
  1010
        proof (rule order_antisym)
huffman@21164
  1011
          show "f z \<le> f b" by (simp add: fb_eq_fx x_max az zb)
huffman@21164
  1012
          show "f b \<le> f z" by (simp add: fb_eq_fx' x'_min az zb)
huffman@21164
  1013
        qed
huffman@21164
  1014
      qed
huffman@21164
  1015
      have bound': "\<forall>y. \<bar>r-y\<bar> < d \<longrightarrow> f r = f y"
huffman@21164
  1016
      proof (intro strip)
huffman@21164
  1017
        fix y::real
huffman@21164
  1018
        assume lt: "\<bar>r-y\<bar> < d"
huffman@21164
  1019
        hence "f y = f b" by (simp add: eq_fb bound)
huffman@21164
  1020
        thus "f r = f y" by (simp add: eq_fb ar rb order_less_imp_le)
huffman@21164
  1021
      qed
huffman@21164
  1022
      from differentiableD [OF dif [OF conjI [OF ar rb]]]
huffman@21164
  1023
      obtain l where der: "DERIV f r :> l" ..
huffman@21164
  1024
      have "l=0" by (rule DERIV_local_const [OF der d bound'])
huffman@21164
  1025
        --{*the derivative of a constant function is zero*}
huffman@21164
  1026
      thus ?thesis using ar rb der by auto
huffman@21164
  1027
    qed
huffman@21164
  1028
  qed
huffman@21164
  1029
qed
huffman@21164
  1030
huffman@21164
  1031
huffman@21164
  1032
subsection{*Mean Value Theorem*}
huffman@21164
  1033
huffman@21164
  1034
lemma lemma_MVT:
huffman@21164
  1035
     "f a - (f b - f a)/(b-a) * a = f b - (f b - f a)/(b-a) * (b::real)"
huffman@21164
  1036
proof cases
huffman@21164
  1037
  assume "a=b" thus ?thesis by simp
huffman@21164
  1038
next
huffman@21164
  1039
  assume "a\<noteq>b"
huffman@21164
  1040
  hence ba: "b-a \<noteq> 0" by arith
huffman@21164
  1041
  show ?thesis
huffman@21164
  1042
    by (rule real_mult_left_cancel [OF ba, THEN iffD1],
huffman@21164
  1043
        simp add: right_diff_distrib,
huffman@21164
  1044
        simp add: left_diff_distrib)
huffman@21164
  1045
qed
huffman@21164
  1046
huffman@21164
  1047
theorem MVT:
huffman@21164
  1048
  assumes lt:  "a < b"
huffman@21164
  1049
      and con: "\<forall>x. a \<le> x & x \<le> b --> isCont f x"
huffman@21164
  1050
      and dif [rule_format]: "\<forall>x. a < x & x < b --> f differentiable x"
huffman@21784
  1051
  shows "\<exists>l z::real. a < z & z < b & DERIV f z :> l &
huffman@21164
  1052
                   (f(b) - f(a) = (b-a) * l)"
huffman@21164
  1053
proof -
huffman@21164
  1054
  let ?F = "%x. f x - ((f b - f a) / (b-a)) * x"
huffman@21164
  1055
  have contF: "\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> isCont ?F x" using con
huffman@23069
  1056
    by (fast intro: isCont_diff isCont_const isCont_mult isCont_ident)
huffman@21164
  1057
  have difF: "\<forall>x. a < x \<and> x < b \<longrightarrow> ?F differentiable x"
huffman@21164
  1058
  proof (clarify)
huffman@21164
  1059
    fix x::real
huffman@21164
  1060
    assume ax: "a < x" and xb: "x < b"
huffman@21164
  1061
    from differentiableD [OF dif [OF conjI [OF ax xb]]]
huffman@21164
  1062
    obtain l where der: "DERIV f x :> l" ..
huffman@21164
  1063
    show "?F differentiable x"
huffman@21164
  1064
      by (rule differentiableI [where D = "l - (f b - f a)/(b-a)"],
huffman@21164
  1065
          blast intro: DERIV_diff DERIV_cmult_Id der)
huffman@21164
  1066
  qed
huffman@21164
  1067
  from Rolle [where f = ?F, OF lt lemma_MVT contF difF]
huffman@21164
  1068
  obtain z where az: "a < z" and zb: "z < b" and der: "DERIV ?F z :> 0"
huffman@21164
  1069
    by blast
huffman@21164
  1070
  have "DERIV (%x. ((f b - f a)/(b-a)) * x) z :> (f b - f a)/(b-a)"
huffman@21164
  1071
    by (rule DERIV_cmult_Id)
huffman@21164
  1072
  hence derF: "DERIV (\<lambda>x. ?F x + (f b - f a) / (b - a) * x) z
huffman@21164
  1073
                   :> 0 + (f b - f a) / (b - a)"
huffman@21164
  1074
    by (rule DERIV_add [OF der])
huffman@21164
  1075
  show ?thesis
huffman@21164
  1076
  proof (intro exI conjI)
huffman@23441
  1077
    show "a < z" using az .
huffman@23441
  1078
    show "z < b" using zb .
huffman@21164
  1079
    show "f b - f a = (b - a) * ((f b - f a)/(b-a))" by (simp)
huffman@21164
  1080
    show "DERIV f z :> ((f b - f a)/(b-a))"  using derF by simp
huffman@21164
  1081
  qed
huffman@21164
  1082
qed
huffman@21164
  1083
hoelzl@29803
  1084
lemma MVT2:
hoelzl@29803
  1085
     "[| a < b; \<forall>x. a \<le> x & x \<le> b --> DERIV f x :> f'(x) |]
hoelzl@29803
  1086
      ==> \<exists>z::real. a < z & z < b & (f b - f a = (b - a) * f'(z))"
hoelzl@29803
  1087
apply (drule MVT)
hoelzl@29803
  1088
apply (blast intro: DERIV_isCont)
hoelzl@29803
  1089
apply (force dest: order_less_imp_le simp add: differentiable_def)
hoelzl@29803
  1090
apply (blast dest: DERIV_unique order_less_imp_le)
hoelzl@29803
  1091
done
hoelzl@29803
  1092
huffman@21164
  1093
huffman@21164
  1094
text{*A function is constant if its derivative is 0 over an interval.*}
huffman@21164
  1095
huffman@21164
  1096
lemma DERIV_isconst_end:
huffman@21164
  1097
  fixes f :: "real => real"
huffman@21164
  1098
  shows "[| a < b;
huffman@21164
  1099
         \<forall>x. a \<le> x & x \<le> b --> isCont f x;
huffman@21164
  1100
         \<forall>x. a < x & x < b --> DERIV f x :> 0 |]
huffman@21164
  1101
        ==> f b = f a"
huffman@21164
  1102
apply (drule MVT, assumption)
huffman@21164
  1103
apply (blast intro: differentiableI)
huffman@21164
  1104
apply (auto dest!: DERIV_unique simp add: diff_eq_eq)
huffman@21164
  1105
done
huffman@21164
  1106
huffman@21164
  1107
lemma DERIV_isconst1:
huffman@21164
  1108
  fixes f :: "real => real"
huffman@21164
  1109
  shows "[| a < b;
huffman@21164
  1110
         \<forall>x. a \<le> x & x \<le> b --> isCont f x;
huffman@21164
  1111
         \<forall>x. a < x & x < b --> DERIV f x :> 0 |]
huffman@21164
  1112
        ==> \<forall>x. a \<le> x & x \<le> b --> f x = f a"
huffman@21164
  1113
apply safe
huffman@21164
  1114
apply (drule_tac x = a in order_le_imp_less_or_eq, safe)
huffman@21164
  1115
apply (drule_tac b = x in DERIV_isconst_end, auto)
huffman@21164
  1116
done
huffman@21164
  1117
huffman@21164
  1118
lemma DERIV_isconst2:
huffman@21164
  1119
  fixes f :: "real => real"
huffman@21164
  1120
  shows "[| a < b;
huffman@21164
  1121
         \<forall>x. a \<le> x & x \<le> b --> isCont f x;
huffman@21164
  1122
         \<forall>x. a < x & x < b --> DERIV f x :> 0;
huffman@21164
  1123
         a \<le> x; x \<le> b |]
huffman@21164
  1124
        ==> f x = f a"
huffman@21164
  1125
apply (blast dest: DERIV_isconst1)
huffman@21164
  1126
done
huffman@21164
  1127
hoelzl@29803
  1128
lemma DERIV_isconst3: fixes a b x y :: real
hoelzl@29803
  1129
  assumes "a < b" and "x \<in> {a <..< b}" and "y \<in> {a <..< b}"
hoelzl@29803
  1130
  assumes derivable: "\<And>x. x \<in> {a <..< b} \<Longrightarrow> DERIV f x :> 0"
hoelzl@29803
  1131
  shows "f x = f y"
hoelzl@29803
  1132
proof (cases "x = y")
hoelzl@29803
  1133
  case False
hoelzl@29803
  1134
  let ?a = "min x y"
hoelzl@29803
  1135
  let ?b = "max x y"
hoelzl@29803
  1136
  
hoelzl@29803
  1137
  have "\<forall>z. ?a \<le> z \<and> z \<le> ?b \<longrightarrow> DERIV f z :> 0"
hoelzl@29803
  1138
  proof (rule allI, rule impI)
hoelzl@29803
  1139
    fix z :: real assume "?a \<le> z \<and> z \<le> ?b"
hoelzl@29803
  1140
    hence "a < z" and "z < b" using `x \<in> {a <..< b}` and `y \<in> {a <..< b}` by auto
hoelzl@29803
  1141
    hence "z \<in> {a<..<b}" by auto
hoelzl@29803
  1142
    thus "DERIV f z :> 0" by (rule derivable)
hoelzl@29803
  1143
  qed
hoelzl@29803
  1144
  hence isCont: "\<forall>z. ?a \<le> z \<and> z \<le> ?b \<longrightarrow> isCont f z"
hoelzl@29803
  1145
    and DERIV: "\<forall>z. ?a < z \<and> z < ?b \<longrightarrow> DERIV f z :> 0" using DERIV_isCont by auto
hoelzl@29803
  1146
hoelzl@29803
  1147
  have "?a < ?b" using `x \<noteq> y` by auto
hoelzl@29803
  1148
  from DERIV_isconst2[OF this isCont DERIV, of x] and DERIV_isconst2[OF this isCont DERIV, of y]
hoelzl@29803
  1149
  show ?thesis by auto
hoelzl@29803
  1150
qed auto
hoelzl@29803
  1151
huffman@21164
  1152
lemma DERIV_isconst_all:
huffman@21164
  1153
  fixes f :: "real => real"
huffman@21164
  1154
  shows "\<forall>x. DERIV f x :> 0 ==> f(x) = f(y)"
huffman@21164
  1155
apply (rule linorder_cases [of x y])
huffman@21164
  1156
apply (blast intro: sym DERIV_isCont DERIV_isconst_end)+
huffman@21164
  1157
done
huffman@21164
  1158
huffman@21164
  1159
lemma DERIV_const_ratio_const:
huffman@21784
  1160
  fixes f :: "real => real"
huffman@21784
  1161
  shows "[|a \<noteq> b; \<forall>x. DERIV f x :> k |] ==> (f(b) - f(a)) = (b-a) * k"
huffman@21164
  1162
apply (rule linorder_cases [of a b], auto)
huffman@21164
  1163
apply (drule_tac [!] f = f in MVT)
huffman@21164
  1164
apply (auto dest: DERIV_isCont DERIV_unique simp add: differentiable_def)
nipkow@23477
  1165
apply (auto dest: DERIV_unique simp add: ring_distribs diff_minus)
huffman@21164
  1166
done
huffman@21164
  1167
huffman@21164
  1168
lemma DERIV_const_ratio_const2:
huffman@21784
  1169
  fixes f :: "real => real"
huffman@21784
  1170
  shows "[|a \<noteq> b; \<forall>x. DERIV f x :> k |] ==> (f(b) - f(a))/(b-a) = k"
huffman@21164
  1171
apply (rule_tac c1 = "b-a" in real_mult_right_cancel [THEN iffD1])
huffman@21164
  1172
apply (auto dest!: DERIV_const_ratio_const simp add: mult_assoc)
huffman@21164
  1173
done
huffman@21164
  1174
huffman@21164
  1175
lemma real_average_minus_first [simp]: "((a + b) /2 - a) = (b-a)/(2::real)"
huffman@21164
  1176
by (simp)
huffman@21164
  1177
huffman@21164
  1178
lemma real_average_minus_second [simp]: "((b + a)/2 - a) = (b-a)/(2::real)"
huffman@21164
  1179
by (simp)
huffman@21164
  1180
huffman@21164
  1181
text{*Gallileo's "trick": average velocity = av. of end velocities*}
huffman@21164
  1182
huffman@21164
  1183
lemma DERIV_const_average:
huffman@21164
  1184
  fixes v :: "real => real"
huffman@21164
  1185
  assumes neq: "a \<noteq> (b::real)"
huffman@21164
  1186
      and der: "\<forall>x. DERIV v x :> k"
huffman@21164
  1187
  shows "v ((a + b)/2) = (v a + v b)/2"
huffman@21164
  1188
proof (cases rule: linorder_cases [of a b])
huffman@21164
  1189
  case equal with neq show ?thesis by simp
huffman@21164
  1190
next
huffman@21164
  1191
  case less
huffman@21164
  1192
  have "(v b - v a) / (b - a) = k"
huffman@21164
  1193
    by (rule DERIV_const_ratio_const2 [OF neq der])
huffman@21164
  1194
  hence "(b-a) * ((v b - v a) / (b-a)) = (b-a) * k" by simp
huffman@21164
  1195
  moreover have "(v ((a + b) / 2) - v a) / ((a + b) / 2 - a) = k"
huffman@21164
  1196
    by (rule DERIV_const_ratio_const2 [OF _ der], simp add: neq)
huffman@21164
  1197
  ultimately show ?thesis using neq by force
huffman@21164
  1198
next
huffman@21164
  1199
  case greater
huffman@21164
  1200
  have "(v b - v a) / (b - a) = k"
huffman@21164
  1201
    by (rule DERIV_const_ratio_const2 [OF neq der])
huffman@21164
  1202
  hence "(b-a) * ((v b - v a) / (b-a)) = (b-a) * k" by simp
huffman@21164
  1203
  moreover have " (v ((b + a) / 2) - v a) / ((b + a) / 2 - a) = k"
huffman@21164
  1204
    by (rule DERIV_const_ratio_const2 [OF _ der], simp add: neq)
huffman@21164
  1205
  ultimately show ?thesis using neq by (force simp add: add_commute)
huffman@21164
  1206
qed
huffman@21164
  1207
huffman@21164
  1208
huffman@29975
  1209
subsection {* Continuous injective functions *}
huffman@29975
  1210
huffman@21164
  1211
text{*Dull lemma: an continuous injection on an interval must have a
huffman@21164
  1212
strict maximum at an end point, not in the middle.*}
huffman@21164
  1213
huffman@21164
  1214
lemma lemma_isCont_inj:
huffman@21164
  1215
  fixes f :: "real \<Rightarrow> real"
huffman@21164
  1216
  assumes d: "0 < d"
huffman@21164
  1217
      and inj [rule_format]: "\<forall>z. \<bar>z-x\<bar> \<le> d --> g(f z) = z"
huffman@21164
  1218
      and cont: "\<forall>z. \<bar>z-x\<bar> \<le> d --> isCont f z"
huffman@21164
  1219
  shows "\<exists>z. \<bar>z-x\<bar> \<le> d & f x < f z"
huffman@21164
  1220
proof (rule ccontr)
huffman@21164
  1221
  assume  "~ (\<exists>z. \<bar>z-x\<bar> \<le> d & f x < f z)"
huffman@21164
  1222
  hence all [rule_format]: "\<forall>z. \<bar>z - x\<bar> \<le> d --> f z \<le> f x" by auto
huffman@21164
  1223
  show False
huffman@21164
  1224
  proof (cases rule: linorder_le_cases [of "f(x-d)" "f(x+d)"])
huffman@21164
  1225
    case le
huffman@21164
  1226
    from d cont all [of "x+d"]
huffman@21164
  1227
    have flef: "f(x+d) \<le> f x"
huffman@21164
  1228
     and xlex: "x - d \<le> x"
huffman@21164
  1229
     and cont': "\<forall>z. x - d \<le> z \<and> z \<le> x \<longrightarrow> isCont f z"
huffman@21164
  1230
       by (auto simp add: abs_if)
huffman@21164
  1231
    from IVT [OF le flef xlex cont']
huffman@21164
  1232
    obtain x' where "x-d \<le> x'" "x' \<le> x" "f x' = f(x+d)" by blast
huffman@21164
  1233
    moreover
huffman@21164
  1234
    hence "g(f x') = g (f(x+d))" by simp
huffman@21164
  1235
    ultimately show False using d inj [of x'] inj [of "x+d"]
huffman@22998
  1236
      by (simp add: abs_le_iff)
huffman@21164
  1237
  next
huffman@21164
  1238
    case ge
huffman@21164
  1239
    from d cont all [of "x-d"]
huffman@21164
  1240
    have flef: "f(x-d) \<le> f x"
huffman@21164
  1241
     and xlex: "x \<le> x+d"
huffman@21164
  1242
     and cont': "\<forall>z. x \<le> z \<and> z \<le> x+d \<longrightarrow> isCont f z"
huffman@21164
  1243
       by (auto simp add: abs_if)
huffman@21164
  1244
    from IVT2 [OF ge flef xlex cont']
huffman@21164
  1245
    obtain x' where "x \<le> x'" "x' \<le> x+d" "f x' = f(x-d)" by blast
huffman@21164
  1246
    moreover
huffman@21164
  1247
    hence "g(f x') = g (f(x-d))" by simp
huffman@21164
  1248
    ultimately show False using d inj [of x'] inj [of "x-d"]
huffman@22998
  1249
      by (simp add: abs_le_iff)
huffman@21164
  1250
  qed
huffman@21164
  1251
qed
huffman@21164
  1252
huffman@21164
  1253
huffman@21164
  1254
text{*Similar version for lower bound.*}
huffman@21164
  1255
huffman@21164
  1256
lemma lemma_isCont_inj2:
huffman@21164
  1257
  fixes f g :: "real \<Rightarrow> real"
huffman@21164
  1258
  shows "[|0 < d; \<forall>z. \<bar>z-x\<bar> \<le> d --> g(f z) = z;
huffman@21164
  1259
        \<forall>z. \<bar>z-x\<bar> \<le> d --> isCont f z |]
huffman@21164
  1260
      ==> \<exists>z. \<bar>z-x\<bar> \<le> d & f z < f x"
huffman@21164
  1261
apply (insert lemma_isCont_inj
huffman@21164
  1262
          [where f = "%x. - f x" and g = "%y. g(-y)" and x = x and d = d])
huffman@21164
  1263
apply (simp add: isCont_minus linorder_not_le)
huffman@21164
  1264
done
huffman@21164
  1265
huffman@21164
  1266
text{*Show there's an interval surrounding @{term "f(x)"} in
huffman@21164
  1267
@{text "f[[x - d, x + d]]"} .*}
huffman@21164
  1268
huffman@21164
  1269
lemma isCont_inj_range:
huffman@21164
  1270
  fixes f :: "real \<Rightarrow> real"
huffman@21164
  1271
  assumes d: "0 < d"
huffman@21164
  1272
      and inj: "\<forall>z. \<bar>z-x\<bar> \<le> d --> g(f z) = z"
huffman@21164
  1273
      and cont: "\<forall>z. \<bar>z-x\<bar> \<le> d --> isCont f z"
huffman@21164
  1274
  shows "\<exists>e>0. \<forall>y. \<bar>y - f x\<bar> \<le> e --> (\<exists>z. \<bar>z-x\<bar> \<le> d & f z = y)"
huffman@21164
  1275
proof -
huffman@21164
  1276
  have "x-d \<le> x+d" "\<forall>z. x-d \<le> z \<and> z \<le> x+d \<longrightarrow> isCont f z" using cont d
huffman@22998
  1277
    by (auto simp add: abs_le_iff)
huffman@21164
  1278
  from isCont_Lb_Ub [OF this]
huffman@21164
  1279
  obtain L M
huffman@21164
  1280
  where all1 [rule_format]: "\<forall>z. x-d \<le> z \<and> z \<le> x+d \<longrightarrow> L \<le> f z \<and> f z \<le> M"
huffman@21164
  1281
    and all2 [rule_format]:
huffman@21164
  1282
           "\<forall>y. L \<le> y \<and> y \<le> M \<longrightarrow> (\<exists>z. x-d \<le> z \<and> z \<le> x+d \<and> f z = y)"
huffman@21164
  1283
    by auto
huffman@21164
  1284
  with d have "L \<le> f x & f x \<le> M" by simp
huffman@21164
  1285
  moreover have "L \<noteq> f x"
huffman@21164
  1286
  proof -
huffman@21164
  1287
    from lemma_isCont_inj2 [OF d inj cont]
huffman@21164
  1288
    obtain u where "\<bar>u - x\<bar> \<le> d" "f u < f x"  by auto
huffman@21164
  1289
    thus ?thesis using all1 [of u] by arith
huffman@21164
  1290
  qed
huffman@21164
  1291
  moreover have "f x \<noteq> M"
huffman@21164
  1292
  proof -
huffman@21164
  1293
    from lemma_isCont_inj [OF d inj cont]
huffman@21164
  1294
    obtain u where "\<bar>u - x\<bar> \<le> d" "f x < f u"  by auto
huffman@21164
  1295
    thus ?thesis using all1 [of u] by arith
huffman@21164
  1296
  qed
huffman@21164
  1297
  ultimately have "L < f x & f x < M" by arith
huffman@21164
  1298
  hence "0 < f x - L" "0 < M - f x" by arith+
huffman@21164
  1299
  from real_lbound_gt_zero [OF this]
huffman@21164
  1300
  obtain e where e: "0 < e" "e < f x - L" "e < M - f x" by auto
huffman@21164
  1301
  thus ?thesis
huffman@21164
  1302
  proof (intro exI conjI)
huffman@23441
  1303
    show "0<e" using e(1) .
huffman@21164
  1304
    show "\<forall>y. \<bar>y - f x\<bar> \<le> e \<longrightarrow> (\<exists>z. \<bar>z - x\<bar> \<le> d \<and> f z = y)"
huffman@21164
  1305
    proof (intro strip)
huffman@21164
  1306
      fix y::real
huffman@21164
  1307
      assume "\<bar>y - f x\<bar> \<le> e"
huffman@21164
  1308
      with e have "L \<le> y \<and> y \<le> M" by arith
huffman@21164
  1309
      from all2 [OF this]
huffman@21164
  1310
      obtain z where "x - d \<le> z" "z \<le> x + d" "f z = y" by blast
chaieb@27668
  1311
      thus "\<exists>z. \<bar>z - x\<bar> \<le> d \<and> f z = y" 
huffman@22998
  1312
        by (force simp add: abs_le_iff)
huffman@21164
  1313
    qed
huffman@21164
  1314
  qed
huffman@21164
  1315
qed
huffman@21164
  1316
huffman@21164
  1317
huffman@21164
  1318
text{*Continuity of inverse function*}
huffman@21164
  1319
huffman@21164
  1320
lemma isCont_inverse_function:
huffman@21164
  1321
  fixes f g :: "real \<Rightarrow> real"
huffman@21164
  1322
  assumes d: "0 < d"
huffman@21164
  1323
      and inj: "\<forall>z. \<bar>z-x\<bar> \<le> d --> g(f z) = z"
huffman@21164
  1324
      and cont: "\<forall>z. \<bar>z-x\<bar> \<le> d --> isCont f z"
huffman@21164
  1325
  shows "isCont g (f x)"
huffman@21164
  1326
proof (simp add: isCont_iff LIM_eq)
huffman@21164
  1327
  show "\<forall>r. 0 < r \<longrightarrow>
huffman@21164
  1328
         (\<exists>s>0. \<forall>z. z\<noteq>0 \<and> \<bar>z\<bar> < s \<longrightarrow> \<bar>g(f x + z) - g(f x)\<bar> < r)"
huffman@21164
  1329
  proof (intro strip)
huffman@21164
  1330
    fix r::real
huffman@21164
  1331
    assume r: "0<r"
huffman@21164
  1332
    from real_lbound_gt_zero [OF r d]
huffman@21164
  1333
    obtain e where e: "0 < e" and e_lt: "e < r \<and> e < d" by blast
huffman@21164
  1334
    with inj cont
huffman@21164
  1335
    have e_simps: "\<forall>z. \<bar>z-x\<bar> \<le> e --> g (f z) = z"
huffman@21164
  1336
                  "\<forall>z. \<bar>z-x\<bar> \<le> e --> isCont f z"   by auto
huffman@21164
  1337
    from isCont_inj_range [OF e this]
huffman@21164
  1338
    obtain e' where e': "0 < e'"
huffman@21164
  1339
        and all: "\<forall>y. \<bar>y - f x\<bar> \<le> e' \<longrightarrow> (\<exists>z. \<bar>z - x\<bar> \<le> e \<and> f z = y)"
huffman@21164
  1340
          by blast
huffman@21164
  1341
    show "\<exists>s>0. \<forall>z. z\<noteq>0 \<and> \<bar>z\<bar> < s \<longrightarrow> \<bar>g(f x + z) - g(f x)\<bar> < r"
huffman@21164
  1342
    proof (intro exI conjI)
huffman@23441
  1343
      show "0<e'" using e' .
huffman@21164
  1344
      show "\<forall>z. z \<noteq> 0 \<and> \<bar>z\<bar> < e' \<longrightarrow> \<bar>g (f x + z) - g (f x)\<bar> < r"
huffman@21164
  1345
      proof (intro strip)
huffman@21164
  1346
        fix z::real
huffman@21164
  1347
        assume z: "z \<noteq> 0 \<and> \<bar>z\<bar> < e'"
huffman@21164
  1348
        with e e_lt e_simps all [rule_format, of "f x + z"]
huffman@21164
  1349
        show "\<bar>g (f x + z) - g (f x)\<bar> < r" by force
huffman@21164
  1350
      qed
huffman@21164
  1351
    qed
huffman@21164
  1352
  qed
huffman@21164
  1353
qed
huffman@21164
  1354
huffman@23041
  1355
text {* Derivative of inverse function *}
huffman@23041
  1356
huffman@23041
  1357
lemma DERIV_inverse_function:
huffman@23041
  1358
  fixes f g :: "real \<Rightarrow> real"
huffman@23041
  1359
  assumes der: "DERIV f (g x) :> D"
huffman@23041
  1360
  assumes neq: "D \<noteq> 0"
huffman@23044
  1361
  assumes a: "a < x" and b: "x < b"
huffman@23044
  1362
  assumes inj: "\<forall>y. a < y \<and> y < b \<longrightarrow> f (g y) = y"
huffman@23041
  1363
  assumes cont: "isCont g x"
huffman@23041
  1364
  shows "DERIV g x :> inverse D"
huffman@23041
  1365
unfolding DERIV_iff2
huffman@23044
  1366
proof (rule LIM_equal2)
huffman@23044
  1367
  show "0 < min (x - a) (b - x)"
chaieb@27668
  1368
    using a b by arith 
huffman@23044
  1369
next
huffman@23041
  1370
  fix y
huffman@23044
  1371
  assume "norm (y - x) < min (x - a) (b - x)"
chaieb@27668
  1372
  hence "a < y" and "y < b" 
huffman@23044
  1373
    by (simp_all add: abs_less_iff)
huffman@23041
  1374
  thus "(g y - g x) / (y - x) =
huffman@23041
  1375
        inverse ((f (g y) - x) / (g y - g x))"
huffman@23041
  1376
    by (simp add: inj)
huffman@23041
  1377
next
huffman@23041
  1378
  have "(\<lambda>z. (f z - f (g x)) / (z - g x)) -- g x --> D"
huffman@23041
  1379
    by (rule der [unfolded DERIV_iff2])
huffman@23041
  1380
  hence 1: "(\<lambda>z. (f z - x) / (z - g x)) -- g x --> D"
huffman@23044
  1381
    using inj a b by simp
huffman@23041
  1382
  have 2: "\<exists>d>0. \<forall>y. y \<noteq> x \<and> norm (y - x) < d \<longrightarrow> g y \<noteq> g x"
huffman@23041
  1383
  proof (safe intro!: exI)
huffman@23044
  1384
    show "0 < min (x - a) (b - x)"
huffman@23044
  1385
      using a b by simp
huffman@23041
  1386
  next
huffman@23041
  1387
    fix y
huffman@23044
  1388
    assume "norm (y - x) < min (x - a) (b - x)"
huffman@23044
  1389
    hence y: "a < y" "y < b"
huffman@23044
  1390
      by (simp_all add: abs_less_iff)
huffman@23041
  1391
    assume "g y = g x"
huffman@23041
  1392
    hence "f (g y) = f (g x)" by simp
huffman@23044
  1393
    hence "y = x" using inj y a b by simp
huffman@23041
  1394
    also assume "y \<noteq> x"
huffman@23041
  1395
    finally show False by simp
huffman@23041
  1396
  qed
huffman@23041
  1397
  have "(\<lambda>y. (f (g y) - x) / (g y - g x)) -- x --> D"
huffman@23041
  1398
    using cont 1 2 by (rule isCont_LIM_compose2)
huffman@23041
  1399
  thus "(\<lambda>y. inverse ((f (g y) - x) / (g y - g x)))
huffman@23041
  1400
        -- x --> inverse D"
huffman@23041
  1401
    using neq by (rule LIM_inverse)
huffman@23041
  1402
qed
huffman@23041
  1403
huffman@29975
  1404
huffman@29975
  1405
subsection {* Generalized Mean Value Theorem *}
huffman@29975
  1406
huffman@21164
  1407
theorem GMVT:
huffman@21784
  1408
  fixes a b :: real
huffman@21164
  1409
  assumes alb: "a < b"
huffman@21164
  1410
  and fc: "\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> isCont f x"
huffman@21164
  1411
  and fd: "\<forall>x. a < x \<and> x < b \<longrightarrow> f differentiable x"
huffman@21164
  1412
  and gc: "\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> isCont g x"
huffman@21164
  1413
  and gd: "\<forall>x. a < x \<and> x < b \<longrightarrow> g differentiable x"
huffman@21164
  1414
  shows "\<exists>g'c f'c c. DERIV g c :> g'c \<and> DERIV f c :> f'c \<and> a < c \<and> c < b \<and> ((f b - f a) * g'c) = ((g b - g a) * f'c)"
huffman@21164
  1415
proof -
huffman@21164
  1416
  let ?h = "\<lambda>x. (f b - f a)*(g x) - (g b - g a)*(f x)"
huffman@21164
  1417
  from prems have "a < b" by simp
huffman@21164
  1418
  moreover have "\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> isCont ?h x"
huffman@21164
  1419
  proof -
huffman@21164
  1420
    have "\<forall>x. a <= x \<and> x <= b \<longrightarrow> isCont (\<lambda>x. f b - f a) x" by simp
huffman@21164
  1421
    with gc have "\<forall>x. a <= x \<and> x <= b \<longrightarrow> isCont (\<lambda>x. (f b - f a) * g x) x"
huffman@21164
  1422
      by (auto intro: isCont_mult)
huffman@21164
  1423
    moreover
huffman@21164
  1424
    have "\<forall>x. a <= x \<and> x <= b \<longrightarrow> isCont (\<lambda>x. g b - g a) x" by simp
huffman@21164
  1425
    with fc have "\<forall>x. a <= x \<and> x <= b \<longrightarrow> isCont (\<lambda>x. (g b - g a) * f x) x"
huffman@21164
  1426
      by (auto intro: isCont_mult)
huffman@21164
  1427
    ultimately show ?thesis
huffman@21164
  1428
      by (fastsimp intro: isCont_diff)
huffman@21164
  1429
  qed
huffman@21164
  1430
  moreover
huffman@21164
  1431
  have "\<forall>x. a < x \<and> x < b \<longrightarrow> ?h differentiable x"
huffman@21164
  1432
  proof -
huffman@21164
  1433
    have "\<forall>x. a < x \<and> x < b \<longrightarrow> (\<lambda>x. f b - f a) differentiable x" by (simp add: differentiable_const)
huffman@21164
  1434
    with gd have "\<forall>x. a < x \<and> x < b \<longrightarrow> (\<lambda>x. (f b - f a) * g x) differentiable x" by (simp add: differentiable_mult)
huffman@21164
  1435
    moreover
huffman@21164
  1436
    have "\<forall>x. a < x \<and> x < b \<longrightarrow> (\<lambda>x. g b - g a) differentiable x" by (simp add: differentiable_const)
huffman@21164
  1437
    with fd have "\<forall>x. a < x \<and> x < b \<longrightarrow> (\<lambda>x. (g b - g a) * f x) differentiable x" by (simp add: differentiable_mult)
huffman@21164
  1438
    ultimately show ?thesis by (simp add: differentiable_diff)
huffman@21164
  1439
  qed
huffman@21164
  1440
  ultimately have "\<exists>l z. a < z \<and> z < b \<and> DERIV ?h z :> l \<and> ?h b - ?h a = (b - a) * l" by (rule MVT)
huffman@21164
  1441
  then obtain l where ldef: "\<exists>z. a < z \<and> z < b \<and> DERIV ?h z :> l \<and> ?h b - ?h a = (b - a) * l" ..
huffman@21164
  1442
  then obtain c where cdef: "a < c \<and> c < b \<and> DERIV ?h c :> l \<and> ?h b - ?h a = (b - a) * l" ..
huffman@21164
  1443
huffman@21164
  1444
  from cdef have cint: "a < c \<and> c < b" by auto
huffman@21164
  1445
  with gd have "g differentiable c" by simp
huffman@21164
  1446
  hence "\<exists>D. DERIV g c :> D" by (rule differentiableD)
huffman@21164
  1447
  then obtain g'c where g'cdef: "DERIV g c :> g'c" ..
huffman@21164
  1448
huffman@21164
  1449
  from cdef have "a < c \<and> c < b" by auto
huffman@21164
  1450
  with fd have "f differentiable c" by simp
huffman@21164
  1451
  hence "\<exists>D. DERIV f c :> D" by (rule differentiableD)
huffman@21164
  1452
  then obtain f'c where f'cdef: "DERIV f c :> f'c" ..
huffman@21164
  1453
huffman@21164
  1454
  from cdef have "DERIV ?h c :> l" by auto
huffman@21164
  1455
  moreover
huffman@21164
  1456
  {
huffman@23441
  1457
    have "DERIV (\<lambda>x. (f b - f a) * g x) c :> g'c * (f b - f a)"
huffman@21164
  1458
      apply (insert DERIV_const [where k="f b - f a"])
huffman@21164
  1459
      apply (drule meta_spec [of _ c])
huffman@23441
  1460
      apply (drule DERIV_mult [OF _ g'cdef])
huffman@23441
  1461
      by simp
huffman@23441
  1462
    moreover have "DERIV (\<lambda>x. (g b - g a) * f x) c :> f'c * (g b - g a)"
huffman@21164
  1463
      apply (insert DERIV_const [where k="g b - g a"])
huffman@21164
  1464
      apply (drule meta_spec [of _ c])
huffman@23441
  1465
      apply (drule DERIV_mult [OF _ f'cdef])
huffman@23441
  1466
      by simp
huffman@21164
  1467
    ultimately have "DERIV ?h c :>  g'c * (f b - f a) - f'c * (g b - g a)"
huffman@21164
  1468
      by (simp add: DERIV_diff)
huffman@21164
  1469
  }
huffman@21164
  1470
  ultimately have leq: "l =  g'c * (f b - f a) - f'c * (g b - g a)" by (rule DERIV_unique)
huffman@21164
  1471
huffman@21164
  1472
  {
huffman@21164
  1473
    from cdef have "?h b - ?h a = (b - a) * l" by auto
huffman@21164
  1474
    also with leq have "\<dots> = (b - a) * (g'c * (f b - f a) - f'c * (g b - g a))" by simp
huffman@21164
  1475
    finally have "?h b - ?h a = (b - a) * (g'c * (f b - f a) - f'c * (g b - g a))" by simp
huffman@21164
  1476
  }
huffman@21164
  1477
  moreover
huffman@21164
  1478
  {
huffman@21164
  1479
    have "?h b - ?h a =
huffman@21164
  1480
         ((f b)*(g b) - (f a)*(g b) - (g b)*(f b) + (g a)*(f b)) -
huffman@21164
  1481
          ((f b)*(g a) - (f a)*(g a) - (g b)*(f a) + (g a)*(f a))"
nipkow@29667
  1482
      by (simp add: algebra_simps)
huffman@21164
  1483
    hence "?h b - ?h a = 0" by auto
huffman@21164
  1484
  }
huffman@21164
  1485
  ultimately have "(b - a) * (g'c * (f b - f a) - f'c * (g b - g a)) = 0" by auto
huffman@21164
  1486
  with alb have "g'c * (f b - f a) - f'c * (g b - g a) = 0" by simp
huffman@21164
  1487
  hence "g'c * (f b - f a) = f'c * (g b - g a)" by simp
huffman@21164
  1488
  hence "(f b - f a) * g'c = (g b - g a) * f'c" by (simp add: mult_ac)
huffman@21164
  1489
huffman@21164
  1490
  with g'cdef f'cdef cint show ?thesis by auto
huffman@21164
  1491
qed
huffman@21164
  1492
huffman@29470
  1493
huffman@29166
  1494
subsection {* Theorems about Limits *}
huffman@29166
  1495
huffman@29166
  1496
(* need to rename second isCont_inverse *)
huffman@29166
  1497
huffman@29166
  1498
lemma isCont_inv_fun:
huffman@29166
  1499
  fixes f g :: "real \<Rightarrow> real"
huffman@29166
  1500
  shows "[| 0 < d; \<forall>z. \<bar>z - x\<bar> \<le> d --> g(f(z)) = z;  
huffman@29166
  1501
         \<forall>z. \<bar>z - x\<bar> \<le> d --> isCont f z |]  
huffman@29166
  1502
      ==> isCont g (f x)"
huffman@29166
  1503
by (rule isCont_inverse_function)
huffman@29166
  1504
huffman@29166
  1505
lemma isCont_inv_fun_inv:
huffman@29166
  1506
  fixes f g :: "real \<Rightarrow> real"
huffman@29166
  1507
  shows "[| 0 < d;  
huffman@29166
  1508
         \<forall>z. \<bar>z - x\<bar> \<le> d --> g(f(z)) = z;  
huffman@29166
  1509
         \<forall>z. \<bar>z - x\<bar> \<le> d --> isCont f z |]  
huffman@29166
  1510
       ==> \<exists>e. 0 < e &  
huffman@29166
  1511
             (\<forall>y. 0 < \<bar>y - f(x)\<bar> & \<bar>y - f(x)\<bar> < e --> f(g(y)) = y)"
huffman@29166
  1512
apply (drule isCont_inj_range)
huffman@29166
  1513
prefer 2 apply (assumption, assumption, auto)
huffman@29166
  1514
apply (rule_tac x = e in exI, auto)
huffman@29166
  1515
apply (rotate_tac 2)
huffman@29166
  1516
apply (drule_tac x = y in spec, auto)
huffman@29166
  1517
done
huffman@29166
  1518
huffman@29166
  1519
huffman@29166
  1520
text{*Bartle/Sherbert: Introduction to Real Analysis, Theorem 4.2.9, p. 110*}
huffman@29166
  1521
lemma LIM_fun_gt_zero:
huffman@29166
  1522
     "[| f -- c --> (l::real); 0 < l |]  
huffman@29166
  1523
         ==> \<exists>r. 0 < r & (\<forall>x::real. x \<noteq> c & \<bar>c - x\<bar> < r --> 0 < f x)"
huffman@31338
  1524
apply (auto simp add: LIM_eq)
huffman@29166
  1525
apply (drule_tac x = "l/2" in spec, safe, force)
huffman@29166
  1526
apply (rule_tac x = s in exI)
huffman@29166
  1527
apply (auto simp only: abs_less_iff)
huffman@29166
  1528
done
huffman@29166
  1529
huffman@29166
  1530
lemma LIM_fun_less_zero:
huffman@29166
  1531
     "[| f -- c --> (l::real); l < 0 |]  
huffman@29166
  1532
      ==> \<exists>r. 0 < r & (\<forall>x::real. x \<noteq> c & \<bar>c - x\<bar> < r --> f x < 0)"
huffman@31338
  1533
apply (auto simp add: LIM_eq)
huffman@29166
  1534
apply (drule_tac x = "-l/2" in spec, safe, force)
huffman@29166
  1535
apply (rule_tac x = s in exI)
huffman@29166
  1536
apply (auto simp only: abs_less_iff)
huffman@29166
  1537
done
huffman@29166
  1538
huffman@29166
  1539
huffman@29166
  1540
lemma LIM_fun_not_zero:
huffman@29166
  1541
     "[| f -- c --> (l::real); l \<noteq> 0 |] 
huffman@29166
  1542
      ==> \<exists>r. 0 < r & (\<forall>x::real. x \<noteq> c & \<bar>c - x\<bar> < r --> f x \<noteq> 0)"
huffman@29166
  1543
apply (cut_tac x = l and y = 0 in linorder_less_linear, auto)
huffman@29166
  1544
apply (drule LIM_fun_less_zero)
huffman@29166
  1545
apply (drule_tac [3] LIM_fun_gt_zero)
huffman@29166
  1546
apply force+
huffman@29166
  1547
done
huffman@29166
  1548
huffman@21164
  1549
end