remove theory Real_Integration, not needed since 44e42d392c6e when Euclidean spaces where introduced
--- a/src/HOL/Multivariate_Analysis/Real_Integration.thy Thu Sep 13 16:43:33 2012 +0200
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,72 +0,0 @@
-header{*Integration on real intervals*}
-
-theory Real_Integration
-imports Integration
-begin
-
-text{*We follow John Harrison in formalizing the Gauge integral.*}
-
-definition Integral :: "real set \<Rightarrow> (real \<Rightarrow> real) \<Rightarrow> real \<Rightarrow> bool" where
- "Integral s f k = (f o dest_vec1 has_integral k) (vec1 ` s)"
-
-lemmas integral_unfold = Integral_def split_conv o_def vec1_interval
-
-lemma Integral_unique:
- "[| Integral{a..b} f k1; Integral{a..b} f k2 |] ==> k1 = k2"
- unfolding integral_unfold apply(rule has_integral_unique) by assumption+
-
-lemma Integral_zero [simp]: "Integral{a..a} f 0"
- unfolding integral_unfold by auto
-
-lemma Integral_eq_diff_bounds: assumes "a \<le> b" shows "Integral{a..b} (%x. 1) (b - a)"
- unfolding integral_unfold using has_integral_const[of "1::real" "vec1 a" "vec1 b"]
- unfolding content_1'[OF assms] by auto
-
-lemma Integral_mult_const: assumes "a \<le> b" shows "Integral{a..b} (%x. c) (c*(b - a))"
- unfolding integral_unfold using has_integral_const[of "c::real" "vec1 a" "vec1 b"]
- unfolding content_1'[OF assms] by(auto simp add:field_simps)
-
-lemma Integral_mult: assumes "Integral{a..b} f k" shows "Integral{a..b} (%x. c * f x) (c * k)"
- using assms unfolding integral_unfold apply(drule_tac has_integral_cmul[where c=c]) by auto
-
-lemma Integral_add:
- assumes "Integral {a..b} f x1" "Integral {b..c} f x2" "a \<le> b" and "b \<le> c"
- shows "Integral {a..c} f (x1 + x2)"
- using assms unfolding integral_unfold apply-
- apply(rule has_integral_combine[of "vec1 a" "vec1 b" "vec1 c"]) by auto
-
-lemma FTC1: assumes "a \<le> b" "\<forall>x. a \<le> x & x \<le> b --> DERIV f x :> f'(x)"
- shows "Integral{a..b} f' (f(b) - f(a))"
-proof-note fundamental_theorem_of_calculus[OF assms(1), of"f o dest_vec1" "f' o dest_vec1"]
- note * = this[unfolded o_def vec1_dest_vec1]
- have **:"\<And>x. (\<lambda>xa\<Colon>real. xa * f' x) = op * (f' x)" apply(rule ext) by(auto simp add:field_simps)
- show ?thesis unfolding integral_unfold apply(rule *)
- using assms(2) unfolding DERIV_conv_has_derivative has_vector_derivative_def
- apply safe apply(rule has_derivative_at_within) by(auto simp add:**) qed
-
-lemma Integral_subst: "[| Integral{a..b} f k1; k2=k1 |] ==> Integral{a..b} f k2"
-by simp
-
-subsection {* Additivity Theorem of Gauge Integral *}
-
-text{* Bartle/Sherbert: Theorem 10.1.5 p. 278 *}
-lemma Integral_add_fun: "[| Integral{a..b} f k1; Integral{a..b} g k2 |] ==> Integral{a..b} (%x. f x + g x) (k1 + k2)"
- unfolding integral_unfold apply(rule has_integral_add) by assumption+
-
-lemma norm_vec1'[simp]:"norm (vec1 x) = norm x"
- using norm_vector_1[of "vec1 x"] by auto
-
-lemma Integral_le: assumes "a \<le> b" "\<forall>x. a \<le> x & x \<le> b --> f(x) \<le> g(x)" "Integral{a..b} f k1" "Integral{a..b} g k2" shows "k1 \<le> k2"
-proof- note assms(3-4)[unfolded integral_unfold] note has_integral_vec1[OF this(1)] has_integral_vec1[OF this(2)]
- note has_integral_component_le[OF this,of 1] thus ?thesis using assms(2) by auto qed
-
-lemma monotonic_anti_derivative:
- fixes f g :: "real => real" shows
- "[| a \<le> b; \<forall>c. a \<le> c & c \<le> b --> f' c \<le> g' c;
- \<forall>x. DERIV f x :> f' x; \<forall>x. DERIV g x :> g' x |]
- ==> f b - f a \<le> g b - g a"
-apply (rule Integral_le, assumption)
-apply (auto intro: FTC1)
-done
-
-end