author | blanchet |
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permissions | -rw-r--r-- |
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(* Title: HOL/Limits.thy |
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Author: Brian Huffman |
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Author: Jacques D. Fleuriot, University of Cambridge |
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Author: Lawrence C Paulson |
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Author: Jeremy Avigad |
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*) |
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header {* Limits on Real Vector Spaces *} |
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theory Limits |
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imports Real_Vector_Spaces |
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begin |
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subsection {* Filter going to infinity norm *} |
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definition at_infinity :: "'a::real_normed_vector filter" where |
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"at_infinity = (INF r. principal {x. r \<le> norm x})" |
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lemma eventually_at_infinity: "eventually P at_infinity \<longleftrightarrow> (\<exists>b. \<forall>x. b \<le> norm x \<longrightarrow> P x)" |
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unfolding at_infinity_def |
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by (subst eventually_INF_base) |
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(auto simp: subset_eq eventually_principal intro!: exI[of _ "max a b" for a b]) |
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lemma at_infinity_eq_at_top_bot: |
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"(at_infinity \<Colon> real filter) = sup at_top at_bot" |
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apply (simp add: filter_eq_iff eventually_sup eventually_at_infinity |
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eventually_at_top_linorder eventually_at_bot_linorder) |
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apply safe |
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apply (rule_tac x="b" in exI, simp) |
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apply (rule_tac x="- b" in exI, simp) |
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apply (rule_tac x="max (- Na) N" in exI, auto simp: abs_real_def) |
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done |
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lemma at_top_le_at_infinity: "at_top \<le> (at_infinity :: real filter)" |
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unfolding at_infinity_eq_at_top_bot by simp |
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lemma at_bot_le_at_infinity: "at_bot \<le> (at_infinity :: real filter)" |
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unfolding at_infinity_eq_at_top_bot by simp |
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lemma filterlim_at_top_imp_at_infinity: |
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fixes f :: "_ \<Rightarrow> real" |
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shows "filterlim f at_top F \<Longrightarrow> filterlim f at_infinity F" |
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by (rule filterlim_mono[OF _ at_top_le_at_infinity order_refl]) |
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subsubsection {* Boundedness *} |
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definition Bfun :: "('a \<Rightarrow> 'b::metric_space) \<Rightarrow> 'a filter \<Rightarrow> bool" where |
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Bfun_metric_def: "Bfun f F = (\<exists>y. \<exists>K>0. eventually (\<lambda>x. dist (f x) y \<le> K) F)" |
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abbreviation Bseq :: "(nat \<Rightarrow> 'a::metric_space) \<Rightarrow> bool" where |
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"Bseq X \<equiv> Bfun X sequentially" |
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lemma Bseq_conv_Bfun: "Bseq X \<longleftrightarrow> Bfun X sequentially" .. |
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lemma Bseq_ignore_initial_segment: "Bseq X \<Longrightarrow> Bseq (\<lambda>n. X (n + k))" |
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unfolding Bfun_metric_def by (subst eventually_sequentially_seg) |
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lemma Bseq_offset: "Bseq (\<lambda>n. X (n + k)) \<Longrightarrow> Bseq X" |
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unfolding Bfun_metric_def by (subst (asm) eventually_sequentially_seg) |
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lemma Bfun_def: |
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"Bfun f F \<longleftrightarrow> (\<exists>K>0. eventually (\<lambda>x. norm (f x) \<le> K) F)" |
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unfolding Bfun_metric_def norm_conv_dist |
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proof safe |
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fix y K assume "0 < K" and *: "eventually (\<lambda>x. dist (f x) y \<le> K) F" |
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moreover have "eventually (\<lambda>x. dist (f x) 0 \<le> dist (f x) y + dist 0 y) F" |
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by (intro always_eventually) (metis dist_commute dist_triangle) |
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with * have "eventually (\<lambda>x. dist (f x) 0 \<le> K + dist 0 y) F" |
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by eventually_elim auto |
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with `0 < K` show "\<exists>K>0. eventually (\<lambda>x. dist (f x) 0 \<le> K) F" |
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by (intro exI[of _ "K + dist 0 y"] add_pos_nonneg conjI zero_le_dist) auto |
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qed auto |
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lemma BfunI: |
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assumes K: "eventually (\<lambda>x. norm (f x) \<le> K) F" shows "Bfun f F" |
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unfolding Bfun_def |
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proof (intro exI conjI allI) |
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show "0 < max K 1" by simp |
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next |
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show "eventually (\<lambda>x. norm (f x) \<le> max K 1) F" |
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using K by (rule eventually_elim1, simp) |
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qed |
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lemma BfunE: |
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assumes "Bfun f F" |
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obtains B where "0 < B" and "eventually (\<lambda>x. norm (f x) \<le> B) F" |
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using assms unfolding Bfun_def by fast |
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lemma Cauchy_Bseq: "Cauchy X \<Longrightarrow> Bseq X" |
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unfolding Cauchy_def Bfun_metric_def eventually_sequentially |
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apply (erule_tac x=1 in allE) |
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apply simp |
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apply safe |
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apply (rule_tac x="X M" in exI) |
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apply (rule_tac x=1 in exI) |
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apply (erule_tac x=M in allE) |
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apply simp |
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apply (rule_tac x=M in exI) |
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apply (auto simp: dist_commute) |
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done |
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subsubsection {* Bounded Sequences *} |
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lemma BseqI': "(\<And>n. norm (X n) \<le> K) \<Longrightarrow> Bseq X" |
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by (intro BfunI) (auto simp: eventually_sequentially) |
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lemma BseqI2': "\<forall>n\<ge>N. norm (X n) \<le> K \<Longrightarrow> Bseq X" |
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by (intro BfunI) (auto simp: eventually_sequentially) |
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lemma Bseq_def: "Bseq X \<longleftrightarrow> (\<exists>K>0. \<forall>n. norm (X n) \<le> K)" |
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unfolding Bfun_def eventually_sequentially |
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proof safe |
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fix N K assume "0 < K" "\<forall>n\<ge>N. norm (X n) \<le> K" |
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then show "\<exists>K>0. \<forall>n. norm (X n) \<le> K" |
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by (intro exI[of _ "max (Max (norm ` X ` {..N})) K"] max.strict_coboundedI2) |
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(auto intro!: imageI not_less[where 'a=nat, THEN iffD1] Max_ge simp: le_max_iff_disj) |
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qed auto |
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lemma BseqE: "\<lbrakk>Bseq X; \<And>K. \<lbrakk>0 < K; \<forall>n. norm (X n) \<le> K\<rbrakk> \<Longrightarrow> Q\<rbrakk> \<Longrightarrow> Q" |
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unfolding Bseq_def by auto |
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lemma BseqD: "Bseq X ==> \<exists>K. 0 < K & (\<forall>n. norm (X n) \<le> K)" |
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by (simp add: Bseq_def) |
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lemma BseqI: "[| 0 < K; \<forall>n. norm (X n) \<le> K |] ==> Bseq X" |
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by (auto simp add: Bseq_def) |
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lemma Bseq_bdd_above: "Bseq (X::nat \<Rightarrow> real) \<Longrightarrow> bdd_above (range X)" |
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proof (elim BseqE, intro bdd_aboveI2) |
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fix K n assume "0 < K" "\<forall>n. norm (X n) \<le> K" then show "X n \<le> K" |
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by (auto elim!: allE[of _ n]) |
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qed |
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lemma Bseq_bdd_below: "Bseq (X::nat \<Rightarrow> real) \<Longrightarrow> bdd_below (range X)" |
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proof (elim BseqE, intro bdd_belowI2) |
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fix K n assume "0 < K" "\<forall>n. norm (X n) \<le> K" then show "- K \<le> X n" |
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by (auto elim!: allE[of _ n]) |
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qed |
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141 |
lemma lemma_NBseq_def: |
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"(\<exists>K > 0. \<forall>n. norm (X n) \<le> K) = (\<exists>N. \<forall>n. norm (X n) \<le> real(Suc N))" |
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143 |
proof safe |
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144 |
fix K :: real |
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from reals_Archimedean2 obtain n :: nat where "K < real n" .. |
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then have "K \<le> real (Suc n)" by auto |
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moreover assume "\<forall>m. norm (X m) \<le> K" |
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148 |
ultimately have "\<forall>m. norm (X m) \<le> real (Suc n)" |
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149 |
by (blast intro: order_trans) |
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then show "\<exists>N. \<forall>n. norm (X n) \<le> real (Suc N)" .. |
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qed (force simp add: real_of_nat_Suc) |
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152 |
|
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153 |
text{* alternative definition for Bseq *} |
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154 |
lemma Bseq_iff: "Bseq X = (\<exists>N. \<forall>n. norm (X n) \<le> real(Suc N))" |
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155 |
apply (simp add: Bseq_def) |
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156 |
apply (simp (no_asm) add: lemma_NBseq_def) |
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157 |
done |
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158 |
|
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159 |
lemma lemma_NBseq_def2: |
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160 |
"(\<exists>K > 0. \<forall>n. norm (X n) \<le> K) = (\<exists>N. \<forall>n. norm (X n) < real(Suc N))" |
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161 |
apply (subst lemma_NBseq_def, auto) |
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162 |
apply (rule_tac x = "Suc N" in exI) |
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163 |
apply (rule_tac [2] x = N in exI) |
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164 |
apply (auto simp add: real_of_nat_Suc) |
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165 |
prefer 2 apply (blast intro: order_less_imp_le) |
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166 |
apply (drule_tac x = n in spec, simp) |
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167 |
done |
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168 |
|
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(* yet another definition for Bseq *) |
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170 |
lemma Bseq_iff1a: "Bseq X = (\<exists>N. \<forall>n. norm (X n) < real(Suc N))" |
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171 |
by (simp add: Bseq_def lemma_NBseq_def2) |
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172 |
|
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subsubsection{*A Few More Equivalence Theorems for Boundedness*} |
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174 |
|
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175 |
text{*alternative formulation for boundedness*} |
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176 |
lemma Bseq_iff2: "Bseq X = (\<exists>k > 0. \<exists>x. \<forall>n. norm (X(n) + -x) \<le> k)" |
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177 |
apply (unfold Bseq_def, safe) |
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178 |
apply (rule_tac [2] x = "k + norm x" in exI) |
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179 |
apply (rule_tac x = K in exI, simp) |
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180 |
apply (rule exI [where x = 0], auto) |
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181 |
apply (erule order_less_le_trans, simp) |
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182 |
apply (drule_tac x=n in spec) |
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183 |
apply (drule order_trans [OF norm_triangle_ineq2]) |
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184 |
apply simp |
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185 |
done |
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186 |
|
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187 |
text{*alternative formulation for boundedness*} |
53602 | 188 |
lemma Bseq_iff3: |
189 |
"Bseq X \<longleftrightarrow> (\<exists>k>0. \<exists>N. \<forall>n. norm (X n + - X N) \<le> k)" (is "?P \<longleftrightarrow> ?Q") |
|
190 |
proof |
|
191 |
assume ?P |
|
192 |
then obtain K |
|
193 |
where *: "0 < K" and **: "\<And>n. norm (X n) \<le> K" by (auto simp add: Bseq_def) |
|
194 |
from * have "0 < K + norm (X 0)" by (rule order_less_le_trans) simp |
|
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from ** have "\<forall>n. norm (X n - X 0) \<le> K + norm (X 0)" |
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196 |
by (auto intro: order_trans norm_triangle_ineq4) |
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197 |
then have "\<forall>n. norm (X n + - X 0) \<le> K + norm (X 0)" |
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198 |
by simp |
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199 |
with `0 < K + norm (X 0)` show ?Q by blast |
53602 | 200 |
next |
201 |
assume ?Q then show ?P by (auto simp add: Bseq_iff2) |
|
202 |
qed |
|
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203 |
|
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204 |
lemma BseqI2: "(\<forall>n. k \<le> f n & f n \<le> (K::real)) ==> Bseq f" |
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205 |
apply (simp add: Bseq_def) |
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206 |
apply (rule_tac x = " (\<bar>k\<bar> + \<bar>K\<bar>) + 1" in exI, auto) |
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207 |
apply (drule_tac x = n in spec, arith) |
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208 |
done |
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209 |
|
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210 |
|
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211 |
subsubsection{*Upper Bounds and Lubs of Bounded Sequences*} |
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212 |
|
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213 |
lemma Bseq_minus_iff: "Bseq (%n. -(X n) :: 'a :: real_normed_vector) = Bseq X" |
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214 |
by (simp add: Bseq_def) |
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215 |
|
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216 |
lemma Bseq_eq_bounded: "range f \<subseteq> {a .. b::real} \<Longrightarrow> Bseq f" |
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217 |
apply (simp add: subset_eq) |
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218 |
apply (rule BseqI'[where K="max (norm a) (norm b)"]) |
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219 |
apply (erule_tac x=n in allE) |
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220 |
apply auto |
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221 |
done |
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222 |
|
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223 |
lemma incseq_bounded: "incseq X \<Longrightarrow> \<forall>i. X i \<le> (B::real) \<Longrightarrow> Bseq X" |
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224 |
by (intro Bseq_eq_bounded[of X "X 0" B]) (auto simp: incseq_def) |
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225 |
|
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226 |
lemma decseq_bounded: "decseq X \<Longrightarrow> \<forall>i. (B::real) \<le> X i \<Longrightarrow> Bseq X" |
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227 |
by (intro Bseq_eq_bounded[of X B "X 0"]) (auto simp: decseq_def) |
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228 |
|
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229 |
subsection {* Bounded Monotonic Sequences *} |
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230 |
|
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231 |
subsubsection{*A Bounded and Monotonic Sequence Converges*} |
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232 |
|
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233 |
(* TODO: delete *) |
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234 |
(* FIXME: one use in NSA/HSEQ.thy *) |
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235 |
lemma Bmonoseq_LIMSEQ: "\<forall>n. m \<le> n --> X n = X m ==> \<exists>L. (X ----> L)" |
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236 |
apply (rule_tac x="X m" in exI) |
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237 |
apply (rule filterlim_cong[THEN iffD2, OF refl refl _ tendsto_const]) |
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238 |
unfolding eventually_sequentially |
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239 |
apply blast |
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240 |
done |
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241 |
|
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242 |
subsection {* Convergence to Zero *} |
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243 |
|
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244 |
definition Zfun :: "('a \<Rightarrow> 'b::real_normed_vector) \<Rightarrow> 'a filter \<Rightarrow> bool" |
44195 | 245 |
where "Zfun f F = (\<forall>r>0. eventually (\<lambda>x. norm (f x) < r) F)" |
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246 |
|
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lemma ZfunI: |
44195 | 248 |
"(\<And>r. 0 < r \<Longrightarrow> eventually (\<lambda>x. norm (f x) < r) F) \<Longrightarrow> Zfun f F" |
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249 |
unfolding Zfun_def by simp |
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250 |
|
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lemma ZfunD: |
44195 | 252 |
"\<lbrakk>Zfun f F; 0 < r\<rbrakk> \<Longrightarrow> eventually (\<lambda>x. norm (f x) < r) F" |
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253 |
unfolding Zfun_def by simp |
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254 |
|
31355 | 255 |
lemma Zfun_ssubst: |
44195 | 256 |
"eventually (\<lambda>x. f x = g x) F \<Longrightarrow> Zfun g F \<Longrightarrow> Zfun f F" |
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257 |
unfolding Zfun_def by (auto elim!: eventually_rev_mp) |
31355 | 258 |
|
44195 | 259 |
lemma Zfun_zero: "Zfun (\<lambda>x. 0) F" |
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260 |
unfolding Zfun_def by simp |
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261 |
|
44195 | 262 |
lemma Zfun_norm_iff: "Zfun (\<lambda>x. norm (f x)) F = Zfun (\<lambda>x. f x) F" |
44081
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rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
263 |
unfolding Zfun_def by simp |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
264 |
|
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
265 |
lemma Zfun_imp_Zfun: |
44195 | 266 |
assumes f: "Zfun f F" |
267 |
assumes g: "eventually (\<lambda>x. norm (g x) \<le> norm (f x) * K) F" |
|
268 |
shows "Zfun (\<lambda>x. g x) F" |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
269 |
proof (cases) |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
270 |
assume K: "0 < K" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
271 |
show ?thesis |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
272 |
proof (rule ZfunI) |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
273 |
fix r::real assume "0 < r" |
56541 | 274 |
hence "0 < r / K" using K by simp |
44195 | 275 |
then have "eventually (\<lambda>x. norm (f x) < r / K) F" |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
276 |
using ZfunD [OF f] by fast |
44195 | 277 |
with g show "eventually (\<lambda>x. norm (g x) < r) F" |
46887 | 278 |
proof eventually_elim |
279 |
case (elim x) |
|
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
280 |
hence "norm (f x) * K < r" |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
281 |
by (simp add: pos_less_divide_eq K) |
46887 | 282 |
thus ?case |
283 |
by (simp add: order_le_less_trans [OF elim(1)]) |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
284 |
qed |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
285 |
qed |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
286 |
next |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
287 |
assume "\<not> 0 < K" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
288 |
hence K: "K \<le> 0" by (simp only: not_less) |
31355 | 289 |
show ?thesis |
290 |
proof (rule ZfunI) |
|
291 |
fix r :: real |
|
292 |
assume "0 < r" |
|
44195 | 293 |
from g show "eventually (\<lambda>x. norm (g x) < r) F" |
46887 | 294 |
proof eventually_elim |
295 |
case (elim x) |
|
296 |
also have "norm (f x) * K \<le> norm (f x) * 0" |
|
31355 | 297 |
using K norm_ge_zero by (rule mult_left_mono) |
46887 | 298 |
finally show ?case |
31355 | 299 |
using `0 < r` by simp |
300 |
qed |
|
301 |
qed |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
302 |
qed |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
303 |
|
44195 | 304 |
lemma Zfun_le: "\<lbrakk>Zfun g F; \<forall>x. norm (f x) \<le> norm (g x)\<rbrakk> \<Longrightarrow> Zfun f F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
305 |
by (erule_tac K="1" in Zfun_imp_Zfun, simp) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
306 |
|
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
307 |
lemma Zfun_add: |
44195 | 308 |
assumes f: "Zfun f F" and g: "Zfun g F" |
309 |
shows "Zfun (\<lambda>x. f x + g x) F" |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
310 |
proof (rule ZfunI) |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
311 |
fix r::real assume "0 < r" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
312 |
hence r: "0 < r / 2" by simp |
44195 | 313 |
have "eventually (\<lambda>x. norm (f x) < r/2) F" |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
314 |
using f r by (rule ZfunD) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
315 |
moreover |
44195 | 316 |
have "eventually (\<lambda>x. norm (g x) < r/2) F" |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
317 |
using g r by (rule ZfunD) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
318 |
ultimately |
44195 | 319 |
show "eventually (\<lambda>x. norm (f x + g x) < r) F" |
46887 | 320 |
proof eventually_elim |
321 |
case (elim x) |
|
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
322 |
have "norm (f x + g x) \<le> norm (f x) + norm (g x)" |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
323 |
by (rule norm_triangle_ineq) |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
324 |
also have "\<dots> < r/2 + r/2" |
46887 | 325 |
using elim by (rule add_strict_mono) |
326 |
finally show ?case |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
327 |
by simp |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
328 |
qed |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
329 |
qed |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
330 |
|
44195 | 331 |
lemma Zfun_minus: "Zfun f F \<Longrightarrow> Zfun (\<lambda>x. - f x) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
332 |
unfolding Zfun_def by simp |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
333 |
|
44195 | 334 |
lemma Zfun_diff: "\<lbrakk>Zfun f F; Zfun g F\<rbrakk> \<Longrightarrow> Zfun (\<lambda>x. f x - g x) F" |
54230
b1d955791529
more simplification rules on unary and binary minus
haftmann
parents:
53602
diff
changeset
|
335 |
using Zfun_add [of f F "\<lambda>x. - g x"] by (simp add: Zfun_minus) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
336 |
|
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
337 |
lemma (in bounded_linear) Zfun: |
44195 | 338 |
assumes g: "Zfun g F" |
339 |
shows "Zfun (\<lambda>x. f (g x)) F" |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
340 |
proof - |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
341 |
obtain K where "\<And>x. norm (f x) \<le> norm x * K" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
342 |
using bounded by fast |
44195 | 343 |
then have "eventually (\<lambda>x. norm (f (g x)) \<le> norm (g x) * K) F" |
31355 | 344 |
by simp |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
345 |
with g show ?thesis |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
346 |
by (rule Zfun_imp_Zfun) |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
347 |
qed |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
348 |
|
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
349 |
lemma (in bounded_bilinear) Zfun: |
44195 | 350 |
assumes f: "Zfun f F" |
351 |
assumes g: "Zfun g F" |
|
352 |
shows "Zfun (\<lambda>x. f x ** g x) F" |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
353 |
proof (rule ZfunI) |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
354 |
fix r::real assume r: "0 < r" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
355 |
obtain K where K: "0 < K" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
356 |
and norm_le: "\<And>x y. norm (x ** y) \<le> norm x * norm y * K" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
357 |
using pos_bounded by fast |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
358 |
from K have K': "0 < inverse K" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
359 |
by (rule positive_imp_inverse_positive) |
44195 | 360 |
have "eventually (\<lambda>x. norm (f x) < r) F" |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
361 |
using f r by (rule ZfunD) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
362 |
moreover |
44195 | 363 |
have "eventually (\<lambda>x. norm (g x) < inverse K) F" |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
364 |
using g K' by (rule ZfunD) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
365 |
ultimately |
44195 | 366 |
show "eventually (\<lambda>x. norm (f x ** g x) < r) F" |
46887 | 367 |
proof eventually_elim |
368 |
case (elim x) |
|
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
369 |
have "norm (f x ** g x) \<le> norm (f x) * norm (g x) * K" |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
370 |
by (rule norm_le) |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
371 |
also have "norm (f x) * norm (g x) * K < r * inverse K * K" |
46887 | 372 |
by (intro mult_strict_right_mono mult_strict_mono' norm_ge_zero elim K) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
373 |
also from K have "r * inverse K * K = r" |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
374 |
by simp |
46887 | 375 |
finally show ?case . |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
376 |
qed |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
377 |
qed |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
378 |
|
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
379 |
lemma (in bounded_bilinear) Zfun_left: |
44195 | 380 |
"Zfun f F \<Longrightarrow> Zfun (\<lambda>x. f x ** a) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
381 |
by (rule bounded_linear_left [THEN bounded_linear.Zfun]) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
382 |
|
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
383 |
lemma (in bounded_bilinear) Zfun_right: |
44195 | 384 |
"Zfun f F \<Longrightarrow> Zfun (\<lambda>x. a ** f x) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
385 |
by (rule bounded_linear_right [THEN bounded_linear.Zfun]) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
386 |
|
44282
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
387 |
lemmas Zfun_mult = bounded_bilinear.Zfun [OF bounded_bilinear_mult] |
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
388 |
lemmas Zfun_mult_right = bounded_bilinear.Zfun_right [OF bounded_bilinear_mult] |
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
389 |
lemmas Zfun_mult_left = bounded_bilinear.Zfun_left [OF bounded_bilinear_mult] |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
390 |
|
44195 | 391 |
lemma tendsto_Zfun_iff: "(f ---> a) F = Zfun (\<lambda>x. f x - a) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
392 |
by (simp only: tendsto_iff Zfun_def dist_norm) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
393 |
|
56366 | 394 |
lemma tendsto_0_le: "\<lbrakk>(f ---> 0) F; eventually (\<lambda>x. norm (g x) \<le> norm (f x) * K) F\<rbrakk> |
395 |
\<Longrightarrow> (g ---> 0) F" |
|
396 |
by (simp add: Zfun_imp_Zfun tendsto_Zfun_iff) |
|
397 |
||
44205
18da2a87421c
generalize constant 'lim' and limit uniqueness theorems to class t2_space
huffman
parents:
44195
diff
changeset
|
398 |
subsubsection {* Distance and norms *} |
36662
621122eeb138
generalize types of LIMSEQ and LIM; generalize many lemmas
huffman
parents:
36656
diff
changeset
|
399 |
|
51531
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
400 |
lemma tendsto_dist [tendsto_intros]: |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
401 |
fixes l m :: "'a :: metric_space" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
402 |
assumes f: "(f ---> l) F" and g: "(g ---> m) F" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
403 |
shows "((\<lambda>x. dist (f x) (g x)) ---> dist l m) F" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
404 |
proof (rule tendstoI) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
405 |
fix e :: real assume "0 < e" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
406 |
hence e2: "0 < e/2" by simp |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
407 |
from tendstoD [OF f e2] tendstoD [OF g e2] |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
408 |
show "eventually (\<lambda>x. dist (dist (f x) (g x)) (dist l m) < e) F" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
409 |
proof (eventually_elim) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
410 |
case (elim x) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
411 |
then show "dist (dist (f x) (g x)) (dist l m) < e" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
412 |
unfolding dist_real_def |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
413 |
using dist_triangle2 [of "f x" "g x" "l"] |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
414 |
using dist_triangle2 [of "g x" "l" "m"] |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
415 |
using dist_triangle3 [of "l" "m" "f x"] |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
416 |
using dist_triangle [of "f x" "m" "g x"] |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
417 |
by arith |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
418 |
qed |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
419 |
qed |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
420 |
|
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
421 |
lemma continuous_dist[continuous_intros]: |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
422 |
fixes f g :: "_ \<Rightarrow> 'a :: metric_space" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
423 |
shows "continuous F f \<Longrightarrow> continuous F g \<Longrightarrow> continuous F (\<lambda>x. dist (f x) (g x))" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
424 |
unfolding continuous_def by (rule tendsto_dist) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
425 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
426 |
lemma continuous_on_dist[continuous_intros]: |
51531
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
427 |
fixes f g :: "_ \<Rightarrow> 'a :: metric_space" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
428 |
shows "continuous_on s f \<Longrightarrow> continuous_on s g \<Longrightarrow> continuous_on s (\<lambda>x. dist (f x) (g x))" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
429 |
unfolding continuous_on_def by (auto intro: tendsto_dist) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
430 |
|
31565 | 431 |
lemma tendsto_norm [tendsto_intros]: |
44195 | 432 |
"(f ---> a) F \<Longrightarrow> ((\<lambda>x. norm (f x)) ---> norm a) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
433 |
unfolding norm_conv_dist by (intro tendsto_intros) |
36662
621122eeb138
generalize types of LIMSEQ and LIM; generalize many lemmas
huffman
parents:
36656
diff
changeset
|
434 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
435 |
lemma continuous_norm [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
436 |
"continuous F f \<Longrightarrow> continuous F (\<lambda>x. norm (f x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
437 |
unfolding continuous_def by (rule tendsto_norm) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
438 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
439 |
lemma continuous_on_norm [continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
440 |
"continuous_on s f \<Longrightarrow> continuous_on s (\<lambda>x. norm (f x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
441 |
unfolding continuous_on_def by (auto intro: tendsto_norm) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
442 |
|
36662
621122eeb138
generalize types of LIMSEQ and LIM; generalize many lemmas
huffman
parents:
36656
diff
changeset
|
443 |
lemma tendsto_norm_zero: |
44195 | 444 |
"(f ---> 0) F \<Longrightarrow> ((\<lambda>x. norm (f x)) ---> 0) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
445 |
by (drule tendsto_norm, simp) |
36662
621122eeb138
generalize types of LIMSEQ and LIM; generalize many lemmas
huffman
parents:
36656
diff
changeset
|
446 |
|
621122eeb138
generalize types of LIMSEQ and LIM; generalize many lemmas
huffman
parents:
36656
diff
changeset
|
447 |
lemma tendsto_norm_zero_cancel: |
44195 | 448 |
"((\<lambda>x. norm (f x)) ---> 0) F \<Longrightarrow> (f ---> 0) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
449 |
unfolding tendsto_iff dist_norm by simp |
36662
621122eeb138
generalize types of LIMSEQ and LIM; generalize many lemmas
huffman
parents:
36656
diff
changeset
|
450 |
|
621122eeb138
generalize types of LIMSEQ and LIM; generalize many lemmas
huffman
parents:
36656
diff
changeset
|
451 |
lemma tendsto_norm_zero_iff: |
44195 | 452 |
"((\<lambda>x. norm (f x)) ---> 0) F \<longleftrightarrow> (f ---> 0) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
453 |
unfolding tendsto_iff dist_norm by simp |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
454 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
455 |
lemma tendsto_rabs [tendsto_intros]: |
44195 | 456 |
"(f ---> (l::real)) F \<Longrightarrow> ((\<lambda>x. \<bar>f x\<bar>) ---> \<bar>l\<bar>) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
457 |
by (fold real_norm_def, rule tendsto_norm) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
458 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
459 |
lemma continuous_rabs [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
460 |
"continuous F f \<Longrightarrow> continuous F (\<lambda>x. \<bar>f x :: real\<bar>)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
461 |
unfolding real_norm_def[symmetric] by (rule continuous_norm) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
462 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
463 |
lemma continuous_on_rabs [continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
464 |
"continuous_on s f \<Longrightarrow> continuous_on s (\<lambda>x. \<bar>f x :: real\<bar>)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
465 |
unfolding real_norm_def[symmetric] by (rule continuous_on_norm) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
466 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
467 |
lemma tendsto_rabs_zero: |
44195 | 468 |
"(f ---> (0::real)) F \<Longrightarrow> ((\<lambda>x. \<bar>f x\<bar>) ---> 0) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
469 |
by (fold real_norm_def, rule tendsto_norm_zero) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
470 |
|
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
471 |
lemma tendsto_rabs_zero_cancel: |
44195 | 472 |
"((\<lambda>x. \<bar>f x\<bar>) ---> (0::real)) F \<Longrightarrow> (f ---> 0) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
473 |
by (fold real_norm_def, rule tendsto_norm_zero_cancel) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
474 |
|
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
475 |
lemma tendsto_rabs_zero_iff: |
44195 | 476 |
"((\<lambda>x. \<bar>f x\<bar>) ---> (0::real)) F \<longleftrightarrow> (f ---> 0) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
477 |
by (fold real_norm_def, rule tendsto_norm_zero_iff) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
478 |
|
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
479 |
subsubsection {* Addition and subtraction *} |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
480 |
|
31565 | 481 |
lemma tendsto_add [tendsto_intros]: |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
482 |
fixes a b :: "'a::real_normed_vector" |
44195 | 483 |
shows "\<lbrakk>(f ---> a) F; (g ---> b) F\<rbrakk> \<Longrightarrow> ((\<lambda>x. f x + g x) ---> a + b) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
484 |
by (simp only: tendsto_Zfun_iff add_diff_add Zfun_add) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
485 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
486 |
lemma continuous_add [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
487 |
fixes f g :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
488 |
shows "continuous F f \<Longrightarrow> continuous F g \<Longrightarrow> continuous F (\<lambda>x. f x + g x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
489 |
unfolding continuous_def by (rule tendsto_add) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
490 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
491 |
lemma continuous_on_add [continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
492 |
fixes f g :: "_ \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
493 |
shows "continuous_on s f \<Longrightarrow> continuous_on s g \<Longrightarrow> continuous_on s (\<lambda>x. f x + g x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
494 |
unfolding continuous_on_def by (auto intro: tendsto_add) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
495 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
496 |
lemma tendsto_add_zero: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
497 |
fixes f g :: "_ \<Rightarrow> 'b::real_normed_vector" |
44195 | 498 |
shows "\<lbrakk>(f ---> 0) F; (g ---> 0) F\<rbrakk> \<Longrightarrow> ((\<lambda>x. f x + g x) ---> 0) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
499 |
by (drule (1) tendsto_add, simp) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
500 |
|
31565 | 501 |
lemma tendsto_minus [tendsto_intros]: |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
502 |
fixes a :: "'a::real_normed_vector" |
44195 | 503 |
shows "(f ---> a) F \<Longrightarrow> ((\<lambda>x. - f x) ---> - a) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
504 |
by (simp only: tendsto_Zfun_iff minus_diff_minus Zfun_minus) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
505 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
506 |
lemma continuous_minus [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
507 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
508 |
shows "continuous F f \<Longrightarrow> continuous F (\<lambda>x. - f x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
509 |
unfolding continuous_def by (rule tendsto_minus) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
510 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
511 |
lemma continuous_on_minus [continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
512 |
fixes f :: "_ \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
513 |
shows "continuous_on s f \<Longrightarrow> continuous_on s (\<lambda>x. - f x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
514 |
unfolding continuous_on_def by (auto intro: tendsto_minus) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
515 |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
516 |
lemma tendsto_minus_cancel: |
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
517 |
fixes a :: "'a::real_normed_vector" |
44195 | 518 |
shows "((\<lambda>x. - f x) ---> - a) F \<Longrightarrow> (f ---> a) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
519 |
by (drule tendsto_minus, simp) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
520 |
|
50330
d0b12171118e
conversion rules for at, at_left and at_right; applied to l'Hopital's rules.
hoelzl
parents:
50327
diff
changeset
|
521 |
lemma tendsto_minus_cancel_left: |
d0b12171118e
conversion rules for at, at_left and at_right; applied to l'Hopital's rules.
hoelzl
parents:
50327
diff
changeset
|
522 |
"(f ---> - (y::_::real_normed_vector)) F \<longleftrightarrow> ((\<lambda>x. - f x) ---> y) F" |
d0b12171118e
conversion rules for at, at_left and at_right; applied to l'Hopital's rules.
hoelzl
parents:
50327
diff
changeset
|
523 |
using tendsto_minus_cancel[of f "- y" F] tendsto_minus[of f "- y" F] |
d0b12171118e
conversion rules for at, at_left and at_right; applied to l'Hopital's rules.
hoelzl
parents:
50327
diff
changeset
|
524 |
by auto |
d0b12171118e
conversion rules for at, at_left and at_right; applied to l'Hopital's rules.
hoelzl
parents:
50327
diff
changeset
|
525 |
|
31565 | 526 |
lemma tendsto_diff [tendsto_intros]: |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
527 |
fixes a b :: "'a::real_normed_vector" |
44195 | 528 |
shows "\<lbrakk>(f ---> a) F; (g ---> b) F\<rbrakk> \<Longrightarrow> ((\<lambda>x. f x - g x) ---> a - b) F" |
54230
b1d955791529
more simplification rules on unary and binary minus
haftmann
parents:
53602
diff
changeset
|
529 |
using tendsto_add [of f a F "\<lambda>x. - g x" "- b"] by (simp add: tendsto_minus) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
530 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
531 |
lemma continuous_diff [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
532 |
fixes f g :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
533 |
shows "continuous F f \<Longrightarrow> continuous F g \<Longrightarrow> continuous F (\<lambda>x. f x - g x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
534 |
unfolding continuous_def by (rule tendsto_diff) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
535 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
536 |
lemma continuous_on_diff [continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
537 |
fixes f g :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
538 |
shows "continuous_on s f \<Longrightarrow> continuous_on s g \<Longrightarrow> continuous_on s (\<lambda>x. f x - g x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
539 |
unfolding continuous_on_def by (auto intro: tendsto_diff) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
540 |
|
31588 | 541 |
lemma tendsto_setsum [tendsto_intros]: |
542 |
fixes f :: "'a \<Rightarrow> 'b \<Rightarrow> 'c::real_normed_vector" |
|
44195 | 543 |
assumes "\<And>i. i \<in> S \<Longrightarrow> (f i ---> a i) F" |
544 |
shows "((\<lambda>x. \<Sum>i\<in>S. f i x) ---> (\<Sum>i\<in>S. a i)) F" |
|
31588 | 545 |
proof (cases "finite S") |
546 |
assume "finite S" thus ?thesis using assms |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
547 |
by (induct, simp add: tendsto_const, simp add: tendsto_add) |
31588 | 548 |
next |
549 |
assume "\<not> finite S" thus ?thesis |
|
550 |
by (simp add: tendsto_const) |
|
551 |
qed |
|
552 |
||
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
553 |
lemma continuous_setsum [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
554 |
fixes f :: "'a \<Rightarrow> 'b::t2_space \<Rightarrow> 'c::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
555 |
shows "(\<And>i. i \<in> S \<Longrightarrow> continuous F (f i)) \<Longrightarrow> continuous F (\<lambda>x. \<Sum>i\<in>S. f i x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
556 |
unfolding continuous_def by (rule tendsto_setsum) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
557 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
558 |
lemma continuous_on_setsum [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
559 |
fixes f :: "'a \<Rightarrow> _ \<Rightarrow> 'c::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
560 |
shows "(\<And>i. i \<in> S \<Longrightarrow> continuous_on s (f i)) \<Longrightarrow> continuous_on s (\<lambda>x. \<Sum>i\<in>S. f i x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
561 |
unfolding continuous_on_def by (auto intro: tendsto_setsum) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
562 |
|
50999 | 563 |
lemmas real_tendsto_sandwich = tendsto_sandwich[where 'b=real] |
564 |
||
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
565 |
subsubsection {* Linear operators and multiplication *} |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
566 |
|
44282
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
567 |
lemma (in bounded_linear) tendsto: |
44195 | 568 |
"(g ---> a) F \<Longrightarrow> ((\<lambda>x. f (g x)) ---> f a) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
569 |
by (simp only: tendsto_Zfun_iff diff [symmetric] Zfun) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
570 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
571 |
lemma (in bounded_linear) continuous: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
572 |
"continuous F g \<Longrightarrow> continuous F (\<lambda>x. f (g x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
573 |
using tendsto[of g _ F] by (auto simp: continuous_def) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
574 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
575 |
lemma (in bounded_linear) continuous_on: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
576 |
"continuous_on s g \<Longrightarrow> continuous_on s (\<lambda>x. f (g x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
577 |
using tendsto[of g] by (auto simp: continuous_on_def) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
578 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
579 |
lemma (in bounded_linear) tendsto_zero: |
44195 | 580 |
"(g ---> 0) F \<Longrightarrow> ((\<lambda>x. f (g x)) ---> 0) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
581 |
by (drule tendsto, simp only: zero) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
582 |
|
44282
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
583 |
lemma (in bounded_bilinear) tendsto: |
44195 | 584 |
"\<lbrakk>(f ---> a) F; (g ---> b) F\<rbrakk> \<Longrightarrow> ((\<lambda>x. f x ** g x) ---> a ** b) F" |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
585 |
by (simp only: tendsto_Zfun_iff prod_diff_prod |
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
586 |
Zfun_add Zfun Zfun_left Zfun_right) |
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
587 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
588 |
lemma (in bounded_bilinear) continuous: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
589 |
"continuous F f \<Longrightarrow> continuous F g \<Longrightarrow> continuous F (\<lambda>x. f x ** g x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
590 |
using tendsto[of f _ F g] by (auto simp: continuous_def) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
591 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
592 |
lemma (in bounded_bilinear) continuous_on: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
593 |
"continuous_on s f \<Longrightarrow> continuous_on s g \<Longrightarrow> continuous_on s (\<lambda>x. f x ** g x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
594 |
using tendsto[of f _ _ g] by (auto simp: continuous_on_def) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
595 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
596 |
lemma (in bounded_bilinear) tendsto_zero: |
44195 | 597 |
assumes f: "(f ---> 0) F" |
598 |
assumes g: "(g ---> 0) F" |
|
599 |
shows "((\<lambda>x. f x ** g x) ---> 0) F" |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
600 |
using tendsto [OF f g] by (simp add: zero_left) |
31355 | 601 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
602 |
lemma (in bounded_bilinear) tendsto_left_zero: |
44195 | 603 |
"(f ---> 0) F \<Longrightarrow> ((\<lambda>x. f x ** c) ---> 0) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
604 |
by (rule bounded_linear.tendsto_zero [OF bounded_linear_left]) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
605 |
|
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
606 |
lemma (in bounded_bilinear) tendsto_right_zero: |
44195 | 607 |
"(f ---> 0) F \<Longrightarrow> ((\<lambda>x. c ** f x) ---> 0) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
608 |
by (rule bounded_linear.tendsto_zero [OF bounded_linear_right]) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
609 |
|
44282
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
610 |
lemmas tendsto_of_real [tendsto_intros] = |
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
611 |
bounded_linear.tendsto [OF bounded_linear_of_real] |
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
612 |
|
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
613 |
lemmas tendsto_scaleR [tendsto_intros] = |
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
614 |
bounded_bilinear.tendsto [OF bounded_bilinear_scaleR] |
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
615 |
|
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
616 |
lemmas tendsto_mult [tendsto_intros] = |
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
617 |
bounded_bilinear.tendsto [OF bounded_bilinear_mult] |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
618 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
619 |
lemmas continuous_of_real [continuous_intros] = |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
620 |
bounded_linear.continuous [OF bounded_linear_of_real] |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
621 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
622 |
lemmas continuous_scaleR [continuous_intros] = |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
623 |
bounded_bilinear.continuous [OF bounded_bilinear_scaleR] |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
624 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
625 |
lemmas continuous_mult [continuous_intros] = |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
626 |
bounded_bilinear.continuous [OF bounded_bilinear_mult] |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
627 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
628 |
lemmas continuous_on_of_real [continuous_intros] = |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
629 |
bounded_linear.continuous_on [OF bounded_linear_of_real] |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
630 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
631 |
lemmas continuous_on_scaleR [continuous_intros] = |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
632 |
bounded_bilinear.continuous_on [OF bounded_bilinear_scaleR] |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
633 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
634 |
lemmas continuous_on_mult [continuous_intros] = |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
635 |
bounded_bilinear.continuous_on [OF bounded_bilinear_mult] |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
636 |
|
44568
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
637 |
lemmas tendsto_mult_zero = |
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
638 |
bounded_bilinear.tendsto_zero [OF bounded_bilinear_mult] |
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
639 |
|
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
640 |
lemmas tendsto_mult_left_zero = |
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
641 |
bounded_bilinear.tendsto_left_zero [OF bounded_bilinear_mult] |
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
642 |
|
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
643 |
lemmas tendsto_mult_right_zero = |
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
644 |
bounded_bilinear.tendsto_right_zero [OF bounded_bilinear_mult] |
e6f291cb5810
discontinue many legacy theorems about LIM and LIMSEQ, in favor of tendsto theorems
huffman
parents:
44342
diff
changeset
|
645 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
646 |
lemma tendsto_power [tendsto_intros]: |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
647 |
fixes f :: "'a \<Rightarrow> 'b::{power,real_normed_algebra}" |
44195 | 648 |
shows "(f ---> a) F \<Longrightarrow> ((\<lambda>x. f x ^ n) ---> a ^ n) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
649 |
by (induct n) (simp_all add: tendsto_const tendsto_mult) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
650 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
651 |
lemma continuous_power [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
652 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::{power,real_normed_algebra}" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
653 |
shows "continuous F f \<Longrightarrow> continuous F (\<lambda>x. (f x)^n)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
654 |
unfolding continuous_def by (rule tendsto_power) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
655 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
656 |
lemma continuous_on_power [continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
657 |
fixes f :: "_ \<Rightarrow> 'b::{power,real_normed_algebra}" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
658 |
shows "continuous_on s f \<Longrightarrow> continuous_on s (\<lambda>x. (f x)^n)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
659 |
unfolding continuous_on_def by (auto intro: tendsto_power) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
660 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
661 |
lemma tendsto_setprod [tendsto_intros]: |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
662 |
fixes f :: "'a \<Rightarrow> 'b \<Rightarrow> 'c::{real_normed_algebra,comm_ring_1}" |
44195 | 663 |
assumes "\<And>i. i \<in> S \<Longrightarrow> (f i ---> L i) F" |
664 |
shows "((\<lambda>x. \<Prod>i\<in>S. f i x) ---> (\<Prod>i\<in>S. L i)) F" |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
665 |
proof (cases "finite S") |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
666 |
assume "finite S" thus ?thesis using assms |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
667 |
by (induct, simp add: tendsto_const, simp add: tendsto_mult) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
668 |
next |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
669 |
assume "\<not> finite S" thus ?thesis |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
670 |
by (simp add: tendsto_const) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
671 |
qed |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
672 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
673 |
lemma continuous_setprod [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
674 |
fixes f :: "'a \<Rightarrow> 'b::t2_space \<Rightarrow> 'c::{real_normed_algebra,comm_ring_1}" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
675 |
shows "(\<And>i. i \<in> S \<Longrightarrow> continuous F (f i)) \<Longrightarrow> continuous F (\<lambda>x. \<Prod>i\<in>S. f i x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
676 |
unfolding continuous_def by (rule tendsto_setprod) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
677 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
678 |
lemma continuous_on_setprod [continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
679 |
fixes f :: "'a \<Rightarrow> _ \<Rightarrow> 'c::{real_normed_algebra,comm_ring_1}" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
680 |
shows "(\<And>i. i \<in> S \<Longrightarrow> continuous_on s (f i)) \<Longrightarrow> continuous_on s (\<lambda>x. \<Prod>i\<in>S. f i x)" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
681 |
unfolding continuous_on_def by (auto intro: tendsto_setprod) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
682 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
683 |
subsubsection {* Inverse and division *} |
31355 | 684 |
|
685 |
lemma (in bounded_bilinear) Zfun_prod_Bfun: |
|
44195 | 686 |
assumes f: "Zfun f F" |
687 |
assumes g: "Bfun g F" |
|
688 |
shows "Zfun (\<lambda>x. f x ** g x) F" |
|
31355 | 689 |
proof - |
690 |
obtain K where K: "0 \<le> K" |
|
691 |
and norm_le: "\<And>x y. norm (x ** y) \<le> norm x * norm y * K" |
|
692 |
using nonneg_bounded by fast |
|
693 |
obtain B where B: "0 < B" |
|
44195 | 694 |
and norm_g: "eventually (\<lambda>x. norm (g x) \<le> B) F" |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
695 |
using g by (rule BfunE) |
44195 | 696 |
have "eventually (\<lambda>x. norm (f x ** g x) \<le> norm (f x) * (B * K)) F" |
46887 | 697 |
using norm_g proof eventually_elim |
698 |
case (elim x) |
|
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
699 |
have "norm (f x ** g x) \<le> norm (f x) * norm (g x) * K" |
31355 | 700 |
by (rule norm_le) |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
701 |
also have "\<dots> \<le> norm (f x) * B * K" |
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
702 |
by (intro mult_mono' order_refl norm_g norm_ge_zero |
46887 | 703 |
mult_nonneg_nonneg K elim) |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
704 |
also have "\<dots> = norm (f x) * (B * K)" |
57512
cc97b347b301
reduced name variants for assoc and commute on plus and mult
haftmann
parents:
57447
diff
changeset
|
705 |
by (rule mult.assoc) |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
706 |
finally show "norm (f x ** g x) \<le> norm (f x) * (B * K)" . |
31355 | 707 |
qed |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
708 |
with f show ?thesis |
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
709 |
by (rule Zfun_imp_Zfun) |
31355 | 710 |
qed |
711 |
||
712 |
lemma (in bounded_bilinear) flip: |
|
713 |
"bounded_bilinear (\<lambda>x y. y ** x)" |
|
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
714 |
apply default |
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
715 |
apply (rule add_right) |
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
716 |
apply (rule add_left) |
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
717 |
apply (rule scaleR_right) |
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
718 |
apply (rule scaleR_left) |
57512
cc97b347b301
reduced name variants for assoc and commute on plus and mult
haftmann
parents:
57447
diff
changeset
|
719 |
apply (subst mult.commute) |
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
720 |
using bounded by fast |
31355 | 721 |
|
722 |
lemma (in bounded_bilinear) Bfun_prod_Zfun: |
|
44195 | 723 |
assumes f: "Bfun f F" |
724 |
assumes g: "Zfun g F" |
|
725 |
shows "Zfun (\<lambda>x. f x ** g x) F" |
|
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
726 |
using flip g f by (rule bounded_bilinear.Zfun_prod_Bfun) |
31355 | 727 |
|
728 |
lemma Bfun_inverse_lemma: |
|
729 |
fixes x :: "'a::real_normed_div_algebra" |
|
730 |
shows "\<lbrakk>r \<le> norm x; 0 < r\<rbrakk> \<Longrightarrow> norm (inverse x) \<le> inverse r" |
|
44081
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
731 |
apply (subst nonzero_norm_inverse, clarsimp) |
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
732 |
apply (erule (1) le_imp_inverse_le) |
730f7cced3a6
rename type 'a net to 'a filter, following standard mathematical terminology
huffman
parents:
44079
diff
changeset
|
733 |
done |
31355 | 734 |
|
735 |
lemma Bfun_inverse: |
|
736 |
fixes a :: "'a::real_normed_div_algebra" |
|
44195 | 737 |
assumes f: "(f ---> a) F" |
31355 | 738 |
assumes a: "a \<noteq> 0" |
44195 | 739 |
shows "Bfun (\<lambda>x. inverse (f x)) F" |
31355 | 740 |
proof - |
741 |
from a have "0 < norm a" by simp |
|
742 |
hence "\<exists>r>0. r < norm a" by (rule dense) |
|
743 |
then obtain r where r1: "0 < r" and r2: "r < norm a" by fast |
|
44195 | 744 |
have "eventually (\<lambda>x. dist (f x) a < r) F" |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
745 |
using tendstoD [OF f r1] by fast |
44195 | 746 |
hence "eventually (\<lambda>x. norm (inverse (f x)) \<le> inverse (norm a - r)) F" |
46887 | 747 |
proof eventually_elim |
748 |
case (elim x) |
|
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
749 |
hence 1: "norm (f x - a) < r" |
31355 | 750 |
by (simp add: dist_norm) |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
751 |
hence 2: "f x \<noteq> 0" using r2 by auto |
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
752 |
hence "norm (inverse (f x)) = inverse (norm (f x))" |
31355 | 753 |
by (rule nonzero_norm_inverse) |
754 |
also have "\<dots> \<le> inverse (norm a - r)" |
|
755 |
proof (rule le_imp_inverse_le) |
|
756 |
show "0 < norm a - r" using r2 by simp |
|
757 |
next |
|
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
758 |
have "norm a - norm (f x) \<le> norm (a - f x)" |
31355 | 759 |
by (rule norm_triangle_ineq2) |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
760 |
also have "\<dots> = norm (f x - a)" |
31355 | 761 |
by (rule norm_minus_commute) |
762 |
also have "\<dots> < r" using 1 . |
|
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
763 |
finally show "norm a - r \<le> norm (f x)" by simp |
31355 | 764 |
qed |
31487
93938cafc0e6
put syntax for tendsto in Limits.thy; rename variables
huffman
parents:
31447
diff
changeset
|
765 |
finally show "norm (inverse (f x)) \<le> inverse (norm a - r)" . |
31355 | 766 |
qed |
767 |
thus ?thesis by (rule BfunI) |
|
768 |
qed |
|
769 |
||
31565 | 770 |
lemma tendsto_inverse [tendsto_intros]: |
31355 | 771 |
fixes a :: "'a::real_normed_div_algebra" |
44195 | 772 |
assumes f: "(f ---> a) F" |
31355 | 773 |
assumes a: "a \<noteq> 0" |
44195 | 774 |
shows "((\<lambda>x. inverse (f x)) ---> inverse a) F" |
31355 | 775 |
proof - |
776 |
from a have "0 < norm a" by simp |
|
44195 | 777 |
with f have "eventually (\<lambda>x. dist (f x) a < norm a) F" |
31355 | 778 |
by (rule tendstoD) |
44195 | 779 |
then have "eventually (\<lambda>x. f x \<noteq> 0) F" |
31355 | 780 |
unfolding dist_norm by (auto elim!: eventually_elim1) |
44627 | 781 |
with a have "eventually (\<lambda>x. inverse (f x) - inverse a = |
782 |
- (inverse (f x) * (f x - a) * inverse a)) F" |
|
783 |
by (auto elim!: eventually_elim1 simp: inverse_diff_inverse) |
|
784 |
moreover have "Zfun (\<lambda>x. - (inverse (f x) * (f x - a) * inverse a)) F" |
|
785 |
by (intro Zfun_minus Zfun_mult_left |
|
786 |
bounded_bilinear.Bfun_prod_Zfun [OF bounded_bilinear_mult] |
|
787 |
Bfun_inverse [OF f a] f [unfolded tendsto_Zfun_iff]) |
|
788 |
ultimately show ?thesis |
|
789 |
unfolding tendsto_Zfun_iff by (rule Zfun_ssubst) |
|
31355 | 790 |
qed |
791 |
||
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
792 |
lemma continuous_inverse: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
793 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_div_algebra" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
794 |
assumes "continuous F f" and "f (Lim F (\<lambda>x. x)) \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
795 |
shows "continuous F (\<lambda>x. inverse (f x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
796 |
using assms unfolding continuous_def by (rule tendsto_inverse) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
797 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
798 |
lemma continuous_at_within_inverse[continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
799 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_div_algebra" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
800 |
assumes "continuous (at a within s) f" and "f a \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
801 |
shows "continuous (at a within s) (\<lambda>x. inverse (f x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
802 |
using assms unfolding continuous_within by (rule tendsto_inverse) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
803 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
804 |
lemma isCont_inverse[continuous_intros, simp]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
805 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_div_algebra" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
806 |
assumes "isCont f a" and "f a \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
807 |
shows "isCont (\<lambda>x. inverse (f x)) a" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
808 |
using assms unfolding continuous_at by (rule tendsto_inverse) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
809 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
810 |
lemma continuous_on_inverse[continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
811 |
fixes f :: "'a::topological_space \<Rightarrow> 'b::real_normed_div_algebra" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
812 |
assumes "continuous_on s f" and "\<forall>x\<in>s. f x \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
813 |
shows "continuous_on s (\<lambda>x. inverse (f x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
814 |
using assms unfolding continuous_on_def by (fast intro: tendsto_inverse) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
815 |
|
31565 | 816 |
lemma tendsto_divide [tendsto_intros]: |
31355 | 817 |
fixes a b :: "'a::real_normed_field" |
44195 | 818 |
shows "\<lbrakk>(f ---> a) F; (g ---> b) F; b \<noteq> 0\<rbrakk> |
819 |
\<Longrightarrow> ((\<lambda>x. f x / g x) ---> a / b) F" |
|
44282
f0de18b62d63
remove bounded_(bi)linear locale interpretations, to avoid duplicating so many lemmas
huffman
parents:
44253
diff
changeset
|
820 |
by (simp add: tendsto_mult tendsto_inverse divide_inverse) |
31355 | 821 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
822 |
lemma continuous_divide: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
823 |
fixes f g :: "'a::t2_space \<Rightarrow> 'b::real_normed_field" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
824 |
assumes "continuous F f" and "continuous F g" and "g (Lim F (\<lambda>x. x)) \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
825 |
shows "continuous F (\<lambda>x. (f x) / (g x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
826 |
using assms unfolding continuous_def by (rule tendsto_divide) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
827 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
828 |
lemma continuous_at_within_divide[continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
829 |
fixes f g :: "'a::t2_space \<Rightarrow> 'b::real_normed_field" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
830 |
assumes "continuous (at a within s) f" "continuous (at a within s) g" and "g a \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
831 |
shows "continuous (at a within s) (\<lambda>x. (f x) / (g x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
832 |
using assms unfolding continuous_within by (rule tendsto_divide) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
833 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
834 |
lemma isCont_divide[continuous_intros, simp]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
835 |
fixes f g :: "'a::t2_space \<Rightarrow> 'b::real_normed_field" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
836 |
assumes "isCont f a" "isCont g a" "g a \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
837 |
shows "isCont (\<lambda>x. (f x) / g x) a" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
838 |
using assms unfolding continuous_at by (rule tendsto_divide) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
839 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
840 |
lemma continuous_on_divide[continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
841 |
fixes f :: "'a::topological_space \<Rightarrow> 'b::real_normed_field" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
842 |
assumes "continuous_on s f" "continuous_on s g" and "\<forall>x\<in>s. g x \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
843 |
shows "continuous_on s (\<lambda>x. (f x) / (g x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
844 |
using assms unfolding continuous_on_def by (fast intro: tendsto_divide) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
845 |
|
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
846 |
lemma tendsto_sgn [tendsto_intros]: |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
847 |
fixes l :: "'a::real_normed_vector" |
44195 | 848 |
shows "\<lbrakk>(f ---> l) F; l \<noteq> 0\<rbrakk> \<Longrightarrow> ((\<lambda>x. sgn (f x)) ---> sgn l) F" |
44194
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
849 |
unfolding sgn_div_norm by (simp add: tendsto_intros) |
0639898074ae
generalize lemmas about LIM and LIMSEQ to tendsto
huffman
parents:
44081
diff
changeset
|
850 |
|
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
851 |
lemma continuous_sgn: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
852 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
853 |
assumes "continuous F f" and "f (Lim F (\<lambda>x. x)) \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
854 |
shows "continuous F (\<lambda>x. sgn (f x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
855 |
using assms unfolding continuous_def by (rule tendsto_sgn) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
856 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
857 |
lemma continuous_at_within_sgn[continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
858 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
859 |
assumes "continuous (at a within s) f" and "f a \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
860 |
shows "continuous (at a within s) (\<lambda>x. sgn (f x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
861 |
using assms unfolding continuous_within by (rule tendsto_sgn) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
862 |
|
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
863 |
lemma isCont_sgn[continuous_intros]: |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
864 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
865 |
assumes "isCont f a" and "f a \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
866 |
shows "isCont (\<lambda>x. sgn (f x)) a" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
867 |
using assms unfolding continuous_at by (rule tendsto_sgn) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
868 |
|
56371
fb9ae0727548
extend continuous_intros; remove continuous_on_intros and isCont_intros
hoelzl
parents:
56366
diff
changeset
|
869 |
lemma continuous_on_sgn[continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
870 |
fixes f :: "'a::topological_space \<Rightarrow> 'b::real_normed_vector" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
871 |
assumes "continuous_on s f" and "\<forall>x\<in>s. f x \<noteq> 0" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
872 |
shows "continuous_on s (\<lambda>x. sgn (f x))" |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
873 |
using assms unfolding continuous_on_def by (fast intro: tendsto_sgn) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
51474
diff
changeset
|
874 |
|
50325 | 875 |
lemma filterlim_at_infinity: |
876 |
fixes f :: "_ \<Rightarrow> 'a\<Colon>real_normed_vector" |
|
877 |
assumes "0 \<le> c" |
|
878 |
shows "(LIM x F. f x :> at_infinity) \<longleftrightarrow> (\<forall>r>c. eventually (\<lambda>x. r \<le> norm (f x)) F)" |
|
879 |
unfolding filterlim_iff eventually_at_infinity |
|
880 |
proof safe |
|
881 |
fix P :: "'a \<Rightarrow> bool" and b |
|
882 |
assume *: "\<forall>r>c. eventually (\<lambda>x. r \<le> norm (f x)) F" |
|
883 |
and P: "\<forall>x. b \<le> norm x \<longrightarrow> P x" |
|
884 |
have "max b (c + 1) > c" by auto |
|
885 |
with * have "eventually (\<lambda>x. max b (c + 1) \<le> norm (f x)) F" |
|
886 |
by auto |
|
887 |
then show "eventually (\<lambda>x. P (f x)) F" |
|
888 |
proof eventually_elim |
|
889 |
fix x assume "max b (c + 1) \<le> norm (f x)" |
|
890 |
with P show "P (f x)" by auto |
|
891 |
qed |
|
892 |
qed force |
|
893 |
||
51529
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
894 |
|
50347 | 895 |
subsection {* Relate @{const at}, @{const at_left} and @{const at_right} *} |
896 |
||
897 |
text {* |
|
898 |
||
899 |
This lemmas are useful for conversion between @{term "at x"} to @{term "at_left x"} and |
|
900 |
@{term "at_right x"} and also @{term "at_right 0"}. |
|
901 |
||
902 |
*} |
|
903 |
||
51471 | 904 |
lemmas filterlim_split_at_real = filterlim_split_at[where 'a=real] |
50323 | 905 |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
906 |
lemma filtermap_homeomorph: |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
907 |
assumes f: "continuous (at a) f" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
908 |
assumes g: "continuous (at (f a)) g" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
909 |
assumes bij1: "\<forall>x. f (g x) = x" and bij2: "\<forall>x. g (f x) = x" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
910 |
shows "filtermap f (nhds a) = nhds (f a)" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
911 |
unfolding filter_eq_iff eventually_filtermap eventually_nhds |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
912 |
proof safe |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
913 |
fix P S assume S: "open S" "f a \<in> S" and P: "\<forall>x\<in>S. P x" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
914 |
from continuous_within_topological[THEN iffD1, rule_format, OF f S] P |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
915 |
show "\<exists>S. open S \<and> a \<in> S \<and> (\<forall>x\<in>S. P (f x))" by auto |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
916 |
next |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
917 |
fix P S assume S: "open S" "a \<in> S" and P: "\<forall>x\<in>S. P (f x)" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
918 |
with continuous_within_topological[THEN iffD1, rule_format, OF g, of S] bij2 |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
919 |
obtain A where "open A" "f a \<in> A" "(\<forall>y\<in>A. g y \<in> S)" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
920 |
by (metis UNIV_I) |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
921 |
with P bij1 show "\<exists>S. open S \<and> f a \<in> S \<and> (\<forall>x\<in>S. P x)" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
922 |
by (force intro!: exI[of _ A]) |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
923 |
qed |
50347 | 924 |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
925 |
lemma filtermap_nhds_shift: "filtermap (\<lambda>x. x - d) (nhds a) = nhds (a - d::'a::real_normed_vector)" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
926 |
by (rule filtermap_homeomorph[where g="\<lambda>x. x + d"]) (auto intro: continuous_intros) |
50347 | 927 |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
928 |
lemma filtermap_nhds_minus: "filtermap (\<lambda>x. - x) (nhds a) = nhds (- a::'a::real_normed_vector)" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
929 |
by (rule filtermap_homeomorph[where g=uminus]) (auto intro: continuous_minus) |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
930 |
|
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
931 |
lemma filtermap_at_shift: "filtermap (\<lambda>x. x - d) (at a) = at (a - d::'a::real_normed_vector)" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
932 |
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_shift[symmetric]) |
50347 | 933 |
|
934 |
lemma filtermap_at_right_shift: "filtermap (\<lambda>x. x - d) (at_right a) = at_right (a - d::real)" |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
935 |
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_shift[symmetric]) |
50323 | 936 |
|
50347 | 937 |
lemma at_right_to_0: "at_right (a::real) = filtermap (\<lambda>x. x + a) (at_right 0)" |
938 |
using filtermap_at_right_shift[of "-a" 0] by simp |
|
939 |
||
940 |
lemma filterlim_at_right_to_0: |
|
941 |
"filterlim f F (at_right (a::real)) \<longleftrightarrow> filterlim (\<lambda>x. f (x + a)) F (at_right 0)" |
|
942 |
unfolding filterlim_def filtermap_filtermap at_right_to_0[of a] .. |
|
943 |
||
944 |
lemma eventually_at_right_to_0: |
|
945 |
"eventually P (at_right (a::real)) \<longleftrightarrow> eventually (\<lambda>x. P (x + a)) (at_right 0)" |
|
946 |
unfolding at_right_to_0[of a] by (simp add: eventually_filtermap) |
|
947 |
||
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
948 |
lemma filtermap_at_minus: "filtermap (\<lambda>x. - x) (at a) = at (- a::'a::real_normed_vector)" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
949 |
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_minus[symmetric]) |
50347 | 950 |
|
951 |
lemma at_left_minus: "at_left (a::real) = filtermap (\<lambda>x. - x) (at_right (- a))" |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
952 |
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_minus[symmetric]) |
50323 | 953 |
|
50347 | 954 |
lemma at_right_minus: "at_right (a::real) = filtermap (\<lambda>x. - x) (at_left (- a))" |
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
955 |
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_minus[symmetric]) |
50347 | 956 |
|
957 |
lemma filterlim_at_left_to_right: |
|
958 |
"filterlim f F (at_left (a::real)) \<longleftrightarrow> filterlim (\<lambda>x. f (- x)) F (at_right (-a))" |
|
959 |
unfolding filterlim_def filtermap_filtermap at_left_minus[of a] .. |
|
960 |
||
961 |
lemma eventually_at_left_to_right: |
|
962 |
"eventually P (at_left (a::real)) \<longleftrightarrow> eventually (\<lambda>x. P (- x)) (at_right (-a))" |
|
963 |
unfolding at_left_minus[of a] by (simp add: eventually_filtermap) |
|
964 |
||
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
965 |
lemma at_top_mirror: "at_top = filtermap uminus (at_bot :: real filter)" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
966 |
unfolding filter_eq_iff eventually_filtermap eventually_at_top_linorder eventually_at_bot_linorder |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
967 |
by (metis le_minus_iff minus_minus) |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
968 |
|
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
969 |
lemma at_bot_mirror: "at_bot = filtermap uminus (at_top :: real filter)" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
970 |
unfolding at_top_mirror filtermap_filtermap by (simp add: filtermap_ident) |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
971 |
|
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
972 |
lemma filterlim_at_top_mirror: "(LIM x at_top. f x :> F) \<longleftrightarrow> (LIM x at_bot. f (-x::real) :> F)" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
973 |
unfolding filterlim_def at_top_mirror filtermap_filtermap .. |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
974 |
|
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
975 |
lemma filterlim_at_bot_mirror: "(LIM x at_bot. f x :> F) \<longleftrightarrow> (LIM x at_top. f (-x::real) :> F)" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
976 |
unfolding filterlim_def at_bot_mirror filtermap_filtermap .. |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
977 |
|
50323 | 978 |
lemma filterlim_uminus_at_top_at_bot: "LIM x at_bot. - x :: real :> at_top" |
979 |
unfolding filterlim_at_top eventually_at_bot_dense |
|
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
980 |
by (metis leI minus_less_iff order_less_asym) |
50323 | 981 |
|
982 |
lemma filterlim_uminus_at_bot_at_top: "LIM x at_top. - x :: real :> at_bot" |
|
983 |
unfolding filterlim_at_bot eventually_at_top_dense |
|
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
984 |
by (metis leI less_minus_iff order_less_asym) |
50323 | 985 |
|
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
986 |
lemma filterlim_uminus_at_top: "(LIM x F. f x :> at_top) \<longleftrightarrow> (LIM x F. - (f x) :: real :> at_bot)" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
987 |
using filterlim_compose[OF filterlim_uminus_at_bot_at_top, of f F] |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
988 |
using filterlim_compose[OF filterlim_uminus_at_top_at_bot, of "\<lambda>x. - f x" F] |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
989 |
by auto |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
990 |
|
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
991 |
lemma filterlim_uminus_at_bot: "(LIM x F. f x :> at_bot) \<longleftrightarrow> (LIM x F. - (f x) :: real :> at_top)" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
992 |
unfolding filterlim_uminus_at_top by simp |
50323 | 993 |
|
50347 | 994 |
lemma filterlim_inverse_at_top_right: "LIM x at_right (0::real). inverse x :> at_top" |
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
995 |
unfolding filterlim_at_top_gt[where c=0] eventually_at_filter |
50347 | 996 |
proof safe |
997 |
fix Z :: real assume [arith]: "0 < Z" |
|
998 |
then have "eventually (\<lambda>x. x < inverse Z) (nhds 0)" |
|
999 |
by (auto simp add: eventually_nhds_metric dist_real_def intro!: exI[of _ "\<bar>inverse Z\<bar>"]) |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1000 |
then show "eventually (\<lambda>x. x \<noteq> 0 \<longrightarrow> x \<in> {0<..} \<longrightarrow> Z \<le> inverse x) (nhds 0)" |
50347 | 1001 |
by (auto elim!: eventually_elim1 simp: inverse_eq_divide field_simps) |
1002 |
qed |
|
1003 |
||
1004 |
lemma filterlim_inverse_at_top: |
|
1005 |
"(f ---> (0 :: real)) F \<Longrightarrow> eventually (\<lambda>x. 0 < f x) F \<Longrightarrow> LIM x F. inverse (f x) :> at_top" |
|
1006 |
by (intro filterlim_compose[OF filterlim_inverse_at_top_right]) |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1007 |
(simp add: filterlim_def eventually_filtermap eventually_elim1 at_within_def le_principal) |
50347 | 1008 |
|
1009 |
lemma filterlim_inverse_at_bot_neg: |
|
1010 |
"LIM x (at_left (0::real)). inverse x :> at_bot" |
|
1011 |
by (simp add: filterlim_inverse_at_top_right filterlim_uminus_at_bot filterlim_at_left_to_right) |
|
1012 |
||
1013 |
lemma filterlim_inverse_at_bot: |
|
1014 |
"(f ---> (0 :: real)) F \<Longrightarrow> eventually (\<lambda>x. f x < 0) F \<Longrightarrow> LIM x F. inverse (f x) :> at_bot" |
|
1015 |
unfolding filterlim_uminus_at_bot inverse_minus_eq[symmetric] |
|
1016 |
by (rule filterlim_inverse_at_top) (simp_all add: tendsto_minus_cancel_left[symmetric]) |
|
1017 |
||
50325 | 1018 |
lemma tendsto_inverse_0: |
1019 |
fixes x :: "_ \<Rightarrow> 'a\<Colon>real_normed_div_algebra" |
|
1020 |
shows "(inverse ---> (0::'a)) at_infinity" |
|
1021 |
unfolding tendsto_Zfun_iff diff_0_right Zfun_def eventually_at_infinity |
|
1022 |
proof safe |
|
1023 |
fix r :: real assume "0 < r" |
|
1024 |
show "\<exists>b. \<forall>x. b \<le> norm x \<longrightarrow> norm (inverse x :: 'a) < r" |
|
1025 |
proof (intro exI[of _ "inverse (r / 2)"] allI impI) |
|
1026 |
fix x :: 'a |
|
1027 |
from `0 < r` have "0 < inverse (r / 2)" by simp |
|
1028 |
also assume *: "inverse (r / 2) \<le> norm x" |
|
1029 |
finally show "norm (inverse x) < r" |
|
1030 |
using * `0 < r` by (subst nonzero_norm_inverse) (simp_all add: inverse_eq_divide field_simps) |
|
1031 |
qed |
|
1032 |
qed |
|
1033 |
||
50347 | 1034 |
lemma at_right_to_top: "(at_right (0::real)) = filtermap inverse at_top" |
1035 |
proof (rule antisym) |
|
1036 |
have "(inverse ---> (0::real)) at_top" |
|
1037 |
by (metis tendsto_inverse_0 filterlim_mono at_top_le_at_infinity order_refl) |
|
1038 |
then show "filtermap inverse at_top \<le> at_right (0::real)" |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1039 |
by (simp add: le_principal eventually_filtermap eventually_gt_at_top filterlim_def at_within_def) |
50347 | 1040 |
next |
1041 |
have "filtermap inverse (filtermap inverse (at_right (0::real))) \<le> filtermap inverse at_top" |
|
1042 |
using filterlim_inverse_at_top_right unfolding filterlim_def by (rule filtermap_mono) |
|
1043 |
then show "at_right (0::real) \<le> filtermap inverse at_top" |
|
1044 |
by (simp add: filtermap_ident filtermap_filtermap) |
|
1045 |
qed |
|
1046 |
||
1047 |
lemma eventually_at_right_to_top: |
|
1048 |
"eventually P (at_right (0::real)) \<longleftrightarrow> eventually (\<lambda>x. P (inverse x)) at_top" |
|
1049 |
unfolding at_right_to_top eventually_filtermap .. |
|
1050 |
||
1051 |
lemma filterlim_at_right_to_top: |
|
1052 |
"filterlim f F (at_right (0::real)) \<longleftrightarrow> (LIM x at_top. f (inverse x) :> F)" |
|
1053 |
unfolding filterlim_def at_right_to_top filtermap_filtermap .. |
|
1054 |
||
1055 |
lemma at_top_to_right: "at_top = filtermap inverse (at_right (0::real))" |
|
1056 |
unfolding at_right_to_top filtermap_filtermap inverse_inverse_eq filtermap_ident .. |
|
1057 |
||
1058 |
lemma eventually_at_top_to_right: |
|
1059 |
"eventually P at_top \<longleftrightarrow> eventually (\<lambda>x. P (inverse x)) (at_right (0::real))" |
|
1060 |
unfolding at_top_to_right eventually_filtermap .. |
|
1061 |
||
1062 |
lemma filterlim_at_top_to_right: |
|
1063 |
"filterlim f F at_top \<longleftrightarrow> (LIM x (at_right (0::real)). f (inverse x) :> F)" |
|
1064 |
unfolding filterlim_def at_top_to_right filtermap_filtermap .. |
|
1065 |
||
50325 | 1066 |
lemma filterlim_inverse_at_infinity: |
1067 |
fixes x :: "_ \<Rightarrow> 'a\<Colon>{real_normed_div_algebra, division_ring_inverse_zero}" |
|
1068 |
shows "filterlim inverse at_infinity (at (0::'a))" |
|
1069 |
unfolding filterlim_at_infinity[OF order_refl] |
|
1070 |
proof safe |
|
1071 |
fix r :: real assume "0 < r" |
|
1072 |
then show "eventually (\<lambda>x::'a. r \<le> norm (inverse x)) (at 0)" |
|
1073 |
unfolding eventually_at norm_inverse |
|
1074 |
by (intro exI[of _ "inverse r"]) |
|
1075 |
(auto simp: norm_conv_dist[symmetric] field_simps inverse_eq_divide) |
|
1076 |
qed |
|
1077 |
||
1078 |
lemma filterlim_inverse_at_iff: |
|
1079 |
fixes g :: "'a \<Rightarrow> 'b\<Colon>{real_normed_div_algebra, division_ring_inverse_zero}" |
|
1080 |
shows "(LIM x F. inverse (g x) :> at 0) \<longleftrightarrow> (LIM x F. g x :> at_infinity)" |
|
1081 |
unfolding filterlim_def filtermap_filtermap[symmetric] |
|
1082 |
proof |
|
1083 |
assume "filtermap g F \<le> at_infinity" |
|
1084 |
then have "filtermap inverse (filtermap g F) \<le> filtermap inverse at_infinity" |
|
1085 |
by (rule filtermap_mono) |
|
1086 |
also have "\<dots> \<le> at 0" |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1087 |
using tendsto_inverse_0[where 'a='b] |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1088 |
by (auto intro!: exI[of _ 1] |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1089 |
simp: le_principal eventually_filtermap filterlim_def at_within_def eventually_at_infinity) |
50325 | 1090 |
finally show "filtermap inverse (filtermap g F) \<le> at 0" . |
1091 |
next |
|
1092 |
assume "filtermap inverse (filtermap g F) \<le> at 0" |
|
1093 |
then have "filtermap inverse (filtermap inverse (filtermap g F)) \<le> filtermap inverse (at 0)" |
|
1094 |
by (rule filtermap_mono) |
|
1095 |
with filterlim_inverse_at_infinity show "filtermap g F \<le> at_infinity" |
|
1096 |
by (auto intro: order_trans simp: filterlim_def filtermap_filtermap) |
|
1097 |
qed |
|
1098 |
||
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1099 |
lemma tendsto_inverse_0_at_top: "LIM x F. f x :> at_top \<Longrightarrow> ((\<lambda>x. inverse (f x) :: real) ---> 0) F" |
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1100 |
by (metis filterlim_at filterlim_mono[OF _ at_top_le_at_infinity order_refl] filterlim_inverse_at_iff) |
50419 | 1101 |
|
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1102 |
text {* |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1103 |
|
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1104 |
We only show rules for multiplication and addition when the functions are either against a real |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1105 |
value or against infinity. Further rules are easy to derive by using @{thm filterlim_uminus_at_top}. |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1106 |
|
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1107 |
*} |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1108 |
|
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1109 |
lemma filterlim_tendsto_pos_mult_at_top: |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1110 |
assumes f: "(f ---> c) F" and c: "0 < c" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1111 |
assumes g: "LIM x F. g x :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1112 |
shows "LIM x F. (f x * g x :: real) :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1113 |
unfolding filterlim_at_top_gt[where c=0] |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1114 |
proof safe |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1115 |
fix Z :: real assume "0 < Z" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1116 |
from f `0 < c` have "eventually (\<lambda>x. c / 2 < f x) F" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1117 |
by (auto dest!: tendstoD[where e="c / 2"] elim!: eventually_elim1 |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1118 |
simp: dist_real_def abs_real_def split: split_if_asm) |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1119 |
moreover from g have "eventually (\<lambda>x. (Z / c * 2) \<le> g x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1120 |
unfolding filterlim_at_top by auto |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1121 |
ultimately show "eventually (\<lambda>x. Z \<le> f x * g x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1122 |
proof eventually_elim |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1123 |
fix x assume "c / 2 < f x" "Z / c * 2 \<le> g x" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1124 |
with `0 < Z` `0 < c` have "c / 2 * (Z / c * 2) \<le> f x * g x" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1125 |
by (intro mult_mono) (auto simp: zero_le_divide_iff) |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1126 |
with `0 < c` show "Z \<le> f x * g x" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1127 |
by simp |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1128 |
qed |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1129 |
qed |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1130 |
|
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1131 |
lemma filterlim_at_top_mult_at_top: |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1132 |
assumes f: "LIM x F. f x :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1133 |
assumes g: "LIM x F. g x :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1134 |
shows "LIM x F. (f x * g x :: real) :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1135 |
unfolding filterlim_at_top_gt[where c=0] |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1136 |
proof safe |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1137 |
fix Z :: real assume "0 < Z" |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1138 |
from f have "eventually (\<lambda>x. 1 \<le> f x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1139 |
unfolding filterlim_at_top by auto |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1140 |
moreover from g have "eventually (\<lambda>x. Z \<le> g x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1141 |
unfolding filterlim_at_top by auto |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1142 |
ultimately show "eventually (\<lambda>x. Z \<le> f x * g x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1143 |
proof eventually_elim |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1144 |
fix x assume "1 \<le> f x" "Z \<le> g x" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1145 |
with `0 < Z` have "1 * Z \<le> f x * g x" |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1146 |
by (intro mult_mono) (auto simp: zero_le_divide_iff) |
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1147 |
then show "Z \<le> f x * g x" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1148 |
by simp |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1149 |
qed |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1150 |
qed |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1151 |
|
50419 | 1152 |
lemma filterlim_tendsto_pos_mult_at_bot: |
1153 |
assumes "(f ---> c) F" "0 < (c::real)" "filterlim g at_bot F" |
|
1154 |
shows "LIM x F. f x * g x :> at_bot" |
|
1155 |
using filterlim_tendsto_pos_mult_at_top[OF assms(1,2), of "\<lambda>x. - g x"] assms(3) |
|
1156 |
unfolding filterlim_uminus_at_bot by simp |
|
1157 |
||
56330 | 1158 |
lemma filterlim_pow_at_top: |
1159 |
fixes f :: "real \<Rightarrow> real" |
|
1160 |
assumes "0 < n" and f: "LIM x F. f x :> at_top" |
|
1161 |
shows "LIM x F. (f x)^n :: real :> at_top" |
|
1162 |
using `0 < n` proof (induct n) |
|
1163 |
case (Suc n) with f show ?case |
|
1164 |
by (cases "n = 0") (auto intro!: filterlim_at_top_mult_at_top) |
|
1165 |
qed simp |
|
1166 |
||
1167 |
lemma filterlim_pow_at_bot_even: |
|
1168 |
fixes f :: "real \<Rightarrow> real" |
|
1169 |
shows "0 < n \<Longrightarrow> LIM x F. f x :> at_bot \<Longrightarrow> even n \<Longrightarrow> LIM x F. (f x)^n :> at_top" |
|
1170 |
using filterlim_pow_at_top[of n "\<lambda>x. - f x" F] by (simp add: filterlim_uminus_at_top) |
|
1171 |
||
1172 |
lemma filterlim_pow_at_bot_odd: |
|
1173 |
fixes f :: "real \<Rightarrow> real" |
|
1174 |
shows "0 < n \<Longrightarrow> LIM x F. f x :> at_bot \<Longrightarrow> odd n \<Longrightarrow> LIM x F. (f x)^n :> at_bot" |
|
1175 |
using filterlim_pow_at_top[of n "\<lambda>x. - f x" F] by (simp add: filterlim_uminus_at_bot) |
|
1176 |
||
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1177 |
lemma filterlim_tendsto_add_at_top: |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1178 |
assumes f: "(f ---> c) F" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1179 |
assumes g: "LIM x F. g x :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1180 |
shows "LIM x F. (f x + g x :: real) :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1181 |
unfolding filterlim_at_top_gt[where c=0] |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1182 |
proof safe |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1183 |
fix Z :: real assume "0 < Z" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1184 |
from f have "eventually (\<lambda>x. c - 1 < f x) F" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1185 |
by (auto dest!: tendstoD[where e=1] elim!: eventually_elim1 simp: dist_real_def) |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1186 |
moreover from g have "eventually (\<lambda>x. Z - (c - 1) \<le> g x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1187 |
unfolding filterlim_at_top by auto |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1188 |
ultimately show "eventually (\<lambda>x. Z \<le> f x + g x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1189 |
by eventually_elim simp |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1190 |
qed |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1191 |
|
50347 | 1192 |
lemma LIM_at_top_divide: |
1193 |
fixes f g :: "'a \<Rightarrow> real" |
|
1194 |
assumes f: "(f ---> a) F" "0 < a" |
|
1195 |
assumes g: "(g ---> 0) F" "eventually (\<lambda>x. 0 < g x) F" |
|
1196 |
shows "LIM x F. f x / g x :> at_top" |
|
1197 |
unfolding divide_inverse |
|
1198 |
by (rule filterlim_tendsto_pos_mult_at_top[OF f]) (rule filterlim_inverse_at_top[OF g]) |
|
1199 |
||
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1200 |
lemma filterlim_at_top_add_at_top: |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1201 |
assumes f: "LIM x F. f x :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1202 |
assumes g: "LIM x F. g x :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1203 |
shows "LIM x F. (f x + g x :: real) :> at_top" |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1204 |
unfolding filterlim_at_top_gt[where c=0] |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1205 |
proof safe |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1206 |
fix Z :: real assume "0 < Z" |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1207 |
from f have "eventually (\<lambda>x. 0 \<le> f x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1208 |
unfolding filterlim_at_top by auto |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1209 |
moreover from g have "eventually (\<lambda>x. Z \<le> g x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1210 |
unfolding filterlim_at_top by auto |
50346
a75c6429c3c3
add filterlim rules for eventually monotone bijective functions; mirror rules for at_top, at_bot; apply them to prove convergence of arctan at infinity and tan at pi/2
hoelzl
parents:
50331
diff
changeset
|
1211 |
ultimately show "eventually (\<lambda>x. Z \<le> f x + g x) F" |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1212 |
by eventually_elim simp |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1213 |
qed |
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1214 |
|
50331 | 1215 |
lemma tendsto_divide_0: |
1216 |
fixes f :: "_ \<Rightarrow> 'a\<Colon>{real_normed_div_algebra, division_ring_inverse_zero}" |
|
1217 |
assumes f: "(f ---> c) F" |
|
1218 |
assumes g: "LIM x F. g x :> at_infinity" |
|
1219 |
shows "((\<lambda>x. f x / g x) ---> 0) F" |
|
1220 |
using tendsto_mult[OF f filterlim_compose[OF tendsto_inverse_0 g]] by (simp add: divide_inverse) |
|
1221 |
||
1222 |
lemma linear_plus_1_le_power: |
|
1223 |
fixes x :: real |
|
1224 |
assumes x: "0 \<le> x" |
|
1225 |
shows "real n * x + 1 \<le> (x + 1) ^ n" |
|
1226 |
proof (induct n) |
|
1227 |
case (Suc n) |
|
1228 |
have "real (Suc n) * x + 1 \<le> (x + 1) * (real n * x + 1)" |
|
56536 | 1229 |
by (simp add: field_simps real_of_nat_Suc x) |
50331 | 1230 |
also have "\<dots> \<le> (x + 1)^Suc n" |
1231 |
using Suc x by (simp add: mult_left_mono) |
|
1232 |
finally show ?case . |
|
1233 |
qed simp |
|
1234 |
||
1235 |
lemma filterlim_realpow_sequentially_gt1: |
|
1236 |
fixes x :: "'a :: real_normed_div_algebra" |
|
1237 |
assumes x[arith]: "1 < norm x" |
|
1238 |
shows "LIM n sequentially. x ^ n :> at_infinity" |
|
1239 |
proof (intro filterlim_at_infinity[THEN iffD2] allI impI) |
|
1240 |
fix y :: real assume "0 < y" |
|
1241 |
have "0 < norm x - 1" by simp |
|
1242 |
then obtain N::nat where "y < real N * (norm x - 1)" by (blast dest: reals_Archimedean3) |
|
1243 |
also have "\<dots> \<le> real N * (norm x - 1) + 1" by simp |
|
1244 |
also have "\<dots> \<le> (norm x - 1 + 1) ^ N" by (rule linear_plus_1_le_power) simp |
|
1245 |
also have "\<dots> = norm x ^ N" by simp |
|
1246 |
finally have "\<forall>n\<ge>N. y \<le> norm x ^ n" |
|
1247 |
by (metis order_less_le_trans power_increasing order_less_imp_le x) |
|
1248 |
then show "eventually (\<lambda>n. y \<le> norm (x ^ n)) sequentially" |
|
1249 |
unfolding eventually_sequentially |
|
1250 |
by (auto simp: norm_power) |
|
1251 |
qed simp |
|
1252 |
||
51471 | 1253 |
|
51526 | 1254 |
subsection {* Limits of Sequences *} |
1255 |
||
1256 |
lemma [trans]: "X=Y ==> Y ----> z ==> X ----> z" |
|
1257 |
by simp |
|
1258 |
||
1259 |
lemma LIMSEQ_iff: |
|
1260 |
fixes L :: "'a::real_normed_vector" |
|
1261 |
shows "(X ----> L) = (\<forall>r>0. \<exists>no. \<forall>n \<ge> no. norm (X n - L) < r)" |
|
1262 |
unfolding LIMSEQ_def dist_norm .. |
|
1263 |
||
1264 |
lemma LIMSEQ_I: |
|
1265 |
fixes L :: "'a::real_normed_vector" |
|
1266 |
shows "(\<And>r. 0 < r \<Longrightarrow> \<exists>no. \<forall>n\<ge>no. norm (X n - L) < r) \<Longrightarrow> X ----> L" |
|
1267 |
by (simp add: LIMSEQ_iff) |
|
1268 |
||
1269 |
lemma LIMSEQ_D: |
|
1270 |
fixes L :: "'a::real_normed_vector" |
|
1271 |
shows "\<lbrakk>X ----> L; 0 < r\<rbrakk> \<Longrightarrow> \<exists>no. \<forall>n\<ge>no. norm (X n - L) < r" |
|
1272 |
by (simp add: LIMSEQ_iff) |
|
1273 |
||
1274 |
lemma LIMSEQ_linear: "\<lbrakk> X ----> x ; l > 0 \<rbrakk> \<Longrightarrow> (\<lambda> n. X (n * l)) ----> x" |
|
1275 |
unfolding tendsto_def eventually_sequentially |
|
57512
cc97b347b301
reduced name variants for assoc and commute on plus and mult
haftmann
parents:
57447
diff
changeset
|
1276 |
by (metis div_le_dividend div_mult_self1_is_m le_trans mult.commute) |
51526 | 1277 |
|
1278 |
lemma Bseq_inverse_lemma: |
|
1279 |
fixes x :: "'a::real_normed_div_algebra" |
|
1280 |
shows "\<lbrakk>r \<le> norm x; 0 < r\<rbrakk> \<Longrightarrow> norm (inverse x) \<le> inverse r" |
|
1281 |
apply (subst nonzero_norm_inverse, clarsimp) |
|
1282 |
apply (erule (1) le_imp_inverse_le) |
|
1283 |
done |
|
1284 |
||
1285 |
lemma Bseq_inverse: |
|
1286 |
fixes a :: "'a::real_normed_div_algebra" |
|
1287 |
shows "\<lbrakk>X ----> a; a \<noteq> 0\<rbrakk> \<Longrightarrow> Bseq (\<lambda>n. inverse (X n))" |
|
1288 |
by (rule Bfun_inverse) |
|
1289 |
||
1290 |
lemma LIMSEQ_diff_approach_zero: |
|
1291 |
fixes L :: "'a::real_normed_vector" |
|
1292 |
shows "g ----> L ==> (%x. f x - g x) ----> 0 ==> f ----> L" |
|
1293 |
by (drule (1) tendsto_add, simp) |
|
1294 |
||
1295 |
lemma LIMSEQ_diff_approach_zero2: |
|
1296 |
fixes L :: "'a::real_normed_vector" |
|
1297 |
shows "f ----> L ==> (%x. f x - g x) ----> 0 ==> g ----> L" |
|
1298 |
by (drule (1) tendsto_diff, simp) |
|
1299 |
||
1300 |
text{*An unbounded sequence's inverse tends to 0*} |
|
1301 |
||
1302 |
lemma LIMSEQ_inverse_zero: |
|
1303 |
"\<forall>r::real. \<exists>N. \<forall>n\<ge>N. r < X n \<Longrightarrow> (\<lambda>n. inverse (X n)) ----> 0" |
|
1304 |
apply (rule filterlim_compose[OF tendsto_inverse_0]) |
|
1305 |
apply (simp add: filterlim_at_infinity[OF order_refl] eventually_sequentially) |
|
1306 |
apply (metis abs_le_D1 linorder_le_cases linorder_not_le) |
|
1307 |
done |
|
1308 |
||
1309 |
text{*The sequence @{term "1/n"} tends to 0 as @{term n} tends to infinity*} |
|
1310 |
||
1311 |
lemma LIMSEQ_inverse_real_of_nat: "(%n. inverse(real(Suc n))) ----> 0" |
|
1312 |
by (metis filterlim_compose tendsto_inverse_0 filterlim_mono order_refl filterlim_Suc |
|
1313 |
filterlim_compose[OF filterlim_real_sequentially] at_top_le_at_infinity) |
|
1314 |
||
1315 |
text{*The sequence @{term "r + 1/n"} tends to @{term r} as @{term n} tends to |
|
1316 |
infinity is now easily proved*} |
|
1317 |
||
1318 |
lemma LIMSEQ_inverse_real_of_nat_add: |
|
1319 |
"(%n. r + inverse(real(Suc n))) ----> r" |
|
1320 |
using tendsto_add [OF tendsto_const LIMSEQ_inverse_real_of_nat] by auto |
|
1321 |
||
1322 |
lemma LIMSEQ_inverse_real_of_nat_add_minus: |
|
1323 |
"(%n. r + -inverse(real(Suc n))) ----> r" |
|
1324 |
using tendsto_add [OF tendsto_const tendsto_minus [OF LIMSEQ_inverse_real_of_nat]] |
|
1325 |
by auto |
|
1326 |
||
1327 |
lemma LIMSEQ_inverse_real_of_nat_add_minus_mult: |
|
1328 |
"(%n. r*( 1 + -inverse(real(Suc n)))) ----> r" |
|
1329 |
using tendsto_mult [OF tendsto_const LIMSEQ_inverse_real_of_nat_add_minus [of 1]] |
|
1330 |
by auto |
|
1331 |
||
1332 |
subsection {* Convergence on sequences *} |
|
1333 |
||
1334 |
lemma convergent_add: |
|
1335 |
fixes X Y :: "nat \<Rightarrow> 'a::real_normed_vector" |
|
1336 |
assumes "convergent (\<lambda>n. X n)" |
|
1337 |
assumes "convergent (\<lambda>n. Y n)" |
|
1338 |
shows "convergent (\<lambda>n. X n + Y n)" |
|
1339 |
using assms unfolding convergent_def by (fast intro: tendsto_add) |
|
1340 |
||
1341 |
lemma convergent_setsum: |
|
1342 |
fixes X :: "'a \<Rightarrow> nat \<Rightarrow> 'b::real_normed_vector" |
|
1343 |
assumes "\<And>i. i \<in> A \<Longrightarrow> convergent (\<lambda>n. X i n)" |
|
1344 |
shows "convergent (\<lambda>n. \<Sum>i\<in>A. X i n)" |
|
1345 |
proof (cases "finite A") |
|
1346 |
case True from this and assms show ?thesis |
|
1347 |
by (induct A set: finite) (simp_all add: convergent_const convergent_add) |
|
1348 |
qed (simp add: convergent_const) |
|
1349 |
||
1350 |
lemma (in bounded_linear) convergent: |
|
1351 |
assumes "convergent (\<lambda>n. X n)" |
|
1352 |
shows "convergent (\<lambda>n. f (X n))" |
|
1353 |
using assms unfolding convergent_def by (fast intro: tendsto) |
|
1354 |
||
1355 |
lemma (in bounded_bilinear) convergent: |
|
1356 |
assumes "convergent (\<lambda>n. X n)" and "convergent (\<lambda>n. Y n)" |
|
1357 |
shows "convergent (\<lambda>n. X n ** Y n)" |
|
1358 |
using assms unfolding convergent_def by (fast intro: tendsto) |
|
1359 |
||
1360 |
lemma convergent_minus_iff: |
|
1361 |
fixes X :: "nat \<Rightarrow> 'a::real_normed_vector" |
|
1362 |
shows "convergent X \<longleftrightarrow> convergent (\<lambda>n. - X n)" |
|
1363 |
apply (simp add: convergent_def) |
|
1364 |
apply (auto dest: tendsto_minus) |
|
1365 |
apply (drule tendsto_minus, auto) |
|
1366 |
done |
|
1367 |
||
1368 |
||
1369 |
text {* A monotone sequence converges to its least upper bound. *} |
|
1370 |
||
54263
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1371 |
lemma LIMSEQ_incseq_SUP: |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1372 |
fixes X :: "nat \<Rightarrow> 'a::{conditionally_complete_linorder, linorder_topology}" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1373 |
assumes u: "bdd_above (range X)" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1374 |
assumes X: "incseq X" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1375 |
shows "X ----> (SUP i. X i)" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1376 |
by (rule order_tendstoI) |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1377 |
(auto simp: eventually_sequentially u less_cSUP_iff intro: X[THEN incseqD] less_le_trans cSUP_lessD[OF u]) |
51526 | 1378 |
|
54263
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1379 |
lemma LIMSEQ_decseq_INF: |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1380 |
fixes X :: "nat \<Rightarrow> 'a::{conditionally_complete_linorder, linorder_topology}" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1381 |
assumes u: "bdd_below (range X)" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1382 |
assumes X: "decseq X" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1383 |
shows "X ----> (INF i. X i)" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1384 |
by (rule order_tendstoI) |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1385 |
(auto simp: eventually_sequentially u cINF_less_iff intro: X[THEN decseqD] le_less_trans less_cINF_D[OF u]) |
51526 | 1386 |
|
1387 |
text{*Main monotonicity theorem*} |
|
1388 |
||
1389 |
lemma Bseq_monoseq_convergent: "Bseq X \<Longrightarrow> monoseq X \<Longrightarrow> convergent (X::nat\<Rightarrow>real)" |
|
54263
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1390 |
by (auto simp: monoseq_iff convergent_def intro: LIMSEQ_decseq_INF LIMSEQ_incseq_SUP dest: Bseq_bdd_above Bseq_bdd_below) |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1391 |
|
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1392 |
lemma Bseq_mono_convergent: "Bseq X \<Longrightarrow> (\<forall>m n. m \<le> n \<longrightarrow> X m \<le> X n) \<Longrightarrow> convergent (X::nat\<Rightarrow>real)" |
c4159fe6fa46
move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices)
hoelzl
parents:
54230
diff
changeset
|
1393 |
by (auto intro!: Bseq_monoseq_convergent incseq_imp_monoseq simp: incseq_def) |
51526 | 1394 |
|
1395 |
lemma Cauchy_iff: |
|
1396 |
fixes X :: "nat \<Rightarrow> 'a::real_normed_vector" |
|
1397 |
shows "Cauchy X \<longleftrightarrow> (\<forall>e>0. \<exists>M. \<forall>m\<ge>M. \<forall>n\<ge>M. norm (X m - X n) < e)" |
|
1398 |
unfolding Cauchy_def dist_norm .. |
|
1399 |
||
1400 |
lemma CauchyI: |
|
1401 |
fixes X :: "nat \<Rightarrow> 'a::real_normed_vector" |
|
1402 |
shows "(\<And>e. 0 < e \<Longrightarrow> \<exists>M. \<forall>m\<ge>M. \<forall>n\<ge>M. norm (X m - X n) < e) \<Longrightarrow> Cauchy X" |
|
1403 |
by (simp add: Cauchy_iff) |
|
1404 |
||
1405 |
lemma CauchyD: |
|
1406 |
fixes X :: "nat \<Rightarrow> 'a::real_normed_vector" |
|
1407 |
shows "\<lbrakk>Cauchy X; 0 < e\<rbrakk> \<Longrightarrow> \<exists>M. \<forall>m\<ge>M. \<forall>n\<ge>M. norm (X m - X n) < e" |
|
1408 |
by (simp add: Cauchy_iff) |
|
1409 |
||
1410 |
lemma incseq_convergent: |
|
1411 |
fixes X :: "nat \<Rightarrow> real" |
|
1412 |
assumes "incseq X" and "\<forall>i. X i \<le> B" |
|
1413 |
obtains L where "X ----> L" "\<forall>i. X i \<le> L" |
|
1414 |
proof atomize_elim |
|
1415 |
from incseq_bounded[OF assms] `incseq X` Bseq_monoseq_convergent[of X] |
|
1416 |
obtain L where "X ----> L" |
|
1417 |
by (auto simp: convergent_def monoseq_def incseq_def) |
|
1418 |
with `incseq X` show "\<exists>L. X ----> L \<and> (\<forall>i. X i \<le> L)" |
|
1419 |
by (auto intro!: exI[of _ L] incseq_le) |
|
1420 |
qed |
|
1421 |
||
1422 |
lemma decseq_convergent: |
|
1423 |
fixes X :: "nat \<Rightarrow> real" |
|
1424 |
assumes "decseq X" and "\<forall>i. B \<le> X i" |
|
1425 |
obtains L where "X ----> L" "\<forall>i. L \<le> X i" |
|
1426 |
proof atomize_elim |
|
1427 |
from decseq_bounded[OF assms] `decseq X` Bseq_monoseq_convergent[of X] |
|
1428 |
obtain L where "X ----> L" |
|
1429 |
by (auto simp: convergent_def monoseq_def decseq_def) |
|
1430 |
with `decseq X` show "\<exists>L. X ----> L \<and> (\<forall>i. L \<le> X i)" |
|
1431 |
by (auto intro!: exI[of _ L] decseq_le) |
|
1432 |
qed |
|
1433 |
||
1434 |
subsubsection {* Cauchy Sequences are Bounded *} |
|
1435 |
||
1436 |
text{*A Cauchy sequence is bounded -- this is the standard |
|
1437 |
proof mechanization rather than the nonstandard proof*} |
|
1438 |
||
1439 |
lemma lemmaCauchy: "\<forall>n \<ge> M. norm (X M - X n) < (1::real) |
|
1440 |
==> \<forall>n \<ge> M. norm (X n :: 'a::real_normed_vector) < 1 + norm (X M)" |
|
1441 |
apply (clarify, drule spec, drule (1) mp) |
|
1442 |
apply (simp only: norm_minus_commute) |
|
1443 |
apply (drule order_le_less_trans [OF norm_triangle_ineq2]) |
|
1444 |
apply simp |
|
1445 |
done |
|
1446 |
||
1447 |
subsection {* Power Sequences *} |
|
1448 |
||
1449 |
text{*The sequence @{term "x^n"} tends to 0 if @{term "0\<le>x"} and @{term |
|
1450 |
"x<1"}. Proof will use (NS) Cauchy equivalence for convergence and |
|
1451 |
also fact that bounded and monotonic sequence converges.*} |
|
1452 |
||
1453 |
lemma Bseq_realpow: "[| 0 \<le> (x::real); x \<le> 1 |] ==> Bseq (%n. x ^ n)" |
|
1454 |
apply (simp add: Bseq_def) |
|
1455 |
apply (rule_tac x = 1 in exI) |
|
1456 |
apply (simp add: power_abs) |
|
1457 |
apply (auto dest: power_mono) |
|
1458 |
done |
|
1459 |
||
1460 |
lemma monoseq_realpow: fixes x :: real shows "[| 0 \<le> x; x \<le> 1 |] ==> monoseq (%n. x ^ n)" |
|
1461 |
apply (clarify intro!: mono_SucI2) |
|
1462 |
apply (cut_tac n = n and N = "Suc n" and a = x in power_decreasing, auto) |
|
1463 |
done |
|
1464 |
||
1465 |
lemma convergent_realpow: |
|
1466 |
"[| 0 \<le> (x::real); x \<le> 1 |] ==> convergent (%n. x ^ n)" |
|
1467 |
by (blast intro!: Bseq_monoseq_convergent Bseq_realpow monoseq_realpow) |
|
1468 |
||
1469 |
lemma LIMSEQ_inverse_realpow_zero: "1 < (x::real) \<Longrightarrow> (\<lambda>n. inverse (x ^ n)) ----> 0" |
|
1470 |
by (rule filterlim_compose[OF tendsto_inverse_0 filterlim_realpow_sequentially_gt1]) simp |
|
1471 |
||
1472 |
lemma LIMSEQ_realpow_zero: |
|
1473 |
"\<lbrakk>0 \<le> (x::real); x < 1\<rbrakk> \<Longrightarrow> (\<lambda>n. x ^ n) ----> 0" |
|
1474 |
proof cases |
|
1475 |
assume "0 \<le> x" and "x \<noteq> 0" |
|
1476 |
hence x0: "0 < x" by simp |
|
1477 |
assume x1: "x < 1" |
|
1478 |
from x0 x1 have "1 < inverse x" |
|
1479 |
by (rule one_less_inverse) |
|
1480 |
hence "(\<lambda>n. inverse (inverse x ^ n)) ----> 0" |
|
1481 |
by (rule LIMSEQ_inverse_realpow_zero) |
|
1482 |
thus ?thesis by (simp add: power_inverse) |
|
1483 |
qed (rule LIMSEQ_imp_Suc, simp add: tendsto_const) |
|
1484 |
||
1485 |
lemma LIMSEQ_power_zero: |
|
1486 |
fixes x :: "'a::{real_normed_algebra_1}" |
|
1487 |
shows "norm x < 1 \<Longrightarrow> (\<lambda>n. x ^ n) ----> 0" |
|
1488 |
apply (drule LIMSEQ_realpow_zero [OF norm_ge_zero]) |
|
1489 |
apply (simp only: tendsto_Zfun_iff, erule Zfun_le) |
|
1490 |
apply (simp add: power_abs norm_power_ineq) |
|
1491 |
done |
|
1492 |
||
1493 |
lemma LIMSEQ_divide_realpow_zero: "1 < x \<Longrightarrow> (\<lambda>n. a / (x ^ n) :: real) ----> 0" |
|
1494 |
by (rule tendsto_divide_0 [OF tendsto_const filterlim_realpow_sequentially_gt1]) simp |
|
1495 |
||
1496 |
text{*Limit of @{term "c^n"} for @{term"\<bar>c\<bar> < 1"}*} |
|
1497 |
||
1498 |
lemma LIMSEQ_rabs_realpow_zero: "\<bar>c\<bar> < 1 \<Longrightarrow> (\<lambda>n. \<bar>c\<bar> ^ n :: real) ----> 0" |
|
1499 |
by (rule LIMSEQ_realpow_zero [OF abs_ge_zero]) |
|
1500 |
||
1501 |
lemma LIMSEQ_rabs_realpow_zero2: "\<bar>c\<bar> < 1 \<Longrightarrow> (\<lambda>n. c ^ n :: real) ----> 0" |
|
1502 |
by (rule LIMSEQ_power_zero) simp |
|
1503 |
||
1504 |
||
1505 |
subsection {* Limits of Functions *} |
|
1506 |
||
1507 |
lemma LIM_eq: |
|
1508 |
fixes a :: "'a::real_normed_vector" and L :: "'b::real_normed_vector" |
|
1509 |
shows "f -- a --> L = |
|
1510 |
(\<forall>r>0.\<exists>s>0.\<forall>x. x \<noteq> a & norm (x-a) < s --> norm (f x - L) < r)" |
|
1511 |
by (simp add: LIM_def dist_norm) |
|
1512 |
||
1513 |
lemma LIM_I: |
|
1514 |
fixes a :: "'a::real_normed_vector" and L :: "'b::real_normed_vector" |
|
1515 |
shows "(!!r. 0<r ==> \<exists>s>0.\<forall>x. x \<noteq> a & norm (x-a) < s --> norm (f x - L) < r) |
|
1516 |
==> f -- a --> L" |
|
1517 |
by (simp add: LIM_eq) |
|
1518 |
||
1519 |
lemma LIM_D: |
|
1520 |
fixes a :: "'a::real_normed_vector" and L :: "'b::real_normed_vector" |
|
1521 |
shows "[| f -- a --> L; 0<r |] |
|
1522 |
==> \<exists>s>0.\<forall>x. x \<noteq> a & norm (x-a) < s --> norm (f x - L) < r" |
|
1523 |
by (simp add: LIM_eq) |
|
1524 |
||
1525 |
lemma LIM_offset: |
|
1526 |
fixes a :: "'a::real_normed_vector" |
|
1527 |
shows "f -- a --> L \<Longrightarrow> (\<lambda>x. f (x + k)) -- a - k --> L" |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1528 |
unfolding filtermap_at_shift[symmetric, of a k] filterlim_def filtermap_filtermap by simp |
51526 | 1529 |
|
1530 |
lemma LIM_offset_zero: |
|
1531 |
fixes a :: "'a::real_normed_vector" |
|
1532 |
shows "f -- a --> L \<Longrightarrow> (\<lambda>h. f (a + h)) -- 0 --> L" |
|
57512
cc97b347b301
reduced name variants for assoc and commute on plus and mult
haftmann
parents:
57447
diff
changeset
|
1533 |
by (drule_tac k="a" in LIM_offset, simp add: add.commute) |
51526 | 1534 |
|
1535 |
lemma LIM_offset_zero_cancel: |
|
1536 |
fixes a :: "'a::real_normed_vector" |
|
1537 |
shows "(\<lambda>h. f (a + h)) -- 0 --> L \<Longrightarrow> f -- a --> L" |
|
1538 |
by (drule_tac k="- a" in LIM_offset, simp) |
|
1539 |
||
51642
400ec5ae7f8f
move FrechetDeriv from the Library to HOL/Deriv; base DERIV on FDERIV and both derivatives allow a restricted support set; FDERIV is now an abbreviation of has_derivative
hoelzl
parents:
51641
diff
changeset
|
1540 |
lemma LIM_offset_zero_iff: |
400ec5ae7f8f
move FrechetDeriv from the Library to HOL/Deriv; base DERIV on FDERIV and both derivatives allow a restricted support set; FDERIV is now an abbreviation of has_derivative
hoelzl
parents:
51641
diff
changeset
|
1541 |
fixes f :: "'a :: real_normed_vector \<Rightarrow> _" |
400ec5ae7f8f
move FrechetDeriv from the Library to HOL/Deriv; base DERIV on FDERIV and both derivatives allow a restricted support set; FDERIV is now an abbreviation of has_derivative
hoelzl
parents:
51641
diff
changeset
|
1542 |
shows "f -- a --> L \<longleftrightarrow> (\<lambda>h. f (a + h)) -- 0 --> L" |
400ec5ae7f8f
move FrechetDeriv from the Library to HOL/Deriv; base DERIV on FDERIV and both derivatives allow a restricted support set; FDERIV is now an abbreviation of has_derivative
hoelzl
parents:
51641
diff
changeset
|
1543 |
using LIM_offset_zero_cancel[of f a L] LIM_offset_zero[of f L a] by auto |
400ec5ae7f8f
move FrechetDeriv from the Library to HOL/Deriv; base DERIV on FDERIV and both derivatives allow a restricted support set; FDERIV is now an abbreviation of has_derivative
hoelzl
parents:
51641
diff
changeset
|
1544 |
|
51526 | 1545 |
lemma LIM_zero: |
1546 |
fixes f :: "'a::topological_space \<Rightarrow> 'b::real_normed_vector" |
|
1547 |
shows "(f ---> l) F \<Longrightarrow> ((\<lambda>x. f x - l) ---> 0) F" |
|
1548 |
unfolding tendsto_iff dist_norm by simp |
|
1549 |
||
1550 |
lemma LIM_zero_cancel: |
|
1551 |
fixes f :: "'a::topological_space \<Rightarrow> 'b::real_normed_vector" |
|
1552 |
shows "((\<lambda>x. f x - l) ---> 0) F \<Longrightarrow> (f ---> l) F" |
|
1553 |
unfolding tendsto_iff dist_norm by simp |
|
1554 |
||
1555 |
lemma LIM_zero_iff: |
|
1556 |
fixes f :: "'a::metric_space \<Rightarrow> 'b::real_normed_vector" |
|
1557 |
shows "((\<lambda>x. f x - l) ---> 0) F = (f ---> l) F" |
|
1558 |
unfolding tendsto_iff dist_norm by simp |
|
1559 |
||
1560 |
lemma LIM_imp_LIM: |
|
1561 |
fixes f :: "'a::topological_space \<Rightarrow> 'b::real_normed_vector" |
|
1562 |
fixes g :: "'a::topological_space \<Rightarrow> 'c::real_normed_vector" |
|
1563 |
assumes f: "f -- a --> l" |
|
1564 |
assumes le: "\<And>x. x \<noteq> a \<Longrightarrow> norm (g x - m) \<le> norm (f x - l)" |
|
1565 |
shows "g -- a --> m" |
|
1566 |
by (rule metric_LIM_imp_LIM [OF f], |
|
1567 |
simp add: dist_norm le) |
|
1568 |
||
1569 |
lemma LIM_equal2: |
|
1570 |
fixes f g :: "'a::real_normed_vector \<Rightarrow> 'b::topological_space" |
|
1571 |
assumes 1: "0 < R" |
|
1572 |
assumes 2: "\<And>x. \<lbrakk>x \<noteq> a; norm (x - a) < R\<rbrakk> \<Longrightarrow> f x = g x" |
|
1573 |
shows "g -- a --> l \<Longrightarrow> f -- a --> l" |
|
1574 |
by (rule metric_LIM_equal2 [OF 1 2], simp_all add: dist_norm) |
|
1575 |
||
1576 |
lemma LIM_compose2: |
|
1577 |
fixes a :: "'a::real_normed_vector" |
|
1578 |
assumes f: "f -- a --> b" |
|
1579 |
assumes g: "g -- b --> c" |
|
1580 |
assumes inj: "\<exists>d>0. \<forall>x. x \<noteq> a \<and> norm (x - a) < d \<longrightarrow> f x \<noteq> b" |
|
1581 |
shows "(\<lambda>x. g (f x)) -- a --> c" |
|
1582 |
by (rule metric_LIM_compose2 [OF f g inj [folded dist_norm]]) |
|
1583 |
||
1584 |
lemma real_LIM_sandwich_zero: |
|
1585 |
fixes f g :: "'a::topological_space \<Rightarrow> real" |
|
1586 |
assumes f: "f -- a --> 0" |
|
1587 |
assumes 1: "\<And>x. x \<noteq> a \<Longrightarrow> 0 \<le> g x" |
|
1588 |
assumes 2: "\<And>x. x \<noteq> a \<Longrightarrow> g x \<le> f x" |
|
1589 |
shows "g -- a --> 0" |
|
1590 |
proof (rule LIM_imp_LIM [OF f]) (* FIXME: use tendsto_sandwich *) |
|
1591 |
fix x assume x: "x \<noteq> a" |
|
1592 |
have "norm (g x - 0) = g x" by (simp add: 1 x) |
|
1593 |
also have "g x \<le> f x" by (rule 2 [OF x]) |
|
1594 |
also have "f x \<le> \<bar>f x\<bar>" by (rule abs_ge_self) |
|
1595 |
also have "\<bar>f x\<bar> = norm (f x - 0)" by simp |
|
1596 |
finally show "norm (g x - 0) \<le> norm (f x - 0)" . |
|
1597 |
qed |
|
1598 |
||
1599 |
||
1600 |
subsection {* Continuity *} |
|
1601 |
||
1602 |
lemma LIM_isCont_iff: |
|
1603 |
fixes f :: "'a::real_normed_vector \<Rightarrow> 'b::topological_space" |
|
1604 |
shows "(f -- a --> f a) = ((\<lambda>h. f (a + h)) -- 0 --> f a)" |
|
1605 |
by (rule iffI [OF LIM_offset_zero LIM_offset_zero_cancel]) |
|
1606 |
||
1607 |
lemma isCont_iff: |
|
1608 |
fixes f :: "'a::real_normed_vector \<Rightarrow> 'b::topological_space" |
|
1609 |
shows "isCont f x = (\<lambda>h. f (x + h)) -- 0 --> f x" |
|
1610 |
by (simp add: isCont_def LIM_isCont_iff) |
|
1611 |
||
1612 |
lemma isCont_LIM_compose2: |
|
1613 |
fixes a :: "'a::real_normed_vector" |
|
1614 |
assumes f [unfolded isCont_def]: "isCont f a" |
|
1615 |
assumes g: "g -- f a --> l" |
|
1616 |
assumes inj: "\<exists>d>0. \<forall>x. x \<noteq> a \<and> norm (x - a) < d \<longrightarrow> f x \<noteq> f a" |
|
1617 |
shows "(\<lambda>x. g (f x)) -- a --> l" |
|
1618 |
by (rule LIM_compose2 [OF f g inj]) |
|
1619 |
||
1620 |
||
1621 |
lemma isCont_norm [simp]: |
|
1622 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
|
1623 |
shows "isCont f a \<Longrightarrow> isCont (\<lambda>x. norm (f x)) a" |
|
1624 |
by (fact continuous_norm) |
|
1625 |
||
1626 |
lemma isCont_rabs [simp]: |
|
1627 |
fixes f :: "'a::t2_space \<Rightarrow> real" |
|
1628 |
shows "isCont f a \<Longrightarrow> isCont (\<lambda>x. \<bar>f x\<bar>) a" |
|
1629 |
by (fact continuous_rabs) |
|
1630 |
||
1631 |
lemma isCont_add [simp]: |
|
1632 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
|
1633 |
shows "\<lbrakk>isCont f a; isCont g a\<rbrakk> \<Longrightarrow> isCont (\<lambda>x. f x + g x) a" |
|
1634 |
by (fact continuous_add) |
|
1635 |
||
1636 |
lemma isCont_minus [simp]: |
|
1637 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
|
1638 |
shows "isCont f a \<Longrightarrow> isCont (\<lambda>x. - f x) a" |
|
1639 |
by (fact continuous_minus) |
|
1640 |
||
1641 |
lemma isCont_diff [simp]: |
|
1642 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::real_normed_vector" |
|
1643 |
shows "\<lbrakk>isCont f a; isCont g a\<rbrakk> \<Longrightarrow> isCont (\<lambda>x. f x - g x) a" |
|
1644 |
by (fact continuous_diff) |
|
1645 |
||
1646 |
lemma isCont_mult [simp]: |
|
1647 |
fixes f g :: "'a::t2_space \<Rightarrow> 'b::real_normed_algebra" |
|
1648 |
shows "\<lbrakk>isCont f a; isCont g a\<rbrakk> \<Longrightarrow> isCont (\<lambda>x. f x * g x) a" |
|
1649 |
by (fact continuous_mult) |
|
1650 |
||
1651 |
lemma (in bounded_linear) isCont: |
|
1652 |
"isCont g a \<Longrightarrow> isCont (\<lambda>x. f (g x)) a" |
|
1653 |
by (fact continuous) |
|
1654 |
||
1655 |
lemma (in bounded_bilinear) isCont: |
|
1656 |
"\<lbrakk>isCont f a; isCont g a\<rbrakk> \<Longrightarrow> isCont (\<lambda>x. f x ** g x) a" |
|
1657 |
by (fact continuous) |
|
1658 |
||
1659 |
lemmas isCont_scaleR [simp] = |
|
1660 |
bounded_bilinear.isCont [OF bounded_bilinear_scaleR] |
|
1661 |
||
1662 |
lemmas isCont_of_real [simp] = |
|
1663 |
bounded_linear.isCont [OF bounded_linear_of_real] |
|
1664 |
||
1665 |
lemma isCont_power [simp]: |
|
1666 |
fixes f :: "'a::t2_space \<Rightarrow> 'b::{power,real_normed_algebra}" |
|
1667 |
shows "isCont f a \<Longrightarrow> isCont (\<lambda>x. f x ^ n) a" |
|
1668 |
by (fact continuous_power) |
|
1669 |
||
1670 |
lemma isCont_setsum [simp]: |
|
1671 |
fixes f :: "'a \<Rightarrow> 'b::t2_space \<Rightarrow> 'c::real_normed_vector" |
|
1672 |
shows "\<forall>i\<in>A. isCont (f i) a \<Longrightarrow> isCont (\<lambda>x. \<Sum>i\<in>A. f i x) a" |
|
1673 |
by (auto intro: continuous_setsum) |
|
1674 |
||
1675 |
subsection {* Uniform Continuity *} |
|
1676 |
||
51531
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1677 |
definition |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1678 |
isUCont :: "['a::metric_space \<Rightarrow> 'b::metric_space] \<Rightarrow> bool" where |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1679 |
"isUCont f = (\<forall>r>0. \<exists>s>0. \<forall>x y. dist x y < s \<longrightarrow> dist (f x) (f y) < r)" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1680 |
|
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1681 |
lemma isUCont_isCont: "isUCont f ==> isCont f x" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1682 |
by (simp add: isUCont_def isCont_def LIM_def, force) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1683 |
|
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1684 |
lemma isUCont_Cauchy: |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1685 |
"\<lbrakk>isUCont f; Cauchy X\<rbrakk> \<Longrightarrow> Cauchy (\<lambda>n. f (X n))" |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1686 |
unfolding isUCont_def |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1687 |
apply (rule metric_CauchyI) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1688 |
apply (drule_tac x=e in spec, safe) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1689 |
apply (drule_tac e=s in metric_CauchyD, safe) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1690 |
apply (rule_tac x=M in exI, simp) |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1691 |
done |
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1692 |
|
51526 | 1693 |
lemma (in bounded_linear) isUCont: "isUCont f" |
1694 |
unfolding isUCont_def dist_norm |
|
1695 |
proof (intro allI impI) |
|
1696 |
fix r::real assume r: "0 < r" |
|
1697 |
obtain K where K: "0 < K" and norm_le: "\<And>x. norm (f x) \<le> norm x * K" |
|
1698 |
using pos_bounded by fast |
|
1699 |
show "\<exists>s>0. \<forall>x y. norm (x - y) < s \<longrightarrow> norm (f x - f y) < r" |
|
1700 |
proof (rule exI, safe) |
|
56541 | 1701 |
from r K show "0 < r / K" by simp |
51526 | 1702 |
next |
1703 |
fix x y :: 'a |
|
1704 |
assume xy: "norm (x - y) < r / K" |
|
1705 |
have "norm (f x - f y) = norm (f (x - y))" by (simp only: diff) |
|
1706 |
also have "\<dots> \<le> norm (x - y) * K" by (rule norm_le) |
|
1707 |
also from K xy have "\<dots> < r" by (simp only: pos_less_divide_eq) |
|
1708 |
finally show "norm (f x - f y) < r" . |
|
1709 |
qed |
|
1710 |
qed |
|
1711 |
||
1712 |
lemma (in bounded_linear) Cauchy: "Cauchy X \<Longrightarrow> Cauchy (\<lambda>n. f (X n))" |
|
1713 |
by (rule isUCont [THEN isUCont_Cauchy]) |
|
1714 |
||
1715 |
lemma LIM_less_bound: |
|
1716 |
fixes f :: "real \<Rightarrow> real" |
|
1717 |
assumes ev: "b < x" "\<forall> x' \<in> { b <..< x}. 0 \<le> f x'" and "isCont f x" |
|
1718 |
shows "0 \<le> f x" |
|
1719 |
proof (rule tendsto_le_const) |
|
1720 |
show "(f ---> f x) (at_left x)" |
|
1721 |
using `isCont f x` by (simp add: filterlim_at_split isCont_def) |
|
1722 |
show "eventually (\<lambda>x. 0 \<le> f x) (at_left x)" |
|
51641
cd05e9fcc63d
remove the within-filter, replace "at" by "at _ within UNIV" (This allows to remove a couple of redundant lemmas)
hoelzl
parents:
51531
diff
changeset
|
1723 |
using ev by (auto simp: eventually_at dist_real_def intro!: exI[of _ "x - b"]) |
51526 | 1724 |
qed simp |
51471 | 1725 |
|
51529
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1726 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1727 |
subsection {* Nested Intervals and Bisection -- Needed for Compactness *} |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1728 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1729 |
lemma nested_sequence_unique: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1730 |
assumes "\<forall>n. f n \<le> f (Suc n)" "\<forall>n. g (Suc n) \<le> g n" "\<forall>n. f n \<le> g n" "(\<lambda>n. f n - g n) ----> 0" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1731 |
shows "\<exists>l::real. ((\<forall>n. f n \<le> l) \<and> f ----> l) \<and> ((\<forall>n. l \<le> g n) \<and> g ----> l)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1732 |
proof - |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1733 |
have "incseq f" unfolding incseq_Suc_iff by fact |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1734 |
have "decseq g" unfolding decseq_Suc_iff by fact |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1735 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1736 |
{ fix n |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1737 |
from `decseq g` have "g n \<le> g 0" by (rule decseqD) simp |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1738 |
with `\<forall>n. f n \<le> g n`[THEN spec, of n] have "f n \<le> g 0" by auto } |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1739 |
then obtain u where "f ----> u" "\<forall>i. f i \<le> u" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1740 |
using incseq_convergent[OF `incseq f`] by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1741 |
moreover |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1742 |
{ fix n |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1743 |
from `incseq f` have "f 0 \<le> f n" by (rule incseqD) simp |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1744 |
with `\<forall>n. f n \<le> g n`[THEN spec, of n] have "f 0 \<le> g n" by simp } |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1745 |
then obtain l where "g ----> l" "\<forall>i. l \<le> g i" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1746 |
using decseq_convergent[OF `decseq g`] by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1747 |
moreover note LIMSEQ_unique[OF assms(4) tendsto_diff[OF `f ----> u` `g ----> l`]] |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1748 |
ultimately show ?thesis by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1749 |
qed |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1750 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1751 |
lemma Bolzano[consumes 1, case_names trans local]: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1752 |
fixes P :: "real \<Rightarrow> real \<Rightarrow> bool" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1753 |
assumes [arith]: "a \<le> b" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1754 |
assumes trans: "\<And>a b c. \<lbrakk>P a b; P b c; a \<le> b; b \<le> c\<rbrakk> \<Longrightarrow> P a c" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1755 |
assumes local: "\<And>x. a \<le> x \<Longrightarrow> x \<le> b \<Longrightarrow> \<exists>d>0. \<forall>a b. a \<le> x \<and> x \<le> b \<and> b - a < d \<longrightarrow> P a b" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1756 |
shows "P a b" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1757 |
proof - |
55415 | 1758 |
def bisect \<equiv> "rec_nat (a, b) (\<lambda>n (x, y). if P x ((x+y) / 2) then ((x+y)/2, y) else (x, (x+y)/2))" |
51529
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1759 |
def l \<equiv> "\<lambda>n. fst (bisect n)" and u \<equiv> "\<lambda>n. snd (bisect n)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1760 |
have l[simp]: "l 0 = a" "\<And>n. l (Suc n) = (if P (l n) ((l n + u n) / 2) then (l n + u n) / 2 else l n)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1761 |
and u[simp]: "u 0 = b" "\<And>n. u (Suc n) = (if P (l n) ((l n + u n) / 2) then u n else (l n + u n) / 2)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1762 |
by (simp_all add: l_def u_def bisect_def split: prod.split) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1763 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1764 |
{ fix n have "l n \<le> u n" by (induct n) auto } note this[simp] |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1765 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1766 |
have "\<exists>x. ((\<forall>n. l n \<le> x) \<and> l ----> x) \<and> ((\<forall>n. x \<le> u n) \<and> u ----> x)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1767 |
proof (safe intro!: nested_sequence_unique) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1768 |
fix n show "l n \<le> l (Suc n)" "u (Suc n) \<le> u n" by (induct n) auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1769 |
next |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1770 |
{ fix n have "l n - u n = (a - b) / 2^n" by (induct n) (auto simp: field_simps) } |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1771 |
then show "(\<lambda>n. l n - u n) ----> 0" by (simp add: LIMSEQ_divide_realpow_zero) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1772 |
qed fact |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1773 |
then obtain x where x: "\<And>n. l n \<le> x" "\<And>n. x \<le> u n" and "l ----> x" "u ----> x" by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1774 |
obtain d where "0 < d" and d: "\<And>a b. a \<le> x \<Longrightarrow> x \<le> b \<Longrightarrow> b - a < d \<Longrightarrow> P a b" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1775 |
using `l 0 \<le> x` `x \<le> u 0` local[of x] by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1776 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1777 |
show "P a b" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1778 |
proof (rule ccontr) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1779 |
assume "\<not> P a b" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1780 |
{ fix n have "\<not> P (l n) (u n)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1781 |
proof (induct n) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1782 |
case (Suc n) with trans[of "l n" "(l n + u n) / 2" "u n"] show ?case by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1783 |
qed (simp add: `\<not> P a b`) } |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1784 |
moreover |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1785 |
{ have "eventually (\<lambda>n. x - d / 2 < l n) sequentially" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1786 |
using `0 < d` `l ----> x` by (intro order_tendstoD[of _ x]) auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1787 |
moreover have "eventually (\<lambda>n. u n < x + d / 2) sequentially" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1788 |
using `0 < d` `u ----> x` by (intro order_tendstoD[of _ x]) auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1789 |
ultimately have "eventually (\<lambda>n. P (l n) (u n)) sequentially" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1790 |
proof eventually_elim |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1791 |
fix n assume "x - d / 2 < l n" "u n < x + d / 2" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1792 |
from add_strict_mono[OF this] have "u n - l n < d" by simp |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1793 |
with x show "P (l n) (u n)" by (rule d) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1794 |
qed } |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1795 |
ultimately show False by simp |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1796 |
qed |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1797 |
qed |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1798 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1799 |
lemma compact_Icc[simp, intro]: "compact {a .. b::real}" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1800 |
proof (cases "a \<le> b", rule compactI) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1801 |
fix C assume C: "a \<le> b" "\<forall>t\<in>C. open t" "{a..b} \<subseteq> \<Union>C" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1802 |
def T == "{a .. b}" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1803 |
from C(1,3) show "\<exists>C'\<subseteq>C. finite C' \<and> {a..b} \<subseteq> \<Union>C'" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1804 |
proof (induct rule: Bolzano) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1805 |
case (trans a b c) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1806 |
then have *: "{a .. c} = {a .. b} \<union> {b .. c}" by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1807 |
from trans obtain C1 C2 where "C1\<subseteq>C \<and> finite C1 \<and> {a..b} \<subseteq> \<Union>C1" "C2\<subseteq>C \<and> finite C2 \<and> {b..c} \<subseteq> \<Union>C2" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1808 |
by (auto simp: *) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1809 |
with trans show ?case |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1810 |
unfolding * by (intro exI[of _ "C1 \<union> C2"]) auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1811 |
next |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1812 |
case (local x) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1813 |
then have "x \<in> \<Union>C" using C by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1814 |
with C(2) obtain c where "x \<in> c" "open c" "c \<in> C" by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1815 |
then obtain e where "0 < e" "{x - e <..< x + e} \<subseteq> c" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1816 |
by (auto simp: open_real_def dist_real_def subset_eq Ball_def abs_less_iff) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1817 |
with `c \<in> C` show ?case |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1818 |
by (safe intro!: exI[of _ "e/2"] exI[of _ "{c}"]) auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1819 |
qed |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1820 |
qed simp |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1821 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1822 |
|
57447
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1823 |
lemma continuous_image_closed_interval: |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1824 |
fixes a b and f :: "real \<Rightarrow> real" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1825 |
defines "S \<equiv> {a..b}" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1826 |
assumes "a \<le> b" and f: "continuous_on S f" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1827 |
shows "\<exists>c d. f`S = {c..d} \<and> c \<le> d" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1828 |
proof - |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1829 |
have S: "compact S" "S \<noteq> {}" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1830 |
using `a \<le> b` by (auto simp: S_def) |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1831 |
obtain c where "c \<in> S" "\<forall>d\<in>S. f d \<le> f c" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1832 |
using continuous_attains_sup[OF S f] by auto |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1833 |
moreover obtain d where "d \<in> S" "\<forall>c\<in>S. f d \<le> f c" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1834 |
using continuous_attains_inf[OF S f] by auto |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1835 |
moreover have "connected (f`S)" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1836 |
using connected_continuous_image[OF f] connected_Icc by (auto simp: S_def) |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1837 |
ultimately have "f ` S = {f d .. f c} \<and> f d \<le> f c" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1838 |
by (auto simp: connected_iff_interval) |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1839 |
then show ?thesis |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1840 |
by auto |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1841 |
qed |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57276
diff
changeset
|
1842 |
|
51529
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1843 |
subsection {* Boundedness of continuous functions *} |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1844 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1845 |
text{*By bisection, function continuous on closed interval is bounded above*} |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1846 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1847 |
lemma isCont_eq_Ub: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1848 |
fixes f :: "real \<Rightarrow> 'a::linorder_topology" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1849 |
shows "a \<le> b \<Longrightarrow> \<forall>x::real. a \<le> x \<and> x \<le> b \<longrightarrow> isCont f x \<Longrightarrow> |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1850 |
\<exists>M. (\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> f x \<le> M) \<and> (\<exists>x. a \<le> x \<and> x \<le> b \<and> f x = M)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1851 |
using continuous_attains_sup[of "{a .. b}" f] |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1852 |
by (auto simp add: continuous_at_imp_continuous_on Ball_def Bex_def) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1853 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1854 |
lemma isCont_eq_Lb: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1855 |
fixes f :: "real \<Rightarrow> 'a::linorder_topology" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1856 |
shows "a \<le> b \<Longrightarrow> \<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> isCont f x \<Longrightarrow> |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1857 |
\<exists>M. (\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> M \<le> f x) \<and> (\<exists>x. a \<le> x \<and> x \<le> b \<and> f x = M)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1858 |
using continuous_attains_inf[of "{a .. b}" f] |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1859 |
by (auto simp add: continuous_at_imp_continuous_on Ball_def Bex_def) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1860 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1861 |
lemma isCont_bounded: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1862 |
fixes f :: "real \<Rightarrow> 'a::linorder_topology" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1863 |
shows "a \<le> b \<Longrightarrow> \<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> isCont f x \<Longrightarrow> \<exists>M. \<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> f x \<le> M" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1864 |
using isCont_eq_Ub[of a b f] by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1865 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1866 |
lemma isCont_has_Ub: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1867 |
fixes f :: "real \<Rightarrow> 'a::linorder_topology" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1868 |
shows "a \<le> b \<Longrightarrow> \<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> isCont f x \<Longrightarrow> |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1869 |
\<exists>M. (\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> f x \<le> M) \<and> (\<forall>N. N < M \<longrightarrow> (\<exists>x. a \<le> x \<and> x \<le> b \<and> N < f x))" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1870 |
using isCont_eq_Ub[of a b f] by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1871 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1872 |
(*HOL style here: object-level formulations*) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1873 |
lemma IVT_objl: "(f(a::real) \<le> (y::real) & y \<le> f(b) & a \<le> b & |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1874 |
(\<forall>x. a \<le> x & x \<le> b --> isCont f x)) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1875 |
--> (\<exists>x. a \<le> x & x \<le> b & f(x) = y)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1876 |
by (blast intro: IVT) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1877 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1878 |
lemma IVT2_objl: "(f(b::real) \<le> (y::real) & y \<le> f(a) & a \<le> b & |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1879 |
(\<forall>x. a \<le> x & x \<le> b --> isCont f x)) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1880 |
--> (\<exists>x. a \<le> x & x \<le> b & f(x) = y)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1881 |
by (blast intro: IVT2) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1882 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1883 |
lemma isCont_Lb_Ub: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1884 |
fixes f :: "real \<Rightarrow> real" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1885 |
assumes "a \<le> b" "\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> isCont f x" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1886 |
shows "\<exists>L M. (\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> L \<le> f x \<and> f x \<le> M) \<and> |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1887 |
(\<forall>y. L \<le> y \<and> y \<le> M \<longrightarrow> (\<exists>x. a \<le> x \<and> x \<le> b \<and> (f x = y)))" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1888 |
proof - |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1889 |
obtain M where M: "a \<le> M" "M \<le> b" "\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> f x \<le> f M" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1890 |
using isCont_eq_Ub[OF assms] by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1891 |
obtain L where L: "a \<le> L" "L \<le> b" "\<forall>x. a \<le> x \<and> x \<le> b \<longrightarrow> f L \<le> f x" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1892 |
using isCont_eq_Lb[OF assms] by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1893 |
show ?thesis |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1894 |
using IVT[of f L _ M] IVT2[of f L _ M] M L assms |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1895 |
apply (rule_tac x="f L" in exI) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1896 |
apply (rule_tac x="f M" in exI) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1897 |
apply (cases "L \<le> M") |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1898 |
apply (simp, metis order_trans) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1899 |
apply (simp, metis order_trans) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1900 |
done |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1901 |
qed |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1902 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1903 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1904 |
text{*Continuity of inverse function*} |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1905 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1906 |
lemma isCont_inverse_function: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1907 |
fixes f g :: "real \<Rightarrow> real" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1908 |
assumes d: "0 < d" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1909 |
and inj: "\<forall>z. \<bar>z-x\<bar> \<le> d \<longrightarrow> g (f z) = z" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1910 |
and cont: "\<forall>z. \<bar>z-x\<bar> \<le> d \<longrightarrow> isCont f z" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1911 |
shows "isCont g (f x)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1912 |
proof - |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1913 |
let ?A = "f (x - d)" and ?B = "f (x + d)" and ?D = "{x - d..x + d}" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1914 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1915 |
have f: "continuous_on ?D f" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1916 |
using cont by (intro continuous_at_imp_continuous_on ballI) auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1917 |
then have g: "continuous_on (f`?D) g" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1918 |
using inj by (intro continuous_on_inv) auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1919 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1920 |
from d f have "{min ?A ?B <..< max ?A ?B} \<subseteq> f ` ?D" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1921 |
by (intro connected_contains_Ioo connected_continuous_image) (auto split: split_min split_max) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1922 |
with g have "continuous_on {min ?A ?B <..< max ?A ?B} g" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1923 |
by (rule continuous_on_subset) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1924 |
moreover |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1925 |
have "(?A < f x \<and> f x < ?B) \<or> (?B < f x \<and> f x < ?A)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1926 |
using d inj by (intro continuous_inj_imp_mono[OF _ _ f] inj_on_imageI2[of g, OF inj_onI]) auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1927 |
then have "f x \<in> {min ?A ?B <..< max ?A ?B}" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1928 |
by auto |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1929 |
ultimately |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1930 |
show ?thesis |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1931 |
by (simp add: continuous_on_eq_continuous_at) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1932 |
qed |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1933 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1934 |
lemma isCont_inverse_function2: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1935 |
fixes f g :: "real \<Rightarrow> real" shows |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1936 |
"\<lbrakk>a < x; x < b; |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1937 |
\<forall>z. a \<le> z \<and> z \<le> b \<longrightarrow> g (f z) = z; |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1938 |
\<forall>z. a \<le> z \<and> z \<le> b \<longrightarrow> isCont f z\<rbrakk> |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1939 |
\<Longrightarrow> isCont g (f x)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1940 |
apply (rule isCont_inverse_function |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1941 |
[where f=f and d="min (x - a) (b - x)"]) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1942 |
apply (simp_all add: abs_le_iff) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1943 |
done |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1944 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1945 |
(* need to rename second isCont_inverse *) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1946 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1947 |
lemma isCont_inv_fun: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1948 |
fixes f g :: "real \<Rightarrow> real" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1949 |
shows "[| 0 < d; \<forall>z. \<bar>z - x\<bar> \<le> d --> g(f(z)) = z; |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1950 |
\<forall>z. \<bar>z - x\<bar> \<le> d --> isCont f z |] |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1951 |
==> isCont g (f x)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1952 |
by (rule isCont_inverse_function) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1953 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1954 |
text{*Bartle/Sherbert: Introduction to Real Analysis, Theorem 4.2.9, p. 110*} |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1955 |
lemma LIM_fun_gt_zero: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1956 |
fixes f :: "real \<Rightarrow> real" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1957 |
shows "f -- c --> l \<Longrightarrow> 0 < l \<Longrightarrow> \<exists>r. 0 < r \<and> (\<forall>x. x \<noteq> c \<and> \<bar>c - x\<bar> < r \<longrightarrow> 0 < f x)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1958 |
apply (drule (1) LIM_D, clarify) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1959 |
apply (rule_tac x = s in exI) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1960 |
apply (simp add: abs_less_iff) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1961 |
done |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1962 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1963 |
lemma LIM_fun_less_zero: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1964 |
fixes f :: "real \<Rightarrow> real" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1965 |
shows "f -- c --> l \<Longrightarrow> l < 0 \<Longrightarrow> \<exists>r. 0 < r \<and> (\<forall>x. x \<noteq> c \<and> \<bar>c - x\<bar> < r \<longrightarrow> f x < 0)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1966 |
apply (drule LIM_D [where r="-l"], simp, clarify) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1967 |
apply (rule_tac x = s in exI) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1968 |
apply (simp add: abs_less_iff) |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1969 |
done |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1970 |
|
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1971 |
lemma LIM_fun_not_zero: |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1972 |
fixes f :: "real \<Rightarrow> real" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1973 |
shows "f -- c --> l \<Longrightarrow> l \<noteq> 0 \<Longrightarrow> \<exists>r. 0 < r \<and> (\<forall>x. x \<noteq> c \<and> \<bar>c - x\<bar> < r \<longrightarrow> f x \<noteq> 0)" |
2d2f59e6055a
move theorems about compactness of real closed intervals, the intermediate value theorem, and lemmas about continuity of bijective functions from Deriv.thy to Limits.thy
hoelzl
parents:
51526
diff
changeset
|
1974 |
using LIM_fun_gt_zero[of f l c] LIM_fun_less_zero[of f l c] by (auto simp add: neq_iff) |
51531
f415febf4234
remove Metric_Spaces and move its content into Limits and Real_Vector_Spaces
hoelzl
parents:
51529
diff
changeset
|
1975 |
|
31349
2261c8781f73
new theory of filters and limits; prove LIMSEQ and LIM lemmas using filters
huffman
parents:
diff
changeset
|
1976 |
end |
50324
0a1242d5e7d4
add filterlim rules for diverging multiplication and addition; move at_infinity to the HOL image
hoelzl
parents:
50323
diff
changeset
|
1977 |