Theory Limits
section ‹Limits on Real Vector Spaces›
theory Limits
imports Real_Vector_Spaces
begin
lemma range_mult [simp]:
fixes a::"real" shows "range ((*) a) = (if a=0 then {0} else UNIV)"
by (simp add: surj_def) (meson dvdE dvd_field_iff)
subsection ‹Filter going to infinity norm›
definition at_infinity :: "'a::real_normed_vector filter"
where "at_infinity = (INF r. principal {x. r ≤ norm x})"
lemma eventually_at_infinity: "eventually P at_infinity ⟷ (∃b. ∀x. b ≤ norm x ⟶ P x)"
unfolding at_infinity_def
by (subst eventually_INF_base)
(auto simp: subset_eq eventually_principal intro!: exI[of _ "max a b" for a b])
corollary eventually_at_infinity_pos:
"eventually p at_infinity ⟷ (∃b. 0 < b ∧ (∀x. norm x ≥ b ⟶ p x))"
unfolding eventually_at_infinity
by (meson le_less_trans norm_ge_zero not_le zero_less_one)
lemma at_infinity_eq_at_top_bot: "(at_infinity :: real filter) = sup at_top at_bot"
proof -
have 1: "⟦∀n≥u. A n; ∀n≤v. A n⟧
⟹ ∃b. ∀x. b ≤ ¦x¦ ⟶ A x" for A and u v::real
by (rule_tac x="max (- v) u" in exI) (auto simp: abs_real_def)
have 2: "∀x. u ≤ ¦x¦ ⟶ A x ⟹ ∃N. ∀n≥N. A n" for A and u::real
by (meson abs_less_iff le_cases less_le_not_le)
have 3: "∀x. u ≤ ¦x¦ ⟶ A x ⟹ ∃N. ∀n≤N. A n" for A and u::real
by (metis (full_types) abs_ge_self abs_minus_cancel le_minus_iff order_trans)
show ?thesis
by (auto simp: filter_eq_iff eventually_sup eventually_at_infinity
eventually_at_top_linorder eventually_at_bot_linorder intro: 1 2 3)
qed
lemma at_top_le_at_infinity: "at_top ≤ (at_infinity :: real filter)"
unfolding at_infinity_eq_at_top_bot by simp
lemma at_bot_le_at_infinity: "at_bot ≤ (at_infinity :: real filter)"
unfolding at_infinity_eq_at_top_bot by simp
lemma filterlim_at_top_imp_at_infinity: "filterlim f at_top F ⟹ filterlim f at_infinity F"
for f :: "_ ⇒ real"
by (rule filterlim_mono[OF _ at_top_le_at_infinity order_refl])
lemma filterlim_real_at_infinity_sequentially: "filterlim real at_infinity sequentially"
by (simp add: filterlim_at_top_imp_at_infinity filterlim_real_sequentially)
lemma lim_infinity_imp_sequentially: "(f ⤏ l) at_infinity ⟹ ((λn. f(n)) ⤏ l) sequentially"
by (simp add: filterlim_at_top_imp_at_infinity filterlim_compose filterlim_real_sequentially)
subsubsection ‹Boundedness›
definition Bfun :: "('a ⇒ 'b::metric_space) ⇒ 'a filter ⇒ bool"
where Bfun_metric_def: "Bfun f F = (∃y. ∃K>0. eventually (λx. dist (f x) y ≤ K) F)"
abbreviation Bseq :: "(nat ⇒ 'a::metric_space) ⇒ bool"
where "Bseq X ≡ Bfun X sequentially"
lemma Bseq_conv_Bfun: "Bseq X ⟷ Bfun X sequentially" ..
lemma Bseq_ignore_initial_segment: "Bseq X ⟹ Bseq (λn. X (n + k))"
unfolding Bfun_metric_def by (subst eventually_sequentially_seg)
lemma Bseq_offset: "Bseq (λn. X (n + k)) ⟹ Bseq X"
unfolding Bfun_metric_def by (subst (asm) eventually_sequentially_seg)
lemma Bfun_def: "Bfun f F ⟷ (∃K>0. eventually (λx. norm (f x) ≤ K) F)"
unfolding Bfun_metric_def norm_conv_dist
proof safe
fix y K
assume K: "0 < K" and *: "eventually (λx. dist (f x) y ≤ K) F"
moreover have "eventually (λx. dist (f x) 0 ≤ dist (f x) y + dist 0 y) F"
by (intro always_eventually) (metis dist_commute dist_triangle)
with * have "eventually (λx. dist (f x) 0 ≤ K + dist 0 y) F"
by eventually_elim auto
with ‹0 < K› show "∃K>0. eventually (λx. dist (f x) 0 ≤ K) F"
by (intro exI[of _ "K + dist 0 y"] add_pos_nonneg conjI zero_le_dist) auto
qed (force simp del: norm_conv_dist [symmetric])
lemma BfunI:
assumes K: "eventually (λx. norm (f x) ≤ K) F"
shows "Bfun f F"
unfolding Bfun_def
proof (intro exI conjI allI)
show "0 < max K 1" by simp
show "eventually (λx. norm (f x) ≤ max K 1) F"
using K by (rule eventually_mono) simp
qed
lemma BfunE:
assumes "Bfun f F"
obtains B where "0 < B" and "eventually (λx. norm (f x) ≤ B) F"
using assms unfolding Bfun_def by blast
lemma Cauchy_Bseq:
assumes "Cauchy X" shows "Bseq X"
proof -
have "∃y K. 0 < K ∧ (∃N. ∀n≥N. dist (X n) y ≤ K)"
if "⋀m n. ⟦m ≥ M; n ≥ M⟧ ⟹ dist (X m) (X n) < 1" for M
by (meson order.order_iff_strict that zero_less_one)
with assms show ?thesis
by (force simp: Cauchy_def Bfun_metric_def eventually_sequentially)
qed
subsubsection ‹Bounded Sequences›
lemma BseqI': "(⋀n. norm (X n) ≤ K) ⟹ Bseq X"
by (intro BfunI) (auto simp: eventually_sequentially)
lemma Bseq_def: "Bseq X ⟷ (∃K>0. ∀n. norm (X n) ≤ K)"
unfolding Bfun_def eventually_sequentially
proof safe
fix N K
assume "0 < K" "∀n≥N. norm (X n) ≤ K"
then show "∃K>0. ∀n. norm (X n) ≤ K"
by (intro exI[of _ "max (Max (norm ` X ` {..N})) K"] max.strict_coboundedI2)
(auto intro!: imageI not_less[where 'a=nat, THEN iffD1] Max_ge simp: le_max_iff_disj)
qed auto
lemma BseqE: "Bseq X ⟹ (⋀K. 0 < K ⟹ ∀n. norm (X n) ≤ K ⟹ Q) ⟹ Q"
unfolding Bseq_def by auto
lemma BseqD: "Bseq X ⟹ ∃K. 0 < K ∧ (∀n. norm (X n) ≤ K)"
by (simp add: Bseq_def)
lemma BseqI: "0 < K ⟹ ∀n. norm (X n) ≤ K ⟹ Bseq X"
by (auto simp: Bseq_def)
lemma Bseq_bdd_above: "Bseq X ⟹ bdd_above (range X)"
for X :: "nat ⇒ real"
proof (elim BseqE, intro bdd_aboveI2)
fix K n
assume "0 < K" "∀n. norm (X n) ≤ K"
then show "X n ≤ K"
by (auto elim!: allE[of _ n])
qed
lemma Bseq_bdd_above': "Bseq X ⟹ bdd_above (range (λn. norm (X n)))"
for X :: "nat ⇒ 'a :: real_normed_vector"
proof (elim BseqE, intro bdd_aboveI2)
fix K n
assume "0 < K" "∀n. norm (X n) ≤ K"
then show "norm (X n) ≤ K"
by (auto elim!: allE[of _ n])
qed
lemma Bseq_bdd_below: "Bseq X ⟹ bdd_below (range X)"
for X :: "nat ⇒ real"
proof (elim BseqE, intro bdd_belowI2)
fix K n
assume "0 < K" "∀n. norm (X n) ≤ K"
then show "- K ≤ X n"
by (auto elim!: allE[of _ n])
qed
lemma Bseq_eventually_mono:
assumes "eventually (λn. norm (f n) ≤ norm (g n)) sequentially" "Bseq g"
shows "Bseq f"
proof -
from assms(2) obtain K where "0 < K" and "eventually (λn. norm (g n) ≤ K) sequentially"
unfolding Bfun_def by fast
with assms(1) have "eventually (λn. norm (f n) ≤ K) sequentially"
by (fast elim: eventually_elim2 order_trans)
with ‹0 < K› show "Bseq f"
unfolding Bfun_def by fast
qed
lemma lemma_NBseq_def: "(∃K > 0. ∀n. norm (X n) ≤ K) ⟷ (∃N. ∀n. norm (X n) ≤ real(Suc N))"
proof safe
fix K :: real
from reals_Archimedean2 obtain n :: nat where "K < real n" ..
then have "K ≤ real (Suc n)" by auto
moreover assume "∀m. norm (X m) ≤ K"
ultimately have "∀m. norm (X m) ≤ real (Suc n)"
by (blast intro: order_trans)
then show "∃N. ∀n. norm (X n) ≤ real (Suc N)" ..
next
show "⋀N. ∀n. norm (X n) ≤ real (Suc N) ⟹ ∃K>0. ∀n. norm (X n) ≤ K"
using of_nat_0_less_iff by blast
qed
text ‹Alternative definition for ‹Bseq›.›
lemma Bseq_iff: "Bseq X ⟷ (∃N. ∀n. norm (X n) ≤ real(Suc N))"
by (simp add: Bseq_def) (simp add: lemma_NBseq_def)
lemma lemma_NBseq_def2: "(∃K > 0. ∀n. norm (X n) ≤ K) = (∃N. ∀n. norm (X n) < real(Suc N))"
proof -
have *: "⋀N. ∀n. norm (X n) ≤ 1 + real N ⟹
∃N. ∀n. norm (X n) < 1 + real N"
by (metis add.commute le_less_trans less_add_one of_nat_Suc)
then show ?thesis
unfolding lemma_NBseq_def
by (metis less_le_not_le not_less_iff_gr_or_eq of_nat_Suc)
qed
text ‹Yet another definition for Bseq.›
lemma Bseq_iff1a: "Bseq X ⟷ (∃N. ∀n. norm (X n) < real (Suc N))"
by (simp add: Bseq_def lemma_NBseq_def2)
subsubsection ‹A Few More Equivalence Theorems for Boundedness›
text ‹Alternative formulation for boundedness.›
lemma Bseq_iff2: "Bseq X ⟷ (∃k > 0. ∃x. ∀n. norm (X n + - x) ≤ k)"
by (metis BseqE BseqI' add.commute add_cancel_right_left add_uminus_conv_diff norm_add_leD
norm_minus_cancel norm_minus_commute)
text ‹Alternative formulation for boundedness.›
lemma Bseq_iff3: "Bseq X ⟷ (∃k>0. ∃N. ∀n. norm (X n + - X N) ≤ k)"
(is "?P ⟷ ?Q")
proof
assume ?P
then obtain K where *: "0 < K" and **: "⋀n. norm (X n) ≤ K"
by (auto simp: Bseq_def)
from * have "0 < K + norm (X 0)" by (rule order_less_le_trans) simp
from ** have "∀n. norm (X n - X 0) ≤ K + norm (X 0)"
by (auto intro: order_trans norm_triangle_ineq4)
then have "∀n. norm (X n + - X 0) ≤ K + norm (X 0)"
by simp
with ‹0 < K + norm (X 0)› show ?Q by blast
next
assume ?Q
then show ?P by (auto simp: Bseq_iff2)
qed
subsubsection ‹Upper Bounds and Lubs of Bounded Sequences›
lemma Bseq_minus_iff: "Bseq (λn. - (X n) :: 'a::real_normed_vector) ⟷ Bseq X"
by (simp add: Bseq_def)
lemma Bseq_add:
fixes f :: "nat ⇒ 'a::real_normed_vector"
assumes "Bseq f"
shows "Bseq (λx. f x + c)"
proof -
from assms obtain K where K: "⋀x. norm (f x) ≤ K"
unfolding Bseq_def by blast
{
fix x :: nat
have "norm (f x + c) ≤ norm (f x) + norm c" by (rule norm_triangle_ineq)
also have "norm (f x) ≤ K" by (rule K)
finally have "norm (f x + c) ≤ K + norm c" by simp
}
then show ?thesis by (rule BseqI')
qed
lemma Bseq_add_iff: "Bseq (λx. f x + c) ⟷ Bseq f"
for f :: "nat ⇒ 'a::real_normed_vector"
using Bseq_add[of f c] Bseq_add[of "λx. f x + c" "-c"] by auto
lemma Bseq_mult:
fixes f g :: "nat ⇒ 'a::real_normed_field"
assumes "Bseq f" and "Bseq g"
shows "Bseq (λx. f x * g x)"
proof -
from assms obtain K1 K2 where K: "norm (f x) ≤ K1" "K1 > 0" "norm (g x) ≤ K2" "K2 > 0"
for x
unfolding Bseq_def by blast
then have "norm (f x * g x) ≤ K1 * K2" for x
by (auto simp: norm_mult intro!: mult_mono)
then show ?thesis by (rule BseqI')
qed
lemma Bfun_const [simp]: "Bfun (λ_. c) F"
unfolding Bfun_metric_def by (auto intro!: exI[of _ c] exI[of _ "1::real"])
lemma Bseq_cmult_iff:
fixes c :: "'a::real_normed_field"
assumes "c ≠ 0"
shows "Bseq (λx. c * f x) ⟷ Bseq f"
proof
assume "Bseq (λx. c * f x)"
with Bfun_const have "Bseq (λx. inverse c * (c * f x))"
by (rule Bseq_mult)
with ‹c ≠ 0› show "Bseq f"
by (simp add: field_split_simps)
qed (intro Bseq_mult Bfun_const)
lemma Bseq_subseq: "Bseq f ⟹ Bseq (λx. f (g x))"
for f :: "nat ⇒ 'a::real_normed_vector"
unfolding Bseq_def by auto
lemma Bseq_Suc_iff: "Bseq (λn. f (Suc n)) ⟷ Bseq f"
for f :: "nat ⇒ 'a::real_normed_vector"
using Bseq_offset[of f 1] by (auto intro: Bseq_subseq)
lemma increasing_Bseq_subseq_iff:
assumes "⋀x y. x ≤ y ⟹ norm (f x :: 'a::real_normed_vector) ≤ norm (f y)" "strict_mono g"
shows "Bseq (λx. f (g x)) ⟷ Bseq f"
proof
assume "Bseq (λx. f (g x))"
then obtain K where K: "⋀x. norm (f (g x)) ≤ K"
unfolding Bseq_def by auto
{
fix x :: nat
from filterlim_subseq[OF assms(2)] obtain y where "g y ≥ x"
by (auto simp: filterlim_at_top eventually_at_top_linorder)
then have "norm (f x) ≤ norm (f (g y))"
using assms(1) by blast
also have "norm (f (g y)) ≤ K" by (rule K)
finally have "norm (f x) ≤ K" .
}
then show "Bseq f" by (rule BseqI')
qed (use Bseq_subseq[of f g] in simp_all)
lemma nonneg_incseq_Bseq_subseq_iff:
fixes f :: "nat ⇒ real"
and g :: "nat ⇒ nat"
assumes "⋀x. f x ≥ 0" "incseq f" "strict_mono g"
shows "Bseq (λx. f (g x)) ⟷ Bseq f"
using assms by (intro increasing_Bseq_subseq_iff) (auto simp: incseq_def)
lemma Bseq_eq_bounded: "range f ⊆ {a..b} ⟹ Bseq f"
for a b :: real
proof (rule BseqI'[where K="max (norm a) (norm b)"])
fix n assume "range f ⊆ {a..b}"
then have "f n ∈ {a..b}"
by blast
then show "norm (f n) ≤ max (norm a) (norm b)"
by auto
qed
lemma incseq_bounded: "incseq X ⟹ ∀i. X i ≤ B ⟹ Bseq X"
for B :: real
by (intro Bseq_eq_bounded[of X "X 0" B]) (auto simp: incseq_def)
lemma decseq_bounded: "decseq X ⟹ ∀i. B ≤ X i ⟹ Bseq X"
for B :: real
by (intro Bseq_eq_bounded[of X B "X 0"]) (auto simp: decseq_def)
subsubsection ‹Polynomal function extremal theorem, from HOL Light›
lemma polyfun_extremal_lemma:
fixes c :: "nat ⇒ 'a::real_normed_div_algebra"
assumes "0 < e"
shows "∃M. ∀z. M ≤ norm(z) ⟶ norm (∑i≤n. c(i) * z^i) ≤ e * norm(z) ^ (Suc n)"
proof (induct n)
case 0 with assms
show ?case
apply (rule_tac x="norm (c 0) / e" in exI)
apply (auto simp: field_simps)
done
next
case (Suc n)
obtain M where M: "⋀z. M ≤ norm z ⟹ norm (∑i≤n. c i * z^i) ≤ e * norm z ^ Suc n"
using Suc assms by blast
show ?case
proof (rule exI [where x= "max M (1 + norm(c(Suc n)) / e)"], clarsimp simp del: power_Suc)
fix z::'a
assume z1: "M ≤ norm z" and "1 + norm (c (Suc n)) / e ≤ norm z"
then have z2: "e + norm (c (Suc n)) ≤ e * norm z"
using assms by (simp add: field_simps)
have "norm (∑i≤n. c i * z^i) ≤ e * norm z ^ Suc n"
using M [OF z1] by simp
then have "norm (∑i≤n. c i * z^i) + norm (c (Suc n) * z ^ Suc n) ≤ e * norm z ^ Suc n + norm (c (Suc n) * z ^ Suc n)"
by simp
then have "norm ((∑i≤n. c i * z^i) + c (Suc n) * z ^ Suc n) ≤ e * norm z ^ Suc n + norm (c (Suc n) * z ^ Suc n)"
by (blast intro: norm_triangle_le elim: )
also have "... ≤ (e + norm (c (Suc n))) * norm z ^ Suc n"
by (simp add: norm_power norm_mult algebra_simps)
also have "... ≤ (e * norm z) * norm z ^ Suc n"
by (metis z2 mult.commute mult_left_mono norm_ge_zero norm_power)
finally show "norm ((∑i≤n. c i * z^i) + c (Suc n) * z ^ Suc n) ≤ e * norm z ^ Suc (Suc n)"
by simp
qed
qed
lemma polyfun_extremal:
fixes c :: "nat ⇒ 'a::real_normed_div_algebra"
assumes k: "c k ≠ 0" "1≤k" and kn: "k≤n"
shows "eventually (λz. norm (∑i≤n. c(i) * z^i) ≥ B) at_infinity"
using kn
proof (induction n)
case 0
then show ?case
using k by simp
next
case (Suc m)
show ?case
proof (cases "c (Suc m) = 0")
case True
then show ?thesis using Suc k
by auto (metis antisym_conv less_eq_Suc_le not_le)
next
case False
then obtain M where M:
"⋀z. M ≤ norm z ⟹ norm (∑i≤m. c i * z^i) ≤ norm (c (Suc m)) / 2 * norm z ^ Suc m"
using polyfun_extremal_lemma [of "norm(c (Suc m)) / 2" c m] Suc
by auto
have "∃b. ∀z. b ≤ norm z ⟶ B ≤ norm (∑i≤Suc m. c i * z^i)"
proof (rule exI [where x="max M (max 1 (¦B¦ / (norm(c (Suc m)) / 2)))"], clarsimp simp del: power_Suc)
fix z::'a
assume z1: "M ≤ norm z" "1 ≤ norm z"
and "¦B¦ * 2 / norm (c (Suc m)) ≤ norm z"
then have z2: "¦B¦ ≤ norm (c (Suc m)) * norm z / 2"
using False by (simp add: field_simps)
have nz: "norm z ≤ norm z ^ Suc m"
by (metis ‹1 ≤ norm z› One_nat_def less_eq_Suc_le power_increasing power_one_right zero_less_Suc)
have *: "⋀y x. norm (c (Suc m)) * norm z / 2 ≤ norm y - norm x ⟹ B ≤ norm (x + y)"
by (metis abs_le_iff add.commute norm_diff_ineq order_trans z2)
have "norm z * norm (c (Suc m)) + 2 * norm (∑i≤m. c i * z^i)
≤ norm (c (Suc m)) * norm z + norm (c (Suc m)) * norm z ^ Suc m"
using M [of z] Suc z1 by auto
also have "... ≤ 2 * (norm (c (Suc m)) * norm z ^ Suc m)"
using nz by (simp add: mult_mono del: power_Suc)
finally show "B ≤ norm ((∑i≤m. c i * z^i) + c (Suc m) * z ^ Suc m)"
using Suc.IH
apply (auto simp: eventually_at_infinity)
apply (rule *)
apply (simp add: field_simps norm_mult norm_power)
done
qed
then show ?thesis
by (simp add: eventually_at_infinity)
qed
qed
subsection ‹Convergence to Zero›
definition Zfun :: "('a ⇒ 'b::real_normed_vector) ⇒ 'a filter ⇒ bool"
where "Zfun f F = (∀r>0. eventually (λx. norm (f x) < r) F)"
lemma ZfunI: "(⋀r. 0 < r ⟹ eventually (λx. norm (f x) < r) F) ⟹ Zfun f F"
by (simp add: Zfun_def)
lemma ZfunD: "Zfun f F ⟹ 0 < r ⟹ eventually (λx. norm (f x) < r) F"
by (simp add: Zfun_def)
lemma Zfun_ssubst: "eventually (λx. f x = g x) F ⟹ Zfun g F ⟹ Zfun f F"
unfolding Zfun_def by (auto elim!: eventually_rev_mp)
lemma Zfun_zero: "Zfun (λx. 0) F"
unfolding Zfun_def by simp
lemma Zfun_norm_iff: "Zfun (λx. norm (f x)) F = Zfun (λx. f x) F"
unfolding Zfun_def by simp
lemma Zfun_imp_Zfun:
assumes f: "Zfun f F"
and g: "eventually (λx. norm (g x) ≤ norm (f x) * K) F"
shows "Zfun (λx. g x) F"
proof (cases "0 < K")
case K: True
show ?thesis
proof (rule ZfunI)
fix r :: real
assume "0 < r"
then have "0 < r / K" using K by simp
then have "eventually (λx. norm (f x) < r / K) F"
using ZfunD [OF f] by blast
with g show "eventually (λx. norm (g x) < r) F"
proof eventually_elim
case (elim x)
then have "norm (f x) * K < r"
by (simp add: pos_less_divide_eq K)
then show ?case
by (simp add: order_le_less_trans [OF elim(1)])
qed
qed
next
case False
then have K: "K ≤ 0" by (simp only: not_less)
show ?thesis
proof (rule ZfunI)
fix r :: real
assume "0 < r"
from g show "eventually (λx. norm (g x) < r) F"
proof eventually_elim
case (elim x)
also have "norm (f x) * K ≤ norm (f x) * 0"
using K norm_ge_zero by (rule mult_left_mono)
finally show ?case
using ‹0 < r› by simp
qed
qed
qed
lemma Zfun_le: "Zfun g F ⟹ ∀x. norm (f x) ≤ norm (g x) ⟹ Zfun f F"
by (erule Zfun_imp_Zfun [where K = 1]) simp
lemma Zfun_add:
assumes f: "Zfun f F"
and g: "Zfun g F"
shows "Zfun (λx. f x + g x) F"
proof (rule ZfunI)
fix r :: real
assume "0 < r"
then have r: "0 < r / 2" by simp
have "eventually (λx. norm (f x) < r/2) F"
using f r by (rule ZfunD)
moreover
have "eventually (λx. norm (g x) < r/2) F"
using g r by (rule ZfunD)
ultimately
show "eventually (λx. norm (f x + g x) < r) F"
proof eventually_elim
case (elim x)
have "norm (f x + g x) ≤ norm (f x) + norm (g x)"
by (rule norm_triangle_ineq)
also have "… < r/2 + r/2"
using elim by (rule add_strict_mono)
finally show ?case
by simp
qed
qed
lemma Zfun_minus: "Zfun f F ⟹ Zfun (λx. - f x) F"
unfolding Zfun_def by simp
lemma Zfun_diff: "Zfun f F ⟹ Zfun g F ⟹ Zfun (λx. f x - g x) F"
using Zfun_add [of f F "λx. - g x"] by (simp add: Zfun_minus)
lemma (in bounded_linear) Zfun:
assumes g: "Zfun g F"
shows "Zfun (λx. f (g x)) F"
proof -
obtain K where "norm (f x) ≤ norm x * K" for x
using bounded by blast
then have "eventually (λx. norm (f (g x)) ≤ norm (g x) * K) F"
by simp
with g show ?thesis
by (rule Zfun_imp_Zfun)
qed
lemma (in bounded_bilinear) Zfun:
assumes f: "Zfun f F"
and g: "Zfun g F"
shows "Zfun (λx. f x ** g x) F"
proof (rule ZfunI)
fix r :: real
assume r: "0 < r"
obtain K where K: "0 < K"
and norm_le: "norm (x ** y) ≤ norm x * norm y * K" for x y
using pos_bounded by blast
from K have K': "0 < inverse K"
by (rule positive_imp_inverse_positive)
have "eventually (λx. norm (f x) < r) F"
using f r by (rule ZfunD)
moreover
have "eventually (λx. norm (g x) < inverse K) F"
using g K' by (rule ZfunD)
ultimately
show "eventually (λx. norm (f x ** g x) < r) F"
proof eventually_elim
case (elim x)
have "norm (f x ** g x) ≤ norm (f x) * norm (g x) * K"
by (rule norm_le)
also have "norm (f x) * norm (g x) * K < r * inverse K * K"
by (intro mult_strict_right_mono mult_strict_mono' norm_ge_zero elim K)
also from K have "r * inverse K * K = r"
by simp
finally show ?case .
qed
qed
lemma (in bounded_bilinear) Zfun_left: "Zfun f F ⟹ Zfun (λx. f x ** a) F"
by (rule bounded_linear_left [THEN bounded_linear.Zfun])
lemma (in bounded_bilinear) Zfun_right: "Zfun f F ⟹ Zfun (λx. a ** f x) F"
by (rule bounded_linear_right [THEN bounded_linear.Zfun])
lemmas Zfun_mult = bounded_bilinear.Zfun [OF bounded_bilinear_mult]
lemmas Zfun_mult_right = bounded_bilinear.Zfun_right [OF bounded_bilinear_mult]
lemmas Zfun_mult_left = bounded_bilinear.Zfun_left [OF bounded_bilinear_mult]
lemma tendsto_Zfun_iff: "(f ⤏ a) F = Zfun (λx. f x - a) F"
by (simp only: tendsto_iff Zfun_def dist_norm)
lemma tendsto_0_le:
"(f ⤏ 0) F ⟹ eventually (λx. norm (g x) ≤ norm (f x) * K) F ⟹ (g ⤏ 0) F"
by (simp add: Zfun_imp_Zfun tendsto_Zfun_iff)
subsubsection ‹Distance and norms›
lemma tendsto_dist [tendsto_intros]:
fixes l m :: "'a::metric_space"
assumes f: "(f ⤏ l) F"
and g: "(g ⤏ m) F"
shows "((λx. dist (f x) (g x)) ⤏ dist l m) F"
proof (rule tendstoI)
fix e :: real
assume "0 < e"
then have e2: "0 < e/2" by simp
from tendstoD [OF f e2] tendstoD [OF g e2]
show "eventually (λx. dist (dist (f x) (g x)) (dist l m) < e) F"
proof (eventually_elim)
case (elim x)
then show "dist (dist (f x) (g x)) (dist l m) < e"
unfolding dist_real_def
using dist_triangle2 [of "f x" "g x" "l"]
and dist_triangle2 [of "g x" "l" "m"]
and dist_triangle3 [of "l" "m" "f x"]
and dist_triangle [of "f x" "m" "g x"]
by arith
qed
qed
lemma continuous_dist[continuous_intros]:
fixes f g :: "_ ⇒ 'a :: metric_space"
shows "continuous F f ⟹ continuous F g ⟹ continuous F (λx. dist (f x) (g x))"
unfolding continuous_def by (rule tendsto_dist)
lemma continuous_on_dist[continuous_intros]:
fixes f g :: "_ ⇒ 'a :: metric_space"
shows "continuous_on s f ⟹ continuous_on s g ⟹ continuous_on s (λx. dist (f x) (g x))"
unfolding continuous_on_def by (auto intro: tendsto_dist)
lemma continuous_at_dist: "isCont (dist a) b"
using continuous_on_dist [OF continuous_on_const continuous_on_id] continuous_on_eq_continuous_within by blast
lemma tendsto_norm [tendsto_intros]: "(f ⤏ a) F ⟹ ((λx. norm (f x)) ⤏ norm a) F"
unfolding norm_conv_dist by (intro tendsto_intros)
lemma continuous_norm [continuous_intros]: "continuous F f ⟹ continuous F (λx. norm (f x))"
unfolding continuous_def by (rule tendsto_norm)
lemma continuous_on_norm [continuous_intros]:
"continuous_on s f ⟹ continuous_on s (λx. norm (f x))"
unfolding continuous_on_def by (auto intro: tendsto_norm)
lemma continuous_on_norm_id [continuous_intros]: "continuous_on S norm"
by (intro continuous_on_id continuous_on_norm)
lemma tendsto_norm_zero: "(f ⤏ 0) F ⟹ ((λx. norm (f x)) ⤏ 0) F"
by (drule tendsto_norm) simp
lemma tendsto_norm_zero_cancel: "((λx. norm (f x)) ⤏ 0) F ⟹ (f ⤏ 0) F"
unfolding tendsto_iff dist_norm by simp
lemma tendsto_norm_zero_iff: "((λx. norm (f x)) ⤏ 0) F ⟷ (f ⤏ 0) F"
unfolding tendsto_iff dist_norm by simp
lemma tendsto_rabs [tendsto_intros]: "(f ⤏ l) F ⟹ ((λx. ¦f x¦) ⤏ ¦l¦) F"
for l :: real
by (fold real_norm_def) (rule tendsto_norm)
lemma continuous_rabs [continuous_intros]:
"continuous F f ⟹ continuous F (λx. ¦f x :: real¦)"
unfolding real_norm_def[symmetric] by (rule continuous_norm)
lemma continuous_on_rabs [continuous_intros]:
"continuous_on s f ⟹ continuous_on s (λx. ¦f x :: real¦)"
unfolding real_norm_def[symmetric] by (rule continuous_on_norm)
lemma tendsto_rabs_zero: "(f ⤏ (0::real)) F ⟹ ((λx. ¦f x¦) ⤏ 0) F"
by (fold real_norm_def) (rule tendsto_norm_zero)
lemma tendsto_rabs_zero_cancel: "((λx. ¦f x¦) ⤏ (0::real)) F ⟹ (f ⤏ 0) F"
by (fold real_norm_def) (rule tendsto_norm_zero_cancel)
lemma tendsto_rabs_zero_iff: "((λx. ¦f x¦) ⤏ (0::real)) F ⟷ (f ⤏ 0) F"
by (fold real_norm_def) (rule tendsto_norm_zero_iff)
subsection ‹Topological Monoid›
class topological_monoid_add = topological_space + monoid_add +
assumes tendsto_add_Pair: "LIM x (nhds a ×⇩F nhds b). fst x + snd x :> nhds (a + b)"
class topological_comm_monoid_add = topological_monoid_add + comm_monoid_add
lemma tendsto_add [tendsto_intros]:
fixes a b :: "'a::topological_monoid_add"
shows "(f ⤏ a) F ⟹ (g ⤏ b) F ⟹ ((λx. f x + g x) ⤏ a + b) F"
using filterlim_compose[OF tendsto_add_Pair, of "λx. (f x, g x)" a b F]
by (simp add: nhds_prod[symmetric] tendsto_Pair)
lemma continuous_add [continuous_intros]:
fixes f g :: "_ ⇒ 'b::topological_monoid_add"
shows "continuous F f ⟹ continuous F g ⟹ continuous F (λx. f x + g x)"
unfolding continuous_def by (rule tendsto_add)
lemma continuous_on_add [continuous_intros]:
fixes f g :: "_ ⇒ 'b::topological_monoid_add"
shows "continuous_on s f ⟹ continuous_on s g ⟹ continuous_on s (λx. f x + g x)"
unfolding continuous_on_def by (auto intro: tendsto_add)
lemma tendsto_add_zero:
fixes f g :: "_ ⇒ 'b::topological_monoid_add"
shows "(f ⤏ 0) F ⟹ (g ⤏ 0) F ⟹ ((λx. f x + g x) ⤏ 0) F"
by (drule (1) tendsto_add) simp
lemma tendsto_sum [tendsto_intros]:
fixes f :: "'a ⇒ 'b ⇒ 'c::topological_comm_monoid_add"
shows "(⋀i. i ∈ I ⟹ (f i ⤏ a i) F) ⟹ ((λx. ∑i∈I. f i x) ⤏ (∑i∈I. a i)) F"
by (induct I rule: infinite_finite_induct) (simp_all add: tendsto_add)
lemma tendsto_null_sum:
fixes f :: "'a ⇒ 'b ⇒ 'c::topological_comm_monoid_add"
assumes "⋀i. i ∈ I ⟹ ((λx. f x i) ⤏ 0) F"
shows "((λi. sum (f i) I) ⤏ 0) F"
using tendsto_sum [of I "λx y. f y x" "λx. 0"] assms by simp
lemma continuous_sum [continuous_intros]:
fixes f :: "'a ⇒ 'b::t2_space ⇒ 'c::topological_comm_monoid_add"
shows "(⋀i. i ∈ I ⟹ continuous F (f i)) ⟹ continuous F (λx. ∑i∈I. f i x)"
unfolding continuous_def by (rule tendsto_sum)
lemma continuous_on_sum [continuous_intros]:
fixes f :: "'a ⇒ 'b::topological_space ⇒ 'c::topological_comm_monoid_add"
shows "(⋀i. i ∈ I ⟹ continuous_on S (f i)) ⟹ continuous_on S (λx. ∑i∈I. f i x)"
unfolding continuous_on_def by (auto intro: tendsto_sum)
instance nat :: topological_comm_monoid_add
by standard
(simp add: nhds_discrete principal_prod_principal filterlim_principal eventually_principal)
instance int :: topological_comm_monoid_add
by standard
(simp add: nhds_discrete principal_prod_principal filterlim_principal eventually_principal)
subsubsection ‹Topological group›
class topological_group_add = topological_monoid_add + group_add +
assumes tendsto_uminus_nhds: "(uminus ⤏ - a) (nhds a)"
begin
lemma tendsto_minus [tendsto_intros]: "(f ⤏ a) F ⟹ ((λx. - f x) ⤏ - a) F"
by (rule filterlim_compose[OF tendsto_uminus_nhds])
end
class topological_ab_group_add = topological_group_add + ab_group_add
instance topological_ab_group_add < topological_comm_monoid_add ..
lemma continuous_minus [continuous_intros]: "continuous F f ⟹ continuous F (λx. - f x)"
for f :: "'a::t2_space ⇒ 'b::topological_group_add"
unfolding continuous_def by (rule tendsto_minus)
lemma continuous_on_minus [continuous_intros]: "continuous_on s f ⟹ continuous_on s (λx. - f x)"
for f :: "_ ⇒ 'b::topological_group_add"
unfolding continuous_on_def by (auto intro: tendsto_minus)
lemma tendsto_minus_cancel: "((λx. - f x) ⤏ - a) F ⟹ (f ⤏ a) F"
for a :: "'a::topological_group_add"
by (drule tendsto_minus) simp
lemma tendsto_minus_cancel_left:
"(f ⤏ - (y::_::topological_group_add)) F ⟷ ((λx. - f x) ⤏ y) F"
using tendsto_minus_cancel[of f "- y" F] tendsto_minus[of f "- y" F]
by auto
lemma tendsto_diff [tendsto_intros]:
fixes a b :: "'a::topological_group_add"
shows "(f ⤏ a) F ⟹ (g ⤏ b) F ⟹ ((λx. f x - g x) ⤏ a - b) F"
using tendsto_add [of f a F "λx. - g x" "- b"] by (simp add: tendsto_minus)
lemma continuous_diff [continuous_intros]:
fixes f g :: "'a::t2_space ⇒ 'b::topological_group_add"
shows "continuous F f ⟹ continuous F g ⟹ continuous F (λx. f x - g x)"
unfolding continuous_def by (rule tendsto_diff)
lemma continuous_on_diff [continuous_intros]:
fixes f g :: "_ ⇒ 'b::topological_group_add"
shows "continuous_on s f ⟹ continuous_on s g ⟹ continuous_on s (λx. f x - g x)"
unfolding continuous_on_def by (auto intro: tendsto_diff)
lemma continuous_on_op_minus: "continuous_on (s::'a::topological_group_add set) ((-) x)"
by (rule continuous_intros | simp)+
instance real_normed_vector < topological_ab_group_add
proof
fix a b :: 'a
show "((λx. fst x + snd x) ⤏ a + b) (nhds a ×⇩F nhds b)"
unfolding tendsto_Zfun_iff add_diff_add
using tendsto_fst[OF filterlim_ident, of "(a,b)"] tendsto_snd[OF filterlim_ident, of "(a,b)"]
by (intro Zfun_add)
(auto simp: tendsto_Zfun_iff[symmetric] nhds_prod[symmetric] intro!: tendsto_fst)
show "(uminus ⤏ - a) (nhds a)"
unfolding tendsto_Zfun_iff minus_diff_minus
using filterlim_ident[of "nhds a"]
by (intro Zfun_minus) (simp add: tendsto_Zfun_iff)
qed
lemmas real_tendsto_sandwich = tendsto_sandwich[where 'a=real]
subsubsection ‹Linear operators and multiplication›
lemma linear_times [simp]: "linear (λx. c * x)"
for c :: "'a::real_algebra"
by (auto simp: linearI distrib_left)
lemma (in bounded_linear) tendsto: "(g ⤏ a) F ⟹ ((λx. f (g x)) ⤏ f a) F"
by (simp only: tendsto_Zfun_iff diff [symmetric] Zfun)
lemma (in bounded_linear) continuous: "continuous F g ⟹ continuous F (λx. f (g x))"
using tendsto[of g _ F] by (auto simp: continuous_def)
lemma (in bounded_linear) continuous_on: "continuous_on s g ⟹ continuous_on s (λx. f (g x))"
using tendsto[of g] by (auto simp: continuous_on_def)
lemma (in bounded_linear) tendsto_zero: "(g ⤏ 0) F ⟹ ((λx. f (g x)) ⤏ 0) F"
by (drule tendsto) (simp only: zero)
lemma (in bounded_bilinear) tendsto:
"(f ⤏ a) F ⟹ (g ⤏ b) F ⟹ ((λx. f x ** g x) ⤏ a ** b) F"
by (simp only: tendsto_Zfun_iff prod_diff_prod Zfun_add Zfun Zfun_left Zfun_right)
lemma (in bounded_bilinear) continuous:
"continuous F f ⟹ continuous F g ⟹ continuous F (λx. f x ** g x)"
using tendsto[of f _ F g] by (auto simp: continuous_def)
lemma (in bounded_bilinear) continuous_on:
"continuous_on s f ⟹ continuous_on s g ⟹ continuous_on s (λx. f x ** g x)"
using tendsto[of f _ _ g] by (auto simp: continuous_on_def)
lemma (in bounded_bilinear) tendsto_zero:
assumes f: "(f ⤏ 0) F"
and g: "(g ⤏ 0) F"
shows "((λx. f x ** g x) ⤏ 0) F"
using tendsto [OF f g] by (simp add: zero_left)
lemma (in bounded_bilinear) tendsto_left_zero:
"(f ⤏ 0) F ⟹ ((λx. f x ** c) ⤏ 0) F"
by (rule bounded_linear.tendsto_zero [OF bounded_linear_left])
lemma (in bounded_bilinear) tendsto_right_zero:
"(f ⤏ 0) F ⟹ ((λx. c ** f x) ⤏ 0) F"
by (rule bounded_linear.tendsto_zero [OF bounded_linear_right])
lemmas tendsto_of_real [tendsto_intros] =
bounded_linear.tendsto [OF bounded_linear_of_real]
lemmas tendsto_scaleR [tendsto_intros] =
bounded_bilinear.tendsto [OF bounded_bilinear_scaleR]
text‹Analogous type class for multiplication›
class topological_semigroup_mult = topological_space + semigroup_mult +
assumes tendsto_mult_Pair: "LIM x (nhds a ×⇩F nhds b). fst x * snd x :> nhds (a * b)"
instance real_normed_algebra < topological_semigroup_mult
proof
fix a b :: 'a
show "((λx. fst x * snd x) ⤏ a * b) (nhds a ×⇩F nhds b)"
unfolding nhds_prod[symmetric]
using tendsto_fst[OF filterlim_ident, of "(a,b)"] tendsto_snd[OF filterlim_ident, of "(a,b)"]
by (simp add: bounded_bilinear.tendsto [OF bounded_bilinear_mult])
qed
lemma tendsto_mult [tendsto_intros]:
fixes a b :: "'a::topological_semigroup_mult"
shows "(f ⤏ a) F ⟹ (g ⤏ b) F ⟹ ((λx. f x * g x) ⤏ a * b) F"
using filterlim_compose[OF tendsto_mult_Pair, of "λx. (f x, g x)" a b F]
by (simp add: nhds_prod[symmetric] tendsto_Pair)
lemma tendsto_mult_left: "(f ⤏ l) F ⟹ ((λx. c * (f x)) ⤏ c * l) F"
for c :: "'a::topological_semigroup_mult"
by (rule tendsto_mult [OF tendsto_const])
lemma tendsto_mult_right: "(f ⤏ l) F ⟹ ((λx. (f x) * c) ⤏ l * c) F"
for c :: "'a::topological_semigroup_mult"
by (rule tendsto_mult [OF _ tendsto_const])
lemma tendsto_mult_left_iff [simp]:
"c ≠ 0 ⟹ tendsto(λx. c * f x) (c * l) F ⟷ tendsto f l F" for c :: "'a::{topological_semigroup_mult,field}"
by (auto simp: tendsto_mult_left dest: tendsto_mult_left [where c = "1/c"])
lemma tendsto_mult_right_iff [simp]:
"c ≠ 0 ⟹ tendsto(λx. f x * c) (l * c) F ⟷ tendsto f l F" for c :: "'a::{topological_semigroup_mult,field}"
by (auto simp: tendsto_mult_right dest: tendsto_mult_left [where c = "1/c"])
lemma tendsto_zero_mult_left_iff [simp]:
fixes c::"'a::{topological_semigroup_mult,field}" assumes "c ≠ 0" shows "(λn. c * a n)⇢ 0 ⟷ a ⇢ 0"
using assms tendsto_mult_left tendsto_mult_left_iff by fastforce
lemma tendsto_zero_mult_right_iff [simp]:
fixes c::"'a::{topological_semigroup_mult,field}" assumes "c ≠ 0" shows "(λn. a n * c)⇢ 0 ⟷ a ⇢ 0"
using assms tendsto_mult_right tendsto_mult_right_iff by fastforce
lemma tendsto_zero_divide_iff [simp]:
fixes c::"'a::{topological_semigroup_mult,field}" assumes "c ≠ 0" shows "(λn. a n / c)⇢ 0 ⟷ a ⇢ 0"
using tendsto_zero_mult_right_iff [of "1/c" a] assms by (simp add: field_simps)
lemma lim_const_over_n [tendsto_intros]:
fixes a :: "'a::real_normed_field"
shows "(λn. a / of_nat n) ⇢ 0"
using tendsto_mult [OF tendsto_const [of a] lim_1_over_n] by simp
lemmas continuous_of_real [continuous_intros] =
bounded_linear.continuous [OF bounded_linear_of_real]
lemmas continuous_scaleR [continuous_intros] =
bounded_bilinear.continuous [OF bounded_bilinear_scaleR]
lemmas continuous_mult [continuous_intros] =
bounded_bilinear.continuous [OF bounded_bilinear_mult]
lemmas continuous_on_of_real [continuous_intros] =
bounded_linear.continuous_on [OF bounded_linear_of_real]
lemmas continuous_on_scaleR [continuous_intros] =
bounded_bilinear.continuous_on [OF bounded_bilinear_scaleR]
lemmas continuous_on_mult [continuous_intros] =
bounded_bilinear.continuous_on [OF bounded_bilinear_mult]
lemmas tendsto_mult_zero =
bounded_bilinear.tendsto_zero [OF bounded_bilinear_mult]
lemmas tendsto_mult_left_zero =
bounded_bilinear.tendsto_left_zero [OF bounded_bilinear_mult]
lemmas tendsto_mult_right_zero =
bounded_bilinear.tendsto_right_zero [OF bounded_bilinear_mult]
lemma continuous_mult_left:
fixes c::"'a::real_normed_algebra"
shows "continuous F f ⟹ continuous F (λx. c * f x)"
by (rule continuous_mult [OF continuous_const])
lemma continuous_mult_right:
fixes c::"'a::real_normed_algebra"
shows "continuous F f ⟹ continuous F (λx. f x * c)"
by (rule continuous_mult [OF _ continuous_const])
lemma continuous_on_mult_left:
fixes c::"'a::real_normed_algebra"
shows "continuous_on s f ⟹ continuous_on s (λx. c * f x)"
by (rule continuous_on_mult [OF continuous_on_const])
lemma continuous_on_mult_right:
fixes c::"'a::real_normed_algebra"
shows "continuous_on s f ⟹ continuous_on s (λx. f x * c)"
by (rule continuous_on_mult [OF _ continuous_on_const])
lemma continuous_on_mult_const [simp]:
fixes c::"'a::real_normed_algebra"
shows "continuous_on s ((*) c)"
by (intro continuous_on_mult_left continuous_on_id)
lemma tendsto_divide_zero:
fixes c :: "'a::real_normed_field"
shows "(f ⤏ 0) F ⟹ ((λx. f x / c) ⤏ 0) F"
by (cases "c=0") (simp_all add: divide_inverse tendsto_mult_left_zero)
lemma tendsto_power [tendsto_intros]: "(f ⤏ a) F ⟹ ((λx. f x ^ n) ⤏ a ^ n) F"
for f :: "'a ⇒ 'b::{power,real_normed_algebra}"
by (induct n) (simp_all add: tendsto_mult)
lemma tendsto_null_power: "⟦(f ⤏ 0) F; 0 < n⟧ ⟹ ((λx. f x ^ n) ⤏ 0) F"
for f :: "'a ⇒ 'b::{power,real_normed_algebra_1}"
using tendsto_power [of f 0 F n] by (simp add: power_0_left)
lemma continuous_power [continuous_intros]: "continuous F f ⟹ continuous F (λx. (f x)^n)"
for f :: "'a::t2_space ⇒ 'b::{power,real_normed_algebra}"
unfolding continuous_def by (rule tendsto_power)
lemma continuous_on_power [continuous_intros]:
fixes f :: "_ ⇒ 'b::{power,real_normed_algebra}"
shows "continuous_on s f ⟹ continuous_on s (λx. (f x)^n)"
unfolding continuous_on_def by (auto intro: tendsto_power)
lemma tendsto_prod [tendsto_intros]:
fixes f :: "'a ⇒ 'b ⇒ 'c::{real_normed_algebra,comm_ring_1}"
shows "(⋀i. i ∈ S ⟹ (f i ⤏ L i) F) ⟹ ((λx. ∏i∈S. f i x) ⤏ (∏i∈S. L i)) F"
by (induct S rule: infinite_finite_induct) (simp_all add: tendsto_mult)
lemma continuous_prod [continuous_intros]:
fixes f :: "'a ⇒ 'b::t2_space ⇒ 'c::{real_normed_algebra,comm_ring_1}"
shows "(⋀i. i ∈ S ⟹ continuous F (f i)) ⟹ continuous F (λx. ∏i∈S. f i x)"
unfolding continuous_def by (rule tendsto_prod)
lemma continuous_on_prod [continuous_intros]:
fixes f :: "'a ⇒ _ ⇒ 'c::{real_normed_algebra,comm_ring_1}"
shows "(⋀i. i ∈ S ⟹ continuous_on s (f i)) ⟹ continuous_on s (λx. ∏i∈S. f i x)"
unfolding continuous_on_def by (auto intro: tendsto_prod)
lemma tendsto_of_real_iff:
"((λx. of_real (f x) :: 'a::real_normed_div_algebra) ⤏ of_real c) F ⟷ (f ⤏ c) F"
unfolding tendsto_iff by simp
lemma tendsto_add_const_iff:
"((λx. c + f x :: 'a::topological_group_add) ⤏ c + d) F ⟷ (f ⤏ d) F"
using tendsto_add[OF tendsto_const[of c], of f d]
and tendsto_add[OF tendsto_const[of "-c"], of "λx. c + f x" "c + d"] by auto
class topological_monoid_mult = topological_semigroup_mult + monoid_mult
class topological_comm_monoid_mult = topological_monoid_mult + comm_monoid_mult
lemma tendsto_power_strong [tendsto_intros]:
fixes f :: "_ ⇒ 'b :: topological_monoid_mult"
assumes "(f ⤏ a) F" "(g ⤏ b) F"
shows "((λx. f x ^ g x) ⤏ a ^ b) F"
proof -
have "((λx. f x ^ b) ⤏ a ^ b) F"
by (induction b) (auto intro: tendsto_intros assms)
also from assms(2) have "eventually (λx. g x = b) F"
by (simp add: nhds_discrete filterlim_principal)
hence "eventually (λx. f x ^ b = f x ^ g x) F"
by eventually_elim simp
hence "((λx. f x ^ b) ⤏ a ^ b) F ⟷ ((λx. f x ^ g x) ⤏ a ^ b) F"
by (intro filterlim_cong refl)
finally show ?thesis .
qed
lemma continuous_mult' [continuous_intros]:
fixes f g :: "_ ⇒ 'b::topological_semigroup_mult"
shows "continuous F f ⟹ continuous F g ⟹ continuous F (λx. f x * g x)"
unfolding continuous_def by (rule tendsto_mult)
lemma continuous_power' [continuous_intros]:
fixes f :: "_ ⇒ 'b::topological_monoid_mult"
shows "continuous F f ⟹ continuous F g ⟹ continuous F (λx. f x ^ g x)"
unfolding continuous_def by (rule tendsto_power_strong) auto
lemma continuous_on_mult' [continuous_intros]:
fixes f g :: "_ ⇒ 'b::topological_semigroup_mult"
shows "continuous_on A f ⟹ continuous_on A g ⟹ continuous_on A (λx. f x * g x)"
unfolding continuous_on_def by (auto intro: tendsto_mult)
lemma continuous_on_power' [continuous_intros]:
fixes f :: "_ ⇒ 'b::topological_monoid_mult"
shows "continuous_on A f ⟹ continuous_on A g ⟹ continuous_on A (λx. f x ^ g x)"
unfolding continuous_on_def by (auto intro: tendsto_power_strong)
lemma tendsto_mult_one:
fixes f g :: "_ ⇒ 'b::topological_monoid_mult"
shows "(f ⤏ 1) F ⟹ (g ⤏ 1) F ⟹ ((λx. f x * g x) ⤏ 1) F"
by (drule (1) tendsto_mult) simp
lemma tendsto_prod' [tendsto_intros]:
fixes f :: "'a ⇒ 'b ⇒ 'c::topological_comm_monoid_mult"
shows "(⋀i. i ∈ I ⟹ (f i ⤏ a i) F) ⟹ ((λx. ∏i∈I. f i x) ⤏ (∏i∈I. a i)) F"
by (induct I rule: infinite_finite_induct) (simp_all add: tendsto_mult)
lemma tendsto_one_prod':
fixes f :: "'a ⇒ 'b ⇒ 'c::topological_comm_monoid_mult"
assumes "⋀i. i ∈ I ⟹ ((λx. f x i) ⤏ 1) F"
shows "((λi. prod (f i) I) ⤏ 1) F"
using tendsto_prod' [of I "λx y. f y x" "λx. 1"] assms by simp
lemma LIMSEQ_prod_0:
fixes f :: "nat ⇒ 'a::{semidom,topological_space}"
assumes "f i = 0"
shows "(λn. prod f {..n}) ⇢ 0"
proof (subst tendsto_cong)
show "∀⇩F n in sequentially. prod f {..n} = 0"
using assms eventually_at_top_linorder by auto
qed auto
lemma LIMSEQ_prod_nonneg:
fixes f :: "nat ⇒ 'a::{linordered_semidom,linorder_topology}"
assumes 0: "⋀n. 0 ≤ f n" and a: "(λn. prod f {..n}) ⇢ a"
shows "a ≥ 0"
by (simp add: "0" prod_nonneg LIMSEQ_le_const [OF a])
lemma continuous_prod' [continuous_intros]:
fixes f :: "'a ⇒ 'b::t2_space ⇒ 'c::topological_comm_monoid_mult"
shows "(⋀i. i ∈ I ⟹ continuous F (f i)) ⟹ continuous F (λx. ∏i∈I. f i x)"
unfolding continuous_def by (rule tendsto_prod')
lemma continuous_on_prod' [continuous_intros]:
fixes f :: "'a ⇒ 'b::topological_space ⇒ 'c::topological_comm_monoid_mult"
shows "(⋀i. i ∈ I ⟹ continuous_on S (f i)) ⟹ continuous_on S (λx. ∏i∈I. f i x)"
unfolding continuous_on_def by (auto intro: tendsto_prod')
instance nat :: topological_comm_monoid_mult
by standard
(simp add: nhds_discrete principal_prod_principal filterlim_principal eventually_principal)
instance int :: topological_comm_monoid_mult
by standard
(simp add: nhds_discrete principal_prod_principal filterlim_principal eventually_principal)
class comm_real_normed_algebra_1 = real_normed_algebra_1 + comm_monoid_mult
context real_normed_field
begin
subclass comm_real_normed_algebra_1
proof
from norm_mult[of "1 :: 'a" 1] show "norm 1 = 1" by simp
qed (simp_all add: norm_mult)
end
subsubsection ‹Inverse and division›
lemma (in bounded_bilinear) Zfun_prod_Bfun:
assumes f: "Zfun f F"
and g: "Bfun g F"
shows "Zfun (λx. f x ** g x) F"
proof -
obtain K where K: "0 ≤ K"
and norm_le: "⋀x y. norm (x ** y) ≤ norm x * norm y * K"
using nonneg_bounded by blast
obtain B where B: "0 < B"
and norm_g: "eventually (λx. norm (g x) ≤ B) F"
using g by (rule BfunE)
have "eventually (λx. norm (f x ** g x) ≤ norm (f x) * (B * K)) F"
using norm_g proof eventually_elim
case (elim x)
have "norm (f x ** g x) ≤ norm (f x) * norm (g x) * K"
by (rule norm_le)
also have "… ≤ norm (f x) * B * K"
by (intro mult_mono' order_refl norm_g norm_ge_zero mult_nonneg_nonneg K elim)
also have "… = norm (f x) * (B * K)"
by (rule mult.assoc)
finally show "norm (f x ** g x) ≤ norm (f x) * (B * K)" .
qed
with f show ?thesis
by (rule Zfun_imp_Zfun)
qed
lemma (in bounded_bilinear) Bfun_prod_Zfun:
assumes f: "Bfun f F"
and g: "Zfun g F"
shows "Zfun (λx. f x ** g x) F"
using flip g f by (rule bounded_bilinear.Zfun_prod_Bfun)
lemma Bfun_inverse:
fixes a :: "'a::real_normed_div_algebra"
assumes f: "(f ⤏ a) F"
assumes a: "a ≠ 0"
shows "Bfun (λx. inverse (f x)) F"
proof -
from a have "0 < norm a" by simp
then have "∃r>0. r < norm a" by (rule dense)
then obtain r where r1: "0 < r" and r2: "r < norm a"
by blast
have "eventually (λx. dist (f x) a < r) F"
using tendstoD [OF f r1] by blast
then have "eventually (λx. norm (inverse (f x)) ≤ inverse (norm a - r)) F"
proof eventually_elim
case (elim x)
then have 1: "norm (f x - a) < r"
by (simp add: dist_norm)
then have 2: "f x ≠ 0" using r2 by auto
then have "norm (inverse (f x)) = inverse (norm (f x))"
by (rule nonzero_norm_inverse)
also have "… ≤ inverse (norm a - r)"
proof (rule le_imp_inverse_le)
show "0 < norm a - r"
using r2 by simp
have "norm a - norm (f x) ≤ norm (a - f x)"
by (rule norm_triangle_ineq2)
also have "… = norm (f x - a)"
by (rule norm_minus_commute)
also have "… < r" using 1 .
finally show "norm a - r ≤ norm (f x)"
by simp
qed
finally show "norm (inverse (f x)) ≤ inverse (norm a - r)" .
qed
then show ?thesis by (rule BfunI)
qed
lemma tendsto_inverse [tendsto_intros]:
fixes a :: "'a::real_normed_div_algebra"
assumes f: "(f ⤏ a) F"
and a: "a ≠ 0"
shows "((λx. inverse (f x)) ⤏ inverse a) F"
proof -
from a have "0 < norm a" by simp
with f have "eventually (λx. dist (f x) a < norm a) F"
by (rule tendstoD)
then have "eventually (λx. f x ≠ 0) F"
unfolding dist_norm by (auto elim!: eventually_mono)
with a have "eventually (λx. inverse (f x) - inverse a =
- (inverse (f x) * (f x - a) * inverse a)) F"
by (auto elim!: eventually_mono simp: inverse_diff_inverse)
moreover have "Zfun (λx. - (inverse (f x) * (f x - a) * inverse a)) F"
by (intro Zfun_minus Zfun_mult_left
bounded_bilinear.Bfun_prod_Zfun [OF bounded_bilinear_mult]
Bfun_inverse [OF f a] f [unfolded tendsto_Zfun_iff])
ultimately show ?thesis
unfolding tendsto_Zfun_iff by (rule Zfun_ssubst)
qed
lemma continuous_inverse:
fixes f :: "'a::t2_space ⇒ 'b::real_normed_div_algebra"
assumes "continuous F f"
and "f (Lim F (λx. x)) ≠ 0"
shows "continuous F (λx. inverse (f x))"
using assms unfolding continuous_def by (rule tendsto_inverse)
lemma continuous_at_within_inverse[continuous_intros]:
fixes f :: "'a::t2_space ⇒ 'b::real_normed_div_algebra"
assumes "continuous (at a within s) f"
and "f a ≠ 0"
shows "continuous (at a within s) (λx. inverse (f x))"
using assms unfolding continuous_within by (rule tendsto_inverse)
lemma continuous_on_inverse[continuous_intros]:
fixes f :: "'a::topological_space ⇒ 'b::real_normed_div_algebra"
assumes "continuous_on s f"
and "∀x∈s. f x ≠ 0"
shows "continuous_on s (λx. inverse (f x))"
using assms unfolding continuous_on_def by (blast intro: tendsto_inverse)
lemma tendsto_divide [tendsto_intros]:
fixes a b :: "'a::real_normed_field"
shows "(f ⤏ a) F ⟹ (g ⤏ b) F ⟹ b ≠ 0 ⟹ ((λx. f x / g x) ⤏ a / b) F"
by (simp add: tendsto_mult tendsto_inverse divide_inverse)
lemma continuous_divide:
fixes f g :: "'a::t2_space ⇒ 'b::real_normed_field"
assumes "continuous F f"
and "continuous F g"
and "g (Lim F (λx. x)) ≠ 0"
shows "continuous F (λx. (f x) / (g x))"
using assms unfolding continuous_def by (rule tendsto_divide)
lemma continuous_at_within_divide[continuous_intros]:
fixes f g :: "'a::t2_space ⇒ 'b::real_normed_field"
assumes "continuous (at a within s) f" "continuous (at a within s) g"
and "g a ≠ 0"
shows "continuous (at a within s) (λx. (f x) / (g x))"
using assms unfolding continuous_within by (rule tendsto_divide)
lemma isCont_divide[continuous_intros, simp]:
fixes f g :: "'a::t2_space ⇒ 'b::real_normed_field"
assumes "isCont f a" "isCont g a" "g a ≠ 0"
shows "isCont (λx. (f x) / g x) a"
using assms unfolding continuous_at by (rule tendsto_divide)
lemma continuous_on_divide[continuous_intros]:
fixes f :: "'a::topological_space ⇒ 'b::real_normed_field"
assumes "continuous_on s f" "continuous_on s g"
and "∀x∈s. g x ≠ 0"
shows "continuous_on s (λx. (f x) / (g x))"
using assms unfolding continuous_on_def by (blast intro: tendsto_divide)
lemma tendsto_power_int [tendsto_intros]:
fixes a :: "'a::real_normed_div_algebra"
assumes f: "(f ⤏ a) F"
and a: "a ≠ 0"
shows "((λx. power_int (f x) n) ⤏ power_int a n) F"
using assms by (cases n rule: int_cases4) (auto intro!: tendsto_intros simp: power_int_minus)
lemma continuous_power_int:
fixes f :: "'a::t2_space ⇒ 'b::real_normed_div_algebra"
assumes "continuous F f"
and "f (Lim F (λx. x)) ≠ 0"
shows "continuous F (λx. power_int (f x) n)"
using assms unfolding continuous_def by (rule tendsto_power_int)
lemma continuous_at_within_power_int[continuous_intros]:
fixes f :: "'a::t2_space ⇒ 'b::real_normed_div_algebra"
assumes "continuous (at a within s) f"
and "f a ≠ 0"
shows "continuous (at a within s) (λx. power_int (f x) n)"
using assms unfolding continuous_within by (rule tendsto_power_int)
lemma continuous_on_power_int [continuous_intros]:
fixes f :: "'a::topological_space ⇒ 'b::real_normed_div_algebra"
assumes "continuous_on s f" and "∀x∈s. f x ≠ 0"
shows "continuous_on s (λx. power_int (f x) n)"
using assms unfolding continuous_on_def by (blast intro: tendsto_power_int)
lemma tendsto_power_int' [tendsto_intros]:
fixes a :: "'a::real_normed_div_algebra"
assumes f: "(f ⤏ a) F"
and a: "a ≠ 0 ∨ n ≥ 0"
shows "((λx. power_int (f x) n) ⤏ power_int a n) F"
using assms by (cases n rule: int_cases4) (auto intro!: tendsto_intros simp: power_int_minus)
lemma tendsto_sgn [tendsto_intros]: "(f ⤏ l) F ⟹ l ≠ 0 ⟹ ((λx. sgn (f x)) ⤏ sgn l) F"
for l :: "'a::real_normed_vector"
unfolding sgn_div_norm by (simp add: tendsto_intros)
lemma continuous_sgn:
fixes f :: "'a::t2_space ⇒ 'b::real_normed_vector"
assumes "continuous F f"
and "f (Lim F (λx. x)) ≠ 0"
shows "continuous F (λx. sgn (f x))"
using assms unfolding continuous_def by (rule tendsto_sgn)
lemma continuous_at_within_sgn[continuous_intros]:
fixes f :: "'a::t2_space ⇒ 'b::real_normed_vector"
assumes "continuous (at a within s) f"
and "f a ≠ 0"
shows "continuous (at a within s) (λx. sgn (f x))"
using assms unfolding continuous_within by (rule tendsto_sgn)
lemma isCont_sgn[continuous_intros]:
fixes f :: "'a::t2_space ⇒ 'b::real_normed_vector"
assumes "isCont f a"
and "f a ≠ 0"
shows "isCont (λx. sgn (f x)) a"
using assms unfolding continuous_at by (rule tendsto_sgn)
lemma continuous_on_sgn[continuous_intros]:
fixes f :: "'a::topological_space ⇒ 'b::real_normed_vector"
assumes "continuous_on s f"
and "∀x∈s. f x ≠ 0"
shows "continuous_on s (λx. sgn (f x))"
using assms unfolding continuous_on_def by (blast intro: tendsto_sgn)
lemma filterlim_at_infinity:
fixes f :: "_ ⇒ 'a::real_normed_vector"
assumes "0 ≤ c"
shows "(LIM x F. f x :> at_infinity) ⟷ (∀r>c. eventually (λx. r ≤ norm (f x)) F)"
unfolding filterlim_iff eventually_at_infinity
proof safe
fix P :: "'a ⇒ bool"
fix b
assume *: "∀r>c. eventually (λx. r ≤ norm (f x)) F"
assume P: "∀x. b ≤ norm x ⟶ P x"
have "max b (c + 1) > c" by auto
with * have "eventually (λx. max b (c + 1) ≤ norm (f x)) F"
by auto
then show "eventually (λx. P (f x)) F"
proof eventually_elim
case (elim x)
with P show "P (f x)" by auto
qed
qed force
lemma filterlim_at_infinity_imp_norm_at_top:
fixes F
assumes "filterlim f at_infinity F"
shows "filterlim (λx. norm (f x)) at_top F"
proof -
{
fix r :: real
have "∀⇩F x in F. r ≤ norm (f x)" using filterlim_at_infinity[of 0 f F] assms
by (cases "r > 0")
(auto simp: not_less intro: always_eventually order.trans[OF _ norm_ge_zero])
}
thus ?thesis by (auto simp: filterlim_at_top)
qed
lemma filterlim_norm_at_top_imp_at_infinity:
fixes F
assumes "filterlim (λx. norm (f x)) at_top F"
shows "filterlim f at_infinity F"
using filterlim_at_infinity[of 0 f F] assms by (auto simp: filterlim_at_top)
lemma filterlim_norm_at_top: "filterlim norm at_top at_infinity"
by (rule filterlim_at_infinity_imp_norm_at_top) (rule filterlim_ident)
lemma filterlim_at_infinity_conv_norm_at_top:
"filterlim f at_infinity G ⟷ filterlim (λx. norm (f x)) at_top G"
by (auto simp: filterlim_at_infinity[OF order.refl] filterlim_at_top_gt[of _ _ 0])
lemma eventually_not_equal_at_infinity:
"eventually (λx. x ≠ (a :: 'a :: {real_normed_vector})) at_infinity"
proof -
from filterlim_norm_at_top[where 'a = 'a]
have "∀⇩F x in at_infinity. norm a < norm (x::'a)" by (auto simp: filterlim_at_top_dense)
thus ?thesis by eventually_elim auto
qed
lemma filterlim_int_of_nat_at_topD:
fixes F
assumes "filterlim (λx. f (int x)) F at_top"
shows "filterlim f F at_top"
proof -
have "filterlim (λx. f (int (nat x))) F at_top"
by (rule filterlim_compose[OF assms filterlim_nat_sequentially])
also have "?this ⟷ filterlim f F at_top"
by (intro filterlim_cong refl eventually_mono [OF eventually_ge_at_top[of "0::int"]]) auto
finally show ?thesis .
qed
lemma filterlim_int_sequentially [tendsto_intros]:
"filterlim int at_top sequentially"
unfolding filterlim_at_top
proof
fix C :: int
show "eventually (λn. int n ≥ C) at_top"
using eventually_ge_at_top[of "nat ⌈C⌉"] by eventually_elim linarith
qed
lemma filterlim_real_of_int_at_top [tendsto_intros]:
"filterlim real_of_int at_top at_top"
unfolding filterlim_at_top
proof
fix C :: real
show "eventually (λn. real_of_int n ≥ C) at_top"
using eventually_ge_at_top[of "⌈C⌉"] by eventually_elim linarith
qed
lemma filterlim_abs_real: "filterlim (abs::real ⇒ real) at_top at_top"
proof (subst filterlim_cong[OF refl refl])
from eventually_ge_at_top[of "0::real"] show "eventually (λx::real. ¦x¦ = x) at_top"
by eventually_elim simp
qed (simp_all add: filterlim_ident)
lemma filterlim_of_real_at_infinity [tendsto_intros]:
"filterlim (of_real :: real ⇒ 'a :: real_normed_algebra_1) at_infinity at_top"
by (intro filterlim_norm_at_top_imp_at_infinity) (auto simp: filterlim_abs_real)
lemma not_tendsto_and_filterlim_at_infinity:
fixes c :: "'a::real_normed_vector"
assumes "F ≠ bot"
and "(f ⤏ c) F"
and "filterlim f at_infinity F"
shows False
proof -
from tendstoD[OF assms(2), of "1/2"]
have "eventually (λx. dist (f x) c < 1/2) F"
by simp
moreover
from filterlim_at_infinity[of "norm c" f F] assms(3)
have "eventually (λx. norm (f x) ≥ norm c + 1) F" by simp
ultimately have "eventually (λx. False) F"
proof eventually_elim
fix x
assume A: "dist (f x) c < 1/2"
assume "norm (f x) ≥ norm c + 1"
also have "norm (f x) = dist (f x) 0" by simp
also have "… ≤ dist (f x) c + dist c 0" by (rule dist_triangle)
finally show False using A by simp
qed
with assms show False by simp
qed
lemma filterlim_at_infinity_imp_not_convergent:
assumes "filterlim f at_infinity sequentially"
shows "¬ convergent f"
by (rule notI, rule not_tendsto_and_filterlim_at_infinity[OF _ _ assms])
(simp_all add: convergent_LIMSEQ_iff)
lemma filterlim_at_infinity_imp_eventually_ne:
assumes "filterlim f at_infinity F"
shows "eventually (λz. f z ≠ c) F"
proof -
have "norm c + 1 > 0"
by (intro add_nonneg_pos) simp_all
with filterlim_at_infinity[OF order.refl, of f F] assms
have "eventually (λz. norm (f z) ≥ norm c + 1) F"
by blast
then show ?thesis
by eventually_elim auto
qed
lemma tendsto_of_nat [tendsto_intros]:
"filterlim (of_nat :: nat ⇒ 'a::real_normed_algebra_1) at_infinity sequentially"
proof (subst filterlim_at_infinity[OF order.refl], intro allI impI)
fix r :: real
assume r: "r > 0"
define n where "n = nat ⌈r⌉"
from r have n: "∀m≥n. of_nat m ≥ r"
unfolding n_def by linarith
from eventually_ge_at_top[of n] show "eventually (λm. norm (of_nat m :: 'a) ≥ r) sequentially"
by eventually_elim (use n in simp_all)
qed
subsection ‹Relate \<^const>‹at›, \<^const>‹at_left› and \<^const>‹at_right››
text ‹
This lemmas are useful for conversion between \<^term>‹at x› to \<^term>‹at_left x› and
\<^term>‹at_right x› and also \<^term>‹at_right 0›.
›
lemmas filterlim_split_at_real = filterlim_split_at[where 'a=real]
lemma filtermap_nhds_shift: "filtermap (λx. x - d) (nhds a) = nhds (a - d)"
for a d :: "'a::real_normed_vector"
by (rule filtermap_fun_inverse[where g="λx. x + d"])
(auto intro!: tendsto_eq_intros filterlim_ident)
lemma filtermap_nhds_minus: "filtermap (λx. - x) (nhds a) = nhds (- a)"
for a :: "'a::real_normed_vector"
by (rule filtermap_fun_inverse[where g=uminus])
(auto intro!: tendsto_eq_intros filterlim_ident)
lemma filtermap_at_shift: "filtermap (λx. x - d) (at a) = at (a - d)"
for a d :: "'a::real_normed_vector"
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_shift[symmetric])
lemma filtermap_at_right_shift: "filtermap (λx. x - d) (at_right a) = at_right (a - d)"
for a d :: "real"
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_shift[symmetric])
lemma filterlim_shift:
fixes d :: "'a::real_normed_vector"
assumes "filterlim f F (at a)"
shows "filterlim (f ∘ (+) d) F (at (a - d))"
unfolding filterlim_iff
proof (intro strip)
fix P
assume "eventually P F"
then have "∀⇩F x in filtermap (λy. y - d) (at a). P (f (d + x))"
using assms by (force simp add: filterlim_iff eventually_filtermap)
then show "(∀⇩F x in at (a - d). P ((f ∘ (+) d) x))"
by (force simp add: filtermap_at_shift)
qed
lemma filterlim_shift_iff:
fixes d :: "'a::real_normed_vector"
shows "filterlim (f ∘ (+) d) F (at (a - d)) = filterlim f F (at a)" (is "?lhs = ?rhs")
proof
assume L: ?lhs show ?rhs
using filterlim_shift [OF L, of "-d"] by (simp add: filterlim_iff)
qed (metis filterlim_shift)
lemma at_right_to_0: "at_right a = filtermap (λx. x + a) (at_right 0)"
for a :: real
using filtermap_at_right_shift[of "-a" 0] by simp
lemma filterlim_at_right_to_0:
"filterlim f F (at_right a) ⟷ filterlim (λx. f (x + a)) F (at_right 0)"
for a :: real
unfolding filterlim_def filtermap_filtermap at_right_to_0[of a] ..
lemma eventually_at_right_to_0:
"eventually P (at_right a) ⟷ eventually (λx. P (x + a)) (at_right 0)"
for a :: real
unfolding at_right_to_0[of a] by (simp add: eventually_filtermap)
lemma at_to_0: "at a = filtermap (λx. x + a) (at 0)"
for a :: "'a::real_normed_vector"
using filtermap_at_shift[of "-a" 0] by simp
lemma filterlim_at_to_0:
"filterlim f F (at a) ⟷ filterlim (λx. f (x + a)) F (at 0)"
for a :: "'a::real_normed_vector"
unfolding filterlim_def filtermap_filtermap at_to_0[of a] ..
lemma eventually_at_to_0:
"eventually P (at a) ⟷ eventually (λx. P (x + a)) (at 0)"
for a :: "'a::real_normed_vector"
unfolding at_to_0[of a] by (simp add: eventually_filtermap)
lemma filtermap_at_minus: "filtermap (λx. - x) (at a) = at (- a)"
for a :: "'a::real_normed_vector"
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_minus[symmetric])
lemma at_left_minus: "at_left a = filtermap (λx. - x) (at_right (- a))"
for a :: real
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_minus[symmetric])
lemma at_right_minus: "at_right a = filtermap (λx. - x) (at_left (- a))"
for a :: real
by (simp add: filter_eq_iff eventually_filtermap eventually_at_filter filtermap_nhds_minus[symmetric])
lemma filterlim_at_left_to_right:
"filterlim f F (at_left a) ⟷ filterlim (λx. f (- x)) F (at_right (-a))"
for a :: real
unfolding filterlim_def filtermap_filtermap at_left_minus[of a] ..
lemma eventually_at_left_to_right:
"eventually P (at_left a) ⟷ eventually (λx. P (- x)) (at_right (-a))"
for a :: real
unfolding at_left_minus[of a] by (simp add: eventually_filtermap)
lemma filterlim_uminus_at_top_at_bot: "LIM x at_bot. - x :: real :> at_top"
unfolding filterlim_at_top eventually_at_bot_dense
by (metis leI minus_less_iff order_less_asym)
lemma filterlim_uminus_at_bot_at_top: "LIM x at_top. - x :: real :> at_bot"
unfolding filterlim_at_bot eventually_at_top_dense
by (metis leI less_minus_iff order_less_asym)
lemma at_bot_mirror :
shows "(at_bot::('a::{ordered_ab_group_add,linorder} filter)) = filtermap uminus at_top"
proof (rule filtermap_fun_inverse[symmetric])
show "filterlim uminus at_top (at_bot::'a filter)"
using eventually_at_bot_linorder filterlim_at_top le_minus_iff by force
show "filterlim uminus (at_bot::'a filter) at_top"
by (simp add: filterlim_at_bot minus_le_iff)
qed auto
lemma at_top_mirror :
shows "(at_top::('a::{ordered_ab_group_add,linorder} filter)) = filtermap uminus at_bot"
apply (subst at_bot_mirror)
by (auto simp: filtermap_filtermap)
lemma filterlim_at_top_mirror: "(LIM x at_top. f x :> F) ⟷ (LIM x at_bot. f (-x::real) :> F)"
unfolding filterlim_def at_top_mirror filtermap_filtermap ..
lemma filterlim_at_bot_mirror: "(LIM x at_bot. f x :> F) ⟷ (LIM x at_top. f (-x::real) :> F)"
unfolding filterlim_def at_bot_mirror filtermap_filtermap ..
lemma filterlim_uminus_at_top: "(LIM x F. f x :> at_top) ⟷ (LIM x F. - (f x) :: real :> at_bot)"
using filterlim_compose[OF filterlim_uminus_at_bot_at_top, of f F]
and filterlim_compose[OF filterlim_uminus_at_top_at_bot, of "λx. - f x" F]
by auto
lemma tendsto_at_botI_sequentially:
fixes f :: "real ⇒ 'b::first_countable_topology"
assumes *: "⋀X. filterlim X at_bot sequentially ⟹ (λn. f (X n)) ⇢ y"
shows "(f ⤏ y) at_bot"
unfolding filterlim_at_bot_mirror
proof (rule tendsto_at_topI_sequentially)
fix X :: "nat ⇒ real" assume "filterlim X at_top sequentially"
thus "(λn. f (-X n)) ⇢ y" by (intro *) (auto simp: filterlim_uminus_at_top)
qed
lemma filterlim_at_infinity_imp_filterlim_at_top:
assumes "filterlim (f :: 'a ⇒ real) at_infinity F"
assumes "eventually (λx. f x > 0) F"
shows "filterlim f at_top F"
proof -
from assms(2) have *: "eventually (λx. norm (f x) = f x) F" by eventually_elim simp
from assms(1) show ?thesis unfolding filterlim_at_infinity_conv_norm_at_top
by (subst (asm) filterlim_cong[OF refl refl *])
qed
lemma filterlim_at_infinity_imp_filterlim_at_bot:
assumes "filterlim (f :: 'a ⇒ real) at_infinity F"
assumes "eventually (λx. f x < 0) F"
shows "filterlim f at_bot F"
proof -
from assms(2) have *: "eventually (λx. norm (f x) = -f x) F" by eventually_elim simp
from assms(1) have "filterlim (λx. - f x) at_top F"
unfolding filterlim_at_infinity_conv_norm_at_top
by (subst (asm) filterlim_cong[OF refl refl *])
thus ?thesis by (simp add: filterlim_uminus_at_top)
qed
lemma filterlim_uminus_at_bot: "(LIM x F. f x :> at_bot) ⟷ (LIM x F. - (f x) :: real :> at_top)"
unfolding filterlim_uminus_at_top by simp
lemma filterlim_inverse_at_top_right: "LIM x at_right (0::real). inverse x :> at_top"
unfolding filterlim_at_top_gt[where c=0] eventually_at_filter
proof safe
fix Z :: real
assume [arith]: "0 < Z"
then have "eventually (λx. x < inverse Z) (nhds 0)"
by (auto simp: eventually_nhds_metric dist_real_def intro!: exI[of _ "¦inverse Z¦"])
then show "eventually (λx. x ≠ 0 ⟶ x ∈ {0<..} ⟶ Z ≤ inverse x) (nhds 0)"
by (auto elim!: eventually_mono simp: inverse_eq_divide field_simps)
qed
lemma tendsto_inverse_0:
fixes x :: "_ ⇒ 'a::real_normed_div_algebra"
shows "(inverse ⤏ (0::'a)) at_infinity"
unfolding tendsto_Zfun_iff diff_0_right Zfun_def eventually_at_infinity
proof safe
fix r :: real
assume "0 < r"
show "∃b. ∀x. b ≤ norm x ⟶ norm (inverse x :: 'a) < r"
proof (intro exI[of _ "inverse (r / 2)"] allI impI)
fix x :: 'a
from ‹0 < r› have "0 < inverse (r / 2)" by simp
also assume *: "inverse (r / 2) ≤ norm x"
finally show "norm (inverse x) < r"
using * ‹0 < r›
by (subst nonzero_norm_inverse) (simp_all add: inverse_eq_divide field_simps)
qed
qed
lemma tendsto_add_filterlim_at_infinity:
fixes c :: "'b::real_normed_vector"
and F :: "'a filter"
assumes "(f ⤏ c) F"
and "filterlim g at_infinity F"
shows "filterlim (λx. f x + g x) at_infinity F"
proof (subst filterlim_at_infinity[OF order_refl], safe)
fix r :: real
assume r: "r > 0"
from assms(1) have "((λx. norm (f x)) ⤏ norm c) F"
by (rule tendsto_norm)
then have "eventually (λx. norm (f x) < norm c + 1) F"
by (rule order_tendstoD) simp_all
moreover from r have "r + norm c + 1 > 0"
by (intro add_pos_nonneg) simp_all
with assms(2) have "eventually (λx. norm (g x) ≥ r + norm c + 1) F"
unfolding filterlim_at_infinity[OF order_refl]
by (elim allE[of _ "r + norm c + 1"]) simp_all
ultimately show "eventually (λx. norm (f x + g x) ≥ r) F"
proof eventually_elim
fix x :: 'a
assume A: "norm (f x) < norm c + 1" and B: "r + norm c + 1 ≤ norm (g x)"
from A B have "r ≤ norm (g x) - norm (f x)"
by simp
also have "norm (g x) - norm (f x) ≤ norm (g x + f x)"
by (rule norm_diff_ineq)
finally show "r ≤ norm (f x + g x)"
by (simp add: add_ac)
qed
qed
lemma tendsto_add_filterlim_at_infinity':
fixes c :: "'b::real_normed_vector"
and F :: "'a filter"
assumes "filterlim f at_infinity F"
and "(g ⤏ c) F"
shows "filterlim (λx. f x + g x) at_infinity F"
by (subst add.commute) (rule tendsto_add_filterlim_at_infinity assms)+
lemma filterlim_inverse_at_right_top: "LIM x at_top. inverse x :> at_right (0::real)"
unfolding filterlim_at
by (auto simp: eventually_at_top_dense)
(metis tendsto_inverse_0 filterlim_mono at_top_le_at_infinity order_refl)
lemma filterlim_inverse_at_top:
"(f ⤏ (0 :: real)) F ⟹ eventually (λx. 0 < f x) F ⟹ LIM x F. inverse (f x) :> at_top"
by (intro filterlim_compose[OF filterlim_inverse_at_top_right])
(simp add: filterlim_def eventually_filtermap eventually_mono at_within_def le_principal)
lemma filterlim_inverse_at_bot_neg:
"LIM x (at_left (0::real)). inverse x :> at_bot"
by (simp add: filterlim_inverse_at_top_right filterlim_uminus_at_bot filterlim_at_left_to_right)
lemma filterlim_inverse_at_bot:
"(f ⤏ (0 :: real)) F ⟹ eventually (λx. f x < 0) F ⟹ LIM x F. inverse (f x) :> at_bot"
unfolding filterlim_uminus_at_bot inverse_minus_eq[symmetric]
by (rule filterlim_inverse_at_top) (simp_all add: tendsto_minus_cancel_left[symmetric])
lemma at_right_to_top: "(at_right (0::real)) = filtermap inverse at_top"
by (intro filtermap_fun_inverse[symmetric, where g=inverse])
(auto intro: filterlim_inverse_at_top_right filterlim_inverse_at_right_top)
lemma eventually_at_right_to_top:
"eventually P (at_right (0::real)) ⟷ eventually (λx. P (inverse x)) at_top"
unfolding at_right_to_top eventually_filtermap ..
lemma filterlim_at_right_to_top:
"filterlim f F (at_right (0::real)) ⟷ (LIM x at_top. f (inverse x) :> F)"
unfolding filterlim_def at_right_to_top filtermap_filtermap ..
lemma at_top_to_right: "at_top = filtermap inverse (at_right (0::real))"
unfolding at_right_to_top filtermap_filtermap inverse_inverse_eq filtermap_ident ..
lemma eventually_at_top_to_right:
"eventually P at_top ⟷ eventually (λx. P (inverse x)) (at_right (0::real))"
unfolding at_top_to_right eventually_filtermap ..
lemma filterlim_at_top_to_right:
"filterlim f F at_top ⟷ (LIM x (at_right (0::real)). f (inverse x) :> F)"
unfolding filterlim_def at_top_to_right filtermap_filtermap ..
lemma filterlim_inverse_at_infinity:
fixes x :: "_ ⇒ 'a::{real_normed_div_algebra, division_ring}"
shows "filterlim inverse at_infinity (at (0::'a))"
unfolding filterlim_at_infinity[OF order_refl]
proof safe
fix r :: real
assume "0 < r"
then show "eventually (λx::'a. r ≤ norm (inverse x)) (at 0)"
unfolding eventually_at norm_inverse
by (intro exI[of _ "inverse r"])
(auto simp: norm_conv_dist[symmetric] field_simps inverse_eq_divide)
qed
lemma filterlim_inverse_at_iff:
fixes g :: "'a ⇒ 'b::{real_normed_div_algebra, division_ring}"
shows "(LIM x F. inverse (g x) :> at 0) ⟷ (LIM x F. g x :> at_infinity)"
unfolding filterlim_def filtermap_filtermap[symmetric]
proof
assume "filtermap g F ≤ at_infinity"
then have "filtermap inverse (filtermap g F) ≤ filtermap inverse at_infinity"
by (rule filtermap_mono)
also have "… ≤ at 0"
using tendsto_inverse_0[where 'a='b]
by (auto intro!: exI[of _ 1]
simp: le_principal eventually_filtermap filterlim_def at_within_def eventually_at_infinity)
finally show "filtermap inverse (filtermap g F) ≤ at 0" .
next
assume "filtermap inverse (filtermap g F) ≤ at 0"
then have "filtermap inverse (filtermap inverse (filtermap g F)) ≤ filtermap inverse (at 0)"
by (rule filtermap_mono)
with filterlim_inverse_at_infinity show "filtermap g F ≤ at_infinity"
by (auto intro: order_trans simp: filterlim_def filtermap_filtermap)
qed
lemma tendsto_mult_filterlim_at_infinity:
fixes c :: "'a::real_normed_field"
assumes "(f ⤏ c) F" "c ≠ 0"
assumes "filterlim g at_infinity F"
shows "filterlim (λx. f x * g x) at_infinity F"
proof -
have "((λx. inverse (f x) * inverse (g x)) ⤏ inverse c * 0) F"
by (intro tendsto_mult tendsto_inverse assms filterlim_compose[OF tendsto_inverse_0])
then have "filterlim (λx. inverse (f x) * inverse (g x)) (at (inverse c * 0)) F"
unfolding filterlim_at
using assms
by (auto intro: filterlim_at_infinity_imp_eventually_ne tendsto_imp_eventually_ne eventually_conj)
then show ?thesis
by (subst filterlim_inverse_at_iff[symmetric]) simp_all
qed
lemma filterlim_power_int_neg_at_infinity:
fixes f :: "_ ⇒ 'a::{real_normed_div_algebra, division_ring}"
assumes "n < 0" and lim: "(f ⤏ 0) F" and ev: "eventually (λx. f x ≠ 0) F"
shows "filterlim (λx. f x powi n) at_infinity F"
proof -
have lim': "((λx. f x ^ nat (- n)) ⤏ 0) F"
by (rule tendsto_eq_intros lim)+ (use ‹n < 0› in auto)
have ev': "eventually (λx. f x ^ nat (-n) ≠ 0) F"
using ev by eventually_elim (use ‹n < 0› in auto)
have "filterlim (λx. inverse (f x ^ nat (-n))) at_infinity F"
by (intro filterlim_compose[OF filterlim_inverse_at_infinity])
(use lim' ev' in ‹auto simp: filterlim_at›)
thus ?thesis
using ‹n < 0› by (simp add: power_int_def power_inverse)
qed
lemma tendsto_inverse_0_at_top: "LIM x F. f x :> at_top ⟹ ((λx. inverse (f x) :: real) ⤏ 0) F"
by (metis filterlim_at filterlim_mono[OF _ at_top_le_at_infinity order_refl] filterlim_inverse_at_iff)
lemma filterlim_inverse_at_top_iff:
"eventually (λx. 0 < f x) F ⟹ (LIM x F. inverse (f x) :> at_top) ⟷ (f ⤏ (0 :: real)) F"
by (auto dest: tendsto_inverse_0_at_top filterlim_inverse_at_top)
lemma filterlim_at_top_iff_inverse_0:
"eventually (λx. 0 < f x) F ⟹ (LIM x F. f x :> at_top) ⟷ ((inverse ∘ f) ⤏ (0 :: real)) F"
using filterlim_inverse_at_top_iff [of "inverse ∘ f"] by auto
lemma real_tendsto_divide_at_top:
fixes c::"real"
assumes "(f ⤏ c) F"
assumes "filterlim g at_top F"
shows "((λx. f x / g x) ⤏ 0) F"
by (auto simp: divide_inverse_commute
intro!: tendsto_mult[THEN tendsto_eq_rhs] tendsto_inverse_0_at_top assms)
lemma mult_nat_left_at_top: "c > 0 ⟹ filterlim (λx. c * x) at_top sequentially"
for c :: nat
by (rule filterlim_subseq) (auto simp: strict_mono_def)
lemma mult_nat_right_at_top: "c > 0 ⟹ filterlim (λx. x * c) at_top sequentially"
for c :: nat
by (rule filterlim_subseq) (auto simp: strict_mono_def)
lemma filterlim_times_pos:
"LIM x F1. c * f x :> at_right l"
if "filterlim f (at_right p) F1" "0 < c" "l = c * p"
for c::"'a::{linordered_field, linorder_topology}"
unfolding filterlim_iff
proof safe
fix P
assume "∀⇩F x in at_right l. P x"
then obtain d where "c * p < d" "⋀y. y > c * p ⟹ y < d ⟹ P y"
unfolding ‹l = _ › eventually_at_right_field
by auto
then have "∀⇩F a in at_right p. P (c * a)"
by (auto simp: eventually_at_right_field ‹0 < c› field_simps intro!: exI[where x="d/c"])
from that(1)[unfolded filterlim_iff, rule_format, OF this]
show "∀⇩F x in F1. P (c * f x)" .
qed
lemma filtermap_nhds_times: "c ≠ 0 ⟹ filtermap (times c) (nhds a) = nhds (c * a)"
for a c :: "'a::real_normed_field"
by (rule filtermap_fun_inverse[where g="λx. inverse c * x"])
(auto intro!: tendsto_eq_intros filterlim_ident)
lemma filtermap_times_pos_at_right:
fixes c::"'a::{linordered_field, linorder_topology}"
assumes "c > 0"
shows "filtermap (times c) (at_right p) = at_right (c * p)"
using assms
by (intro filtermap_fun_inverse[where g="λx. inverse c * x"])
(auto intro!: filterlim_ident filterlim_times_pos)
lemma at_to_infinity: "(at (0::'a::{real_normed_field,field})) = filtermap inverse at_infinity"
proof (rule antisym)
have "(inverse ⤏ (0::'a)) at_infinity"
by (fact tendsto_inverse_0)
then show "filtermap inverse at_infinity ≤ at (0::'a)"
using filterlim_def filterlim_ident filterlim_inverse_at_iff by fastforce
next
have "filtermap inverse (filtermap inverse (at (0::'a))) ≤ filtermap inverse at_infinity"
using filterlim_inverse_at_infinity unfolding filterlim_def
by (rule filtermap_mono)
then show "at (0::'a) ≤ filtermap inverse at_infinity"
by (simp add: filtermap_ident filtermap_filtermap)
qed
lemma lim_at_infinity_0:
fixes l :: "'a::{real_normed_field,field}"
shows "(f ⤏ l) at_infinity ⟷ ((f ∘ inverse) ⤏ l) (at (0::'a))"
by (simp add: tendsto_compose_filtermap at_to_infinity filtermap_filtermap)
lemma lim_zero_infinity:
fixes l :: "'a::{real_normed_field,field}"
shows "((λx. f(1 / x)) ⤏ l) (at (0::'a)) ⟹ (f ⤏ l) at_infinity"
by (simp add: inverse_eq_divide lim_at_infinity_0 comp_def)
text ‹
We only show rules for multiplication and addition when the functions are either against a real
value or against infinity. Further rules are easy to derive by using @{thm
filterlim_uminus_at_top}.
›
lemma filterlim_tendsto_pos_mult_at_top:
assumes f: "(f ⤏ c) F"
and c: "0 < c"
and g: "LIM x F. g x :> at_top"
shows "LIM x F. (f x * g x :: real) :> at_top"
unfolding filterlim_at_top_gt[where c=0]
proof safe
fix Z :: real
assume "0 < Z"
from f ‹0 < c› have "eventually (λx. c / 2 < f x) F"
by (auto dest!: tendstoD[where e="c / 2"] elim!: eventually_mono
simp: dist_real_def abs_real_def split: if_split_asm)
moreover from g have "eventually (λx. (Z / c * 2) ≤ g x) F"
unfolding filterlim_at_top by auto
ultimately show "eventually (λx. Z ≤ f x * g x) F"
proof eventually_elim
case (elim x)
with ‹0 < Z› ‹0 < c› have "c / 2 * (Z / c * 2) ≤ f x * g x"
by (intro mult_mono) (auto simp: zero_le_divide_iff)
with ‹0 < c› show "Z ≤ f x * g x"
by simp
qed
qed
lemma filterlim_at_top_mult_at_top:
assumes f: "LIM x F. f x :> at_top"
and g: "LIM x F. g x :> at_top"
shows "LIM x F. (f x * g x :: real) :> at_top"
unfolding filterlim_at_top_gt[where c=0]
proof safe
fix Z :: real
assume "0 < Z"
from f have "eventually (λx. 1 ≤ f x) F"
unfolding filterlim_at_top by auto
moreover from g have "eventually (λx. Z ≤ g x) F"
unfolding filterlim_at_top by auto
ultimately show "eventually (λx. Z ≤ f x * g x) F"
proof eventually_elim
case (elim x)
with ‹0 < Z› have "1 * Z ≤ f x * g x"
by (intro mult_mono) (auto simp: zero_le_divide_iff)
then show "Z ≤ f x * g x"
by simp
qed
qed
lemma filterlim_at_top_mult_tendsto_pos:
assumes f: "(f ⤏ c) F"
and c: "0 < c"
and g: "LIM x F. g x :> at_top"
shows "LIM x F. (g x * f x:: real) :> at_top"
by (auto simp: mult.commute intro!: filterlim_tendsto_pos_mult_at_top f c g)
lemma filterlim_tendsto_pos_mult_at_bot:
fixes c :: real
assumes "(f ⤏ c) F" "0 < c" "filterlim g at_bot F"
shows "LIM x F. f x * g x :> at_bot"
using filterlim_tendsto_pos_mult_at_top[OF assms(1,2), of "λx. - g x"] assms(3)
unfolding filterlim_uminus_at_bot by simp
lemma filterlim_tendsto_neg_mult_at_bot:
fixes c :: real
assumes c: "(f ⤏ c) F" "c < 0" and g: "filterlim g at_top F"
shows "LIM x F. f x * g x :> at_bot"
using c filterlim_tendsto_pos_mult_at_top[of "λx. - f x" "- c" F, OF _ _ g]
unfolding filterlim_uminus_at_bot tendsto_minus_cancel_left by simp
lemma filterlim_cmult_at_bot_at_top:
assumes "filterlim (h :: _ ⇒ real) at_top F" "c ≠ 0" "G = (if c > 0 then at_top else at_bot)"
shows "filterlim (λx. c * h x) G F"
using assms filterlim_tendsto_pos_mult_at_top[OF tendsto_const[of c], of h F]
filterlim_tendsto_neg_mult_at_bot[OF tendsto_const[of c], of h F] by simp
lemma filterlim_pow_at_top:
fixes f :: "'a ⇒ real"
assumes "0 < n"
and f: "LIM x F. f x :> at_top"
shows "LIM x F. (f x)^n :: real :> at_top"
using ‹0 < n›
proof (induct n)
case 0
then show ?case by simp
next
case (Suc n) with f show ?case
by (cases "n = 0") (auto intro!: filterlim_at_top_mult_at_top)
qed
lemma filterlim_pow_at_bot_even:
fixes f :: "real ⇒ real"
shows "0 < n ⟹ LIM x F. f x :> at_bot ⟹ even n ⟹ LIM x F. (f x)^n :> at_top"
using filterlim_pow_at_top[of n "λx. - f x" F] by (simp add: filterlim_uminus_at_top)
lemma filterlim_pow_at_bot_odd:
fixes f :: "real ⇒ real"
shows "0 < n ⟹ LIM x F. f x :> at_bot ⟹ odd n ⟹ LIM x F. (f x)^n :> at_bot"
using filterlim_pow_at_top[of n "λx. - f x" F] by (simp add: filterlim_uminus_at_bot)
lemma filterlim_power_at_infinity [tendsto_intros]:
fixes F and f :: "'a ⇒ 'b :: real_normed_div_algebra"
assumes "filterlim f at_infinity F" "n > 0"
shows "filterlim (λx. f x ^ n) at_infinity F"
by (rule filterlim_norm_at_top_imp_at_infinity)
(auto simp: norm_power intro!: filterlim_pow_at_top assms
intro: filterlim_at_infinity_imp_norm_at_top)
lemma filterlim_tendsto_add_at_top:
assumes f: "(f ⤏ c) F"
and g: "LIM x F. g x :> at_top"
shows "LIM x F. (f x + g x :: real) :> at_top"
unfolding filterlim_at_top_gt[where c=0]
proof safe
fix Z :: real
assume "0 < Z"
from f have "eventually (λx. c - 1 < f x) F"
by (auto dest!: tendstoD[where e=1] elim!: eventually_mono simp: dist_real_def)
moreover from g have "eventually (λx. Z - (c - 1) ≤ g x) F"
unfolding filterlim_at_top by auto
ultimately show "eventually (λx. Z ≤ f x + g x) F"
by eventually_elim simp
qed
lemma LIM_at_top_divide:
fixes f g :: "'a ⇒ real"
assumes f: "(f ⤏ a) F" "0 < a"
and g: "(g ⤏ 0) F" "eventually (λx. 0 < g x) F"
shows "LIM x F. f x / g x :> at_top"
unfolding divide_inverse
by (rule filterlim_tendsto_pos_mult_at_top[OF f]) (rule filterlim_inverse_at_top[OF g])
lemma filterlim_at_top_add_at_top:
assumes f: "LIM x F. f x :> at_top"
and g: "LIM x F. g x :> at_top"
shows "LIM x F. (f x + g x :: real) :> at_top"
unfolding filterlim_at_top_gt[where c=0]
proof safe
fix Z :: real
assume "0 < Z"
from f have "eventually (λx. 0 ≤ f x) F"
unfolding filterlim_at_top by auto
moreover from g have "eventually (λx. Z ≤ g x) F"
unfolding filterlim_at_top by auto
ultimately show "eventually (λx. Z ≤ f x + g x) F"
by eventually_elim simp
qed
lemma tendsto_divide_0:
fixes f :: "_ ⇒ 'a::{real_normed_div_algebra, division_ring}"
assumes f: "(f ⤏ c) F"
and g: "LIM x F. g x :> at_infinity"
shows "((λx. f x / g x) ⤏ 0) F"
using tendsto_mult[OF f filterlim_compose[OF tendsto_inverse_0 g]]
by (simp add: divide_inverse)
lemma linear_plus_1_le_power:
fixes x :: real
assumes x: "0 ≤ x"
shows "real n * x + 1 ≤ (x + 1) ^ n"
proof (induct n)
case 0
then show ?case by simp
next
case (Suc n)
from x have "real (Suc n) * x + 1 ≤ (x + 1) * (real n * x + 1)"
by (simp add: field_simps)
also have "… ≤ (x + 1)^Suc n"
using Suc x by (simp add: mult_left_mono)
finally show ?case .
qed
lemma filterlim_realpow_sequentially_gt1:
fixes x :: "'a :: real_normed_div_algebra"
assumes x[arith]: "1 < norm x"
shows "LIM n sequentially. x ^ n :> at_infinity"
proof (intro filterlim_at_infinity[THEN iffD2] allI impI)
fix y :: real
assume "0 < y"
obtain N :: nat where "y < real N * (norm x - 1)"
by (meson diff_gt_0_iff_gt reals_Archimedean3 x)
also have "… ≤ real N * (norm x - 1) + 1"
by simp
also have "… ≤ (norm x - 1 + 1) ^ N"
by (rule linear_plus_1_le_power) simp
also have "… = norm x ^ N"
by simp
finally have "∀n≥N. y ≤ norm x ^ n"
by (metis order_less_le_trans power_increasing order_less_imp_le x)
then show "eventually (λn. y ≤ norm (x ^ n)) sequentially"
unfolding eventually_sequentially
by (auto simp: norm_power)
qed simp
lemma filterlim_divide_at_infinity:
fixes f g :: "'a ⇒ 'a :: real_normed_field"
assumes "filterlim f (nhds c) F" "filterlim g (at 0) F" "c ≠ 0"
shows "filterlim (λx. f x / g x) at_infinity F"
proof -
have "filterlim (λx. f x * inverse (g x)) at_infinity F"
by (intro tendsto_mult_filterlim_at_infinity[OF assms(1,3)]
filterlim_compose [OF filterlim_inverse_at_infinity assms(2)])
thus ?thesis by (simp add: field_simps)
qed
subsection ‹Floor and Ceiling›
lemma eventually_floor_less:
fixes f :: "'a ⇒ 'b::{order_topology,floor_ceiling}"
assumes f: "(f ⤏ l) F"
and l: "l ∉ ℤ"
shows "∀⇩F x in F. of_int (floor l) < f x"
by (intro order_tendstoD[OF f]) (metis Ints_of_int antisym_conv2 floor_correct l)
lemma eventually_less_ceiling:
fixes f :: "'a ⇒ 'b::{order_topology,floor_ceiling}"
assumes f: "(f ⤏ l) F"
and l: "l ∉ ℤ"
shows "∀⇩F x in F. f x < of_int (ceiling l)"
by (intro order_tendstoD[OF f]) (metis Ints_of_int l le_of_int_ceiling less_le)
lemma eventually_floor_eq:
fixes f::"'a ⇒ 'b::{order_topology,floor_ceiling}"
assumes f: "(f ⤏ l) F"
and l: "l ∉ ℤ"
shows "∀⇩F x in F. floor (f x) = floor l"
using eventually_floor_less[OF assms] eventually_less_ceiling[OF assms]
by eventually_elim (meson floor_less_iff less_ceiling_iff not_less_iff_gr_or_eq)
lemma eventually_ceiling_eq:
fixes f::"'a ⇒ 'b::{order_topology,floor_ceiling}"
assumes f: "(f ⤏ l) F"
and l: "l ∉ ℤ"
shows "∀⇩F x in F. ceiling (f x) = ceiling l"
using eventually_floor_less[OF assms] eventually_less_ceiling[OF assms]
by eventually_elim (meson floor_less_iff less_ceiling_iff not_less_iff_gr_or_eq)
lemma tendsto_of_int_floor:
fixes f::"'a ⇒ 'b::{order_topology,floor_ceiling}"
assumes "(f ⤏ l) F"
and "l ∉ ℤ"
shows "((λx. of_int (floor (f x)) :: 'c::{ring_1,topological_space}) ⤏ of_int (floor l)) F"
using eventually_floor_eq[OF assms]
by (simp add: eventually_mono topological_tendstoI)
lemma tendsto_of_int_ceiling:
fixes f::"'a ⇒ 'b::{order_topology,floor_ceiling}"
assumes "(f ⤏ l) F"
and "l ∉ ℤ"
shows "((λx. of_int (ceiling (f x)):: 'c::{ring_1,topological_space}) ⤏ of_int (ceiling l)) F"
using eventually_ceiling_eq[OF assms]
by (simp add: eventually_mono topological_tendstoI)
lemma continuous_on_of_int_floor:
"continuous_on (UNIV - ℤ::'a::{order_topology, floor_ceiling} set)
(λx. of_int (floor x)::'b::{ring_1, topological_space})"
unfolding continuous_on_def
by (auto intro!: tendsto_of_int_floor)
lemma continuous_on_of_int_ceiling:
"continuous_on (UNIV - ℤ::'a::{order_topology, floor_ceiling} set)
(λx. of_int (ceiling x)::'b::{ring_1, topological_space})"
unfolding continuous_on_def
by (auto intro!: tendsto_of_int_ceiling)
subsection ‹Limits of Sequences›
lemma [trans]: "X = Y ⟹ Y ⇢ z ⟹ X ⇢ z"
by simp
lemma LIMSEQ_iff:
fixes L :: "'a::real_normed_vector"
shows "(X ⇢ L) = (∀r>0. ∃no. ∀n ≥ no. norm (X n - L) < r)"
unfolding lim_sequentially dist_norm ..
lemma LIMSEQ_I: "(⋀r. 0 < r ⟹ ∃no. ∀n≥no. norm (X n - L) < r) ⟹ X ⇢ L"
for L :: "'a::real_normed_vector"
by (simp add: LIMSEQ_iff)
lemma LIMSEQ_D: "X ⇢ L ⟹ 0 < r ⟹ ∃no. ∀n≥no. norm (X n - L) < r"
for L :: "'a::real_normed_vector"
by (simp add: LIMSEQ_iff)
lemma LIMSEQ_linear: "X ⇢ x ⟹ l > 0 ⟹ (λ n. X (n * l)) ⇢ x"
unfolding tendsto_def eventually_sequentially
by (metis div_le_dividend div_mult_self1_is_m le_trans mult.commute)
text ‹Transformation of limit.›
lemma Lim_transform: "(g ⤏ a) F ⟹ ((λx. f x - g x) ⤏ 0) F ⟹ (f ⤏ a) F"
for a b :: "'a::real_normed_vector"
using tendsto_add [of g a F "λx. f x - g x" 0] by simp
lemma Lim_transform2: "(f ⤏ a) F ⟹ ((λx. f x - g x) ⤏ 0) F ⟹ (g ⤏ a) F"
for a b :: "'a::real_normed_vector"
by (erule Lim_transform) (simp add: tendsto_minus_cancel)
proposition Lim_transform_eq: "((λx. f x - g x) ⤏ 0) F ⟹ (f ⤏ a) F ⟷ (g ⤏ a) F"
for a :: "'a::real_normed_vector"
using Lim_transform Lim_transform2 by blast
lemma Lim_transform_eventually:
"⟦(f ⤏ l) F; eventually (λx. f x = g x) F⟧ ⟹ (g ⤏ l) F"
using eventually_elim2 by (fastforce simp add: tendsto_def)
lemma Lim_transform_within:
assumes "(f ⤏ l) (at x within S)"
and "0 < d"
and "⋀x'. x'∈S ⟹ 0 < dist x' x ⟹ dist x' x < d ⟹ f x' = g x'"
shows "(g ⤏ l) (at x within S)"
proof (rule Lim_transform_eventually)
show "eventually (λx. f x = g x) (at x within S)"
using assms by (auto simp: eventually_at)
show "(f ⤏ l) (at x within S)"
by fact
qed
lemma filterlim_transform_within:
assumes "filterlim g G (at x within S)"
assumes "G ≤ F" "0<d" "(⋀x'. x' ∈ S ⟹ 0 < dist x' x ⟹ dist x' x < d ⟹ f x' = g x') "
shows "filterlim f F (at x within S)"
using assms
apply (elim filterlim_mono_eventually)
unfolding eventually_at by auto
text ‹Common case assuming being away from some crucial point like 0.›
lemma Lim_transform_away_within:
fixes a b :: "'a::t1_space"
assumes "a ≠ b"
and "∀x∈S. x ≠ a ∧ x ≠ b ⟶ f x = g x"
and "(f ⤏ l) (at a within S)"
shows "(g ⤏ l) (at a within S)"
proof (rule Lim_transform_eventually)
show "(f ⤏ l) (at a within S)"
by fact
show "eventually (λx. f x = g x) (at a within S)"
unfolding eventually_at_topological
by (rule exI [where x="- {b}"]) (simp add: open_Compl assms)
qed
lemma Lim_transform_away_at:
fixes a b :: "'a::t1_space"
assumes ab: "a ≠ b"
and fg: "∀x. x ≠ a ∧ x ≠ b ⟶ f x = g x"
and fl: "(f ⤏ l) (at a)"
shows "(g ⤏ l) (at a)"
using Lim_transform_away_within[OF ab, of UNIV f g l] fg fl by simp
text ‹Alternatively, within an open set.›
lemma Lim_transform_within_open:
assumes "(f ⤏ l) (at a within T)"
and "open s" and "a ∈ s"
and "⋀x. x∈s ⟹ x ≠ a ⟹ f x = g x"
shows "(g ⤏ l) (at a within T)"
proof (rule Lim_transform_eventually)
show "eventually (λx. f x = g x) (at a within T)"
unfolding eventually_at_topological
using assms by auto
show "(f ⤏ l) (at a within T)" by fact
qed
text ‹A congruence rule allowing us to transform limits assuming not at point.›
lemma Lim_cong_within:
assumes "a = b"
and "x = y"
and "S = T"
and "⋀x. x ≠ b ⟹ x ∈ T ⟹ f x = g x"
shows "(f ⤏ x) (at a within S) ⟷ (g ⤏ y) (at b within T)"
unfolding tendsto_def eventually_at_topological
using assms by simp
text ‹An unbounded sequence's inverse tends to 0.›
lemma LIMSEQ_inverse_zero:
assumes "⋀r::real. ∃N. ∀n≥N. r < X n"
shows "(λn. inverse (X n)) ⇢ 0"
apply (rule filterlim_compose[OF tendsto_inverse_0])
by (metis assms eventually_at_top_linorderI filterlim_at_top_dense filterlim_at_top_imp_at_infinity)
text ‹The sequence \<^term>‹1/n› tends to 0 as \<^term>‹n› tends to infinity.›
lemma LIMSEQ_inverse_real_of_nat: "(λn. inverse (real (Suc n))) ⇢ 0"
by (metis filterlim_compose tendsto_inverse_0 filterlim_mono order_refl filterlim_Suc
filterlim_compose[OF filterlim_real_sequentially] at_top_le_at_infinity)
text ‹
The sequence \<^term>‹r + 1/n› tends to \<^term>‹r› as \<^term>‹n› tends to
infinity is now easily proved.
›
lemma LIMSEQ_inverse_real_of_nat_add: "(λn. r + inverse (real (Suc n))) ⇢ r"
using tendsto_add [OF tendsto_const LIMSEQ_inverse_real_of_nat] by auto
lemma LIMSEQ_inverse_real_of_nat_add_minus: "(λn. r + -inverse (real (Suc n))) ⇢ r"
using tendsto_add [OF tendsto_const tendsto_minus [OF LIMSEQ_inverse_real_of_nat]]
by auto
lemma LIMSEQ_inverse_real_of_nat_add_minus_mult: "(λn. r * (1 + - inverse (real (Suc n)))) ⇢ r"
using tendsto_mult [OF tendsto_const LIMSEQ_inverse_real_of_nat_add_minus [of 1]]
by auto
lemma lim_inverse_n: "((λn. inverse(of_nat n)) ⤏ (0::'a::real_normed_field)) sequentially"
using lim_1_over_n by (simp add: inverse_eq_divide)
lemma lim_inverse_n': "((λn. 1 / n) ⤏ 0) sequentially"
using lim_inverse_n
by (simp add: inverse_eq_divide)
lemma LIMSEQ_Suc_n_over_n: "(λn. of_nat (Suc n) / of_nat n :: 'a :: real_normed_field) ⇢ 1"
proof (rule Lim_transform_eventually)
show "eventually (λn. 1 + inverse (of_nat n :: 'a) = of_nat (Suc n) / of_nat n) sequentially"
using eventually_gt_at_top[of "0::nat"]
by eventually_elim (simp add: field_simps)
have "(λn. 1 + inverse (of_nat n) :: 'a) ⇢ 1 + 0"
by (intro tendsto_add tendsto_const lim_inverse_n)
then show "(λn. 1 + inverse (of_nat n) :: 'a) ⇢ 1"
by simp
qed
lemma LIMSEQ_n_over_Suc_n: "(λn. of_nat n / of_nat (Suc n) :: 'a :: real_normed_field) ⇢ 1"
proof (rule Lim_transform_eventually)
show "eventually (λn. inverse (of_nat (Suc n) / of_nat n :: 'a) =
of_nat n / of_nat (Suc n)) sequentially"
using eventually_gt_at_top[of "0::nat"]
by eventually_elim (simp add: field_simps del: of_nat_Suc)
have "(λn. inverse (of_nat (Suc n) / of_nat n :: 'a)) ⇢ inverse 1"
by (intro tendsto_inverse LIMSEQ_Suc_n_over_n) simp_all
then show "(λn. inverse (of_nat (Suc n) / of_nat n :: 'a)) ⇢ 1"
by simp
qed
subsection ‹Convergence on sequences›
lemma convergent_cong:
assumes "eventually (λx. f x = g x) sequentially"
shows "convergent f ⟷ convergent g"
unfolding convergent_def
by (subst filterlim_cong[OF refl refl assms]) (rule refl)
lemma convergent_Suc_iff: "convergent (λn. f (Suc n)) ⟷ convergent f"
by (auto simp: convergent_def filterlim_sequentially_Suc)
lemma convergent_ignore_initial_segment: "convergent (λn. f (n + m)) = convergent f"
proof (induct m arbitrary: f)
case 0
then show ?case by simp
next
case (Suc m)
have "convergent (λn. f (n + Suc m)) ⟷ convergent (λn. f (Suc n + m))"
by simp
also have "… ⟷ convergent (λn. f (n + m))"
by (rule convergent_Suc_iff)
also have "… ⟷ convergent f"
by (rule Suc)
finally show ?case .
qed
lemma convergent_add:
fixes X Y :: "nat ⇒ 'a::topological_monoid_add"
assumes "convergent (λn. X n)"
and "convergent (λn. Y n)"
shows "convergent (λn. X n + Y n)"
using assms unfolding convergent_def by (blast intro: tendsto_add)
lemma convergent_sum:
fixes X :: "'a ⇒ nat ⇒ 'b::topological_comm_monoid_add"
shows "(⋀i. i ∈ A ⟹ convergent (λn. X i n)) ⟹ convergent (λn. ∑i∈A. X i n)"
by (induct A rule: infinite_finite_induct) (simp_all add: convergent_const convergent_add)
lemma (in bounded_linear) convergent:
assumes "convergent (λn. X n)"
shows "convergent (λn. f (X n))"
using assms unfolding convergent_def by (blast intro: tendsto)
lemma (in bounded_bilinear) convergent:
assumes "convergent (λn. X n)"
and "convergent (λn. Y n)"
shows "convergent (λn. X n ** Y n)"
using assms unfolding convergent_def by (blast intro: tendsto)
lemma convergent_minus_iff:
fixes X :: "nat ⇒ 'a::topological_group_add"
shows "convergent X ⟷ convergent (λn. - X n)"
unfolding convergent_def by (force dest: tendsto_minus)
lemma convergent_diff:
fixes X Y :: "nat ⇒ 'a::topological_group_add"
assumes "convergent (λn. X n)"
assumes "convergent (λn. Y n)"
shows "convergent (λn. X n - Y n)"
using assms unfolding convergent_def by (blast intro: tendsto_diff)
lemma convergent_norm:
assumes "convergent f"
shows "convergent (λn. norm (f n))"
proof -
from assms have "f ⇢ lim f"
by (simp add: convergent_LIMSEQ_iff)
then have "(λn. norm (f n)) ⇢ norm (lim f)"
by (rule tendsto_norm)
then show ?thesis
by (auto simp: convergent_def)
qed
lemma convergent_of_real:
"convergent f ⟹ convergent (λn. of_real (f n) :: 'a::real_normed_algebra_1)"
unfolding convergent_def by (blast intro!: tendsto_of_real)
lemma convergent_add_const_iff:
"convergent (λn. c + f n :: 'a::topological_ab_group_add) ⟷ convergent f"
proof
assume "convergent (λn. c + f n)"
from convergent_diff[OF this convergent_const[of c]] show "convergent f"
by simp
next
assume "convergent f"
from convergent_add[OF convergent_const[of c] this] show "convergent (λn. c + f n)"
by simp
qed
lemma convergent_add_const_right_iff:
"convergent (λn. f n + c :: 'a::topological_ab_group_add) ⟷ convergent f"
using convergent_add_const_iff[of c f] by (simp add: add_ac)
lemma convergent_diff_const_right_iff:
"convergent (λn. f n - c :: 'a::topological_ab_group_add) ⟷ convergent f"
using convergent_add_const_right_iff[of f "-c"] by (simp add: add_ac)
lemma convergent_mult:
fixes X Y :: "nat ⇒ 'a::topological_semigroup_mult"
assumes "convergent (λn. X n)"
and "convergent (λn. Y n)"
shows "convergent (λn. X n * Y n)"
using assms unfolding convergent_def by (blast intro: tendsto_mult)
lemma convergent_mult_const_iff:
assumes "c ≠ 0"
shows "convergent (λn. c * f n :: 'a::{field,topological_semigroup_mult}) ⟷ convergent f"
proof
assume "convergent (λn. c * f n)"
from assms convergent_mult[OF this convergent_const[of "inverse c"]]
show "convergent f" by (simp add: field_simps)
next
assume "convergent f"
from convergent_mult[OF convergent_const[of c] this] show "convergent (λn. c * f n)"
by simp
qed
lemma convergent_mult_const_right_iff:
fixes c :: "'a::{field,topological_semigroup_mult}"
assumes "c ≠ 0"
shows "convergent (λn. f n * c) ⟷ convergent f"
using convergent_mult_const_iff[OF assms, of f] by (simp add: mult_ac)
lemma convergent_imp_Bseq: "convergent f ⟹ Bseq f"
by (simp add: Cauchy_Bseq convergent_Cauchy)
text ‹A monotone sequence converges to its least upper bound.›
lemma LIMSEQ_incseq_SUP:
fixes X :: "nat ⇒ 'a::{conditionally_complete_linorder,linorder_topology}"
assumes u: "bdd_above (range X)"
and X: "incseq X"
shows "X ⇢ (SUP i. X i)"
by (rule order_tendstoI)
(auto simp: eventually_sequentially u less_cSUP_iff
intro: X[THEN incseqD] less_le_trans cSUP_lessD[OF u])
lemma LIMSEQ_decseq_INF:
fixes X :: "nat ⇒ 'a::{conditionally_complete_linorder, linorder_topology}"
assumes u: "bdd_below (range X)"
and X: "decseq X"
shows "X ⇢ (INF i. X i)"
by (rule order_tendstoI)
(auto simp: eventually_sequentially u cINF_less_iff
intro: X[THEN decseqD] le_less_trans less_cINF_D[OF u])
text ‹Main monotonicity theorem.›
lemma Bseq_monoseq_convergent: "Bseq X ⟹ monoseq X ⟹ convergent X"
for X :: "nat ⇒ real"
by (auto simp: monoseq_iff convergent_def intro: LIMSEQ_decseq_INF LIMSEQ_incseq_SUP
dest: Bseq_bdd_above Bseq_bdd_below)
lemma Bseq_mono_convergent: "Bseq X ⟹ (∀m n. m ≤ n ⟶ X m ≤ X n) ⟹ convergent X"
for X :: "nat ⇒ real"
by (auto intro!: Bseq_monoseq_convergent incseq_imp_monoseq simp: incseq_def)
lemma monoseq_imp_convergent_iff_Bseq: "monoseq f ⟹ convergent f ⟷ Bseq f"
for f :: "nat ⇒ real"
using Bseq_monoseq_convergent[of f] convergent_imp_Bseq[of f] by blast
lemma Bseq_monoseq_convergent'_inc:
fixes f :: "nat ⇒ real"
shows "Bseq (λn. f (n + M)) ⟹ (⋀m n. M ≤ m ⟹ m ≤ n ⟹ f m ≤ f n) ⟹ convergent f"
by (subst convergent_ignore_initial_segment [symmetric, of _ M])
(auto intro!: Bseq_monoseq_convergent simp: monoseq_def)
lemma Bseq_monoseq_convergent'_dec:
fixes f :: "nat ⇒ real"
shows "Bseq (λn. f (n + M)) ⟹ (⋀m n. M ≤ m ⟹ m ≤ n ⟹ f m ≥ f n) ⟹ convergent f"
by (subst convergent_ignore_initial_segment [symmetric, of _ M])
(auto intro!: Bseq_monoseq_convergent simp: monoseq_def)
lemma Cauchy_iff: "Cauchy X ⟷ (∀e>0. ∃M. ∀m≥M. ∀n≥M. norm (X m - X n) < e)"
for X :: "nat ⇒ 'a::real_normed_vector"
unfolding Cauchy_def dist_norm ..
lemma CauchyI: "(⋀e. 0 < e ⟹ ∃M. ∀m≥M. ∀n≥M. norm (X m - X n) < e) ⟹ Cauchy X"
for X :: "nat ⇒ 'a::real_normed_vector"
by (simp add: Cauchy_iff)
lemma CauchyD: "Cauchy X ⟹ 0 < e ⟹ ∃M. ∀m≥M. ∀n≥M. norm (X m - X n) < e"
for X :: "nat ⇒ 'a::real_normed_vector"
by (simp add: Cauchy_iff)
lemma incseq_convergent:
fixes X :: "nat ⇒ real"
assumes "incseq X"
and "∀i. X i ≤ B"
obtains L where "X ⇢ L" "∀i. X i ≤ L"
proof atomize_elim
from incseq_bounded[OF assms] ‹incseq X› Bseq_monoseq_convergent[of X]
obtain L where "X ⇢ L"
by (auto simp: convergent_def monoseq_def incseq_def)
with ‹incseq X› show "∃L. X ⇢ L ∧ (∀i. X i ≤ L)"
by (auto intro!: exI[of _ L] incseq_le)
qed
lemma decseq_convergent:
fixes X :: "nat ⇒ real"
assumes "decseq X"
and "∀i. B ≤ X i"
obtains L where "X ⇢ L" "∀i. L ≤ X i"
proof atomize_elim
from decseq_bounded[OF assms] ‹decseq X› Bseq_monoseq_convergent[of X]
obtain L where "X ⇢ L"
by (auto simp: convergent_def monoseq_def decseq_def)
with ‹decseq X› show "∃L. X ⇢ L ∧ (∀i. L ≤ X i)"
by (auto intro!: exI[of _ L] decseq_ge)
qed
lemma monoseq_convergent:
fixes X :: "nat ⇒ real"
assumes X: "monoseq X" and B: "⋀i. ¦X i¦ ≤ B"
obtains L where "X ⇢ L"
using X unfolding monoseq_iff
proof
assume "incseq X"
show thesis
using abs_le_D1 [OF B] incseq_convergent [OF ‹incseq X›] that by meson
next
assume "decseq X"
show thesis
using decseq_convergent [OF ‹decseq X›] that
by (metis B abs_le_iff add.inverse_inverse neg_le_iff_le)
qed
subsection ‹More about @{term filterlim} (thanks to Wenda Li)›
lemma filterlim_at_infinity_times:
fixes f :: "'a ⇒ 'b::real_normed_field"
assumes "filterlim f at_infinity F" "filterlim g at_infinity F"
shows "filterlim (λx. f x * g x) at_infinity F"
proof -
have "((λx. inverse (f x) * inverse (g x)) ⤏ 0 * 0) F"
by (intro tendsto_mult tendsto_inverse assms filterlim_compose[OF tendsto_inverse_0])
then have "filterlim (λx. inverse (f x) * inverse (g x)) (at 0) F"
unfolding filterlim_at using assms
by (auto intro: filterlim_at_infinity_imp_eventually_ne tendsto_imp_eventually_ne eventually_conj)
then show ?thesis
by (subst filterlim_inverse_at_iff[symmetric]) simp_all
qed
lemma filterlim_at_top_at_bot[elim]:
fixes f::"'a ⇒ 'b::unbounded_dense_linorder" and F::"'a filter"
assumes top:"filterlim f at_top F" and bot: "filterlim f at_bot F" and "F≠bot"
shows False
proof -
obtain c::'b where True by auto
have "∀⇩F x in F. c < f x"
using top unfolding filterlim_at_top_dense by auto
moreover have "∀⇩F x in F. f x < c"
using bot unfolding filterlim_at_bot_dense by auto
ultimately have "∀⇩F x in F. c < f x ∧ f x < c"
using eventually_conj by auto
then have "∀⇩F x in F. False" by (auto elim:eventually_mono)
then show False using ‹F≠bot› by auto
qed
lemma filterlim_at_top_nhds[elim]:
fixes f::"'a ⇒ 'b::{unbounded_dense_linorder,order_topology}" and F::"'a filter"
assumes top:"filterlim f at_top F" and tendsto: "(f ⤏ c) F" and "F≠bot"
shows False
proof -
obtain c'::'b where "c'>c" using gt_ex by blast
have "∀⇩F x in F. c' < f x"
using top unfolding filterlim_at_top_dense by auto
moreover have "∀⇩F x in F. f x < c'"
using order_tendstoD[OF tendsto,of c'] ‹c'>c› by auto
ultimately have "∀⇩F x in F. c' < f x ∧ f x < c'"
using eventually_conj by auto
then have "∀⇩F x in F. False" by (auto elim:eventually_mono)
then show False using ‹F≠bot› by auto
qed
lemma filterlim_at_bot_nhds[elim]:
fixes f::"'a ⇒ 'b::{unbounded_dense_linorder,order_topology}" and F::"'a filter"
assumes top:"filterlim f at_bot F" and tendsto: "(f ⤏ c) F" and "F≠bot"
shows False
proof -
obtain c'::'b where "c'<c" using lt_ex by blast
have "∀⇩F x in F. c' > f x"
using top unfolding filterlim_at_bot_dense by auto
moreover have "∀⇩F x in F. f x > c'"
using order_tendstoD[OF tendsto,of c'] ‹c'<c› by auto
ultimately have "∀⇩F x in F. c' < f x ∧ f x < c'"
using eventually_conj by auto
then have "∀⇩F x in F. False" by (auto elim:eventually_mono)
then show False using ‹F≠bot› by auto
qed
lemma eventually_times_inverse_1:
fixes f::"'a ⇒ 'b::{field,t2_space}"
assumes "(f ⤏ c) F" "c≠0"
shows "∀⇩F x in F. inverse (f x) * f x = 1"
by (smt (verit) assms eventually_mono mult.commute right_inverse tendsto_imp_eventually_ne)
lemma filterlim_at_infinity_divide_iff:
fixes f::"'a ⇒ 'b::real_normed_field"
assumes "(f ⤏ c) F" "c≠0"
shows "(LIM x F. f x / g x :> at_infinity) ⟷ (LIM x F. g x :> at 0)"
proof
assume "LIM x F. f x / g x :> at_infinity"
then have "LIM x F. inverse (f x) * (f x / g x) :> at_infinity"
using assms tendsto_inverse tendsto_mult_filterlim_at_infinity by fastforce
then have "LIM x F. inverse (g x) :> at_infinity"
apply (elim filterlim_mono_eventually)
using eventually_times_inverse_1[OF assms]
by (auto elim:eventually_mono simp add:field_simps)
then show "filterlim g (at 0) F" using filterlim_inverse_at_iff[symmetric] by force
next
assume "filterlim g (at 0) F"
then have "filterlim (λx. inverse (g x)) at_infinity F"
using filterlim_compose filterlim_inverse_at_infinity by blast
then have "LIM x F. f x * inverse (g x) :> at_infinity"
using tendsto_mult_filterlim_at_infinity[OF assms, of "λx. inverse(g x)"]
by simp
then show "LIM x F. f x / g x :> at_infinity" by (simp add: divide_inverse)
qed
lemma filterlim_tendsto_pos_mult_at_top_iff:
fixes f::"'a ⇒ real"
assumes "(f ⤏ c) F" and "0 < c"
shows "(LIM x F. (f x * g x) :> at_top) ⟷ (LIM x F. g x :> at_top)"
proof
assume "filterlim g at_top F"
then show "LIM x F. f x * g x :> at_top"
using filterlim_tendsto_pos_mult_at_top[OF assms] by auto
next
assume asm:"LIM x F. f x * g x :> at_top"
have "((λx. inverse (f x)) ⤏ inverse c) F"
using tendsto_inverse[OF assms(1)] ‹0<c› by auto
moreover have "inverse c >0" using assms(2) by auto
ultimately have "LIM x F. inverse (f x) * (f x * g x) :> at_top"
using filterlim_tendsto_pos_mult_at_top[OF _ _ asm,of "λx. inverse (f x)" "inverse c"] by auto
then show "LIM x F. g x :> at_top"
apply (elim filterlim_mono_eventually)
apply simp_all[2]
using eventually_times_inverse_1[OF assms(1)] ‹c>0› eventually_mono by fastforce
qed
lemma filterlim_tendsto_pos_mult_at_bot_iff:
fixes c :: real
assumes "(f ⤏ c) F" "0 < c"
shows "(LIM x F. f x * g x :> at_bot) ⟷ filterlim g at_bot F"
using filterlim_tendsto_pos_mult_at_top_iff[OF assms(1,2), of "λx. - g x"]
unfolding filterlim_uminus_at_bot by simp
lemma filterlim_tendsto_neg_mult_at_top_iff:
fixes f::"'a ⇒ real"
assumes "(f ⤏ c) F" and "c < 0"
shows "(LIM x F. (f x * g x) :> at_top) ⟷ (LIM x F. g x :> at_bot)"
proof -
have "(LIM x F. f x * g x :> at_top) = (LIM x F. - g x :> at_top)"
apply (rule filterlim_tendsto_pos_mult_at_top_iff[of "λx. - f x" "-c" F "λx. - g x", simplified])
using assms by (auto intro: tendsto_intros )
also have "... = (LIM x F. g x :> at_bot)"
using filterlim_uminus_at_bot[symmetric] by auto
finally show ?thesis .
qed
lemma filterlim_tendsto_neg_mult_at_bot_iff:
fixes c :: real
assumes "(f ⤏ c) F" "0 > c"
shows "(LIM x F. f x * g x :> at_bot) ⟷ filterlim g at_top F"
using filterlim_tendsto_neg_mult_at_top_iff[OF assms(1,2), of "λx. - g x"]
unfolding filterlim_uminus_at_top by simp
subsection ‹Power Sequences›
lemma Bseq_realpow: "0 ≤ x ⟹ x ≤ 1 ⟹ Bseq (λn. x ^ n)"
for x :: real
by (metis decseq_bounded decseq_def power_decreasing zero_le_power)
lemma monoseq_realpow: "0 ≤ x ⟹ x ≤ 1 ⟹ monoseq (λn. x ^ n)"
for x :: real
using monoseq_def power_decreasing by blast
lemma convergent_realpow: "0 ≤ x ⟹ x ≤ 1 ⟹ convergent (λn. x ^ n)"
for x :: real
by (blast intro!: Bseq_monoseq_convergent Bseq_realpow monoseq_realpow)
lemma LIMSEQ_inverse_realpow_zero: "1 < x ⟹ (λn. inverse (x ^ n)) ⇢ 0"
for x :: real
by (rule filterlim_compose[OF tendsto_inverse_0 filterlim_realpow_sequentially_gt1]) simp
lemma LIMSEQ_realpow_zero:
fixes x :: real
assumes "0 ≤ x" "x < 1"
shows "(λn. x ^ n) ⇢ 0"
proof (cases "x = 0")
case False
with ‹0 ≤ x› have "1 < inverse x"
using ‹x < 1› by (simp add: one_less_inverse)
then have "(λn. inverse (inverse x ^ n)) ⇢ 0"
by (rule LIMSEQ_inverse_realpow_zero)
then show ?thesis by (simp add: power_inverse)
next
case True
show ?thesis
by (rule LIMSEQ_imp_Suc) (simp add: True)
qed
lemma LIMSEQ_power_zero [tendsto_intros]: "norm x < 1 ⟹ (λn. x ^ n) ⇢ 0"
for x :: "'a::real_normed_algebra_1"
apply (drule LIMSEQ_realpow_zero [OF norm_ge_zero])
by (simp add: Zfun_le norm_power_ineq tendsto_Zfun_iff)
lemma LIMSEQ_divide_realpow_zero: "1 < x ⟹ (λn. a / (x ^ n) :: real) ⇢ 0"
by (rule tendsto_divide_0 [OF tendsto_const filterlim_realpow_sequentially_gt1]) simp
lemma
tendsto_power_zero:
fixes x::"'a::real_normed_algebra_1"
assumes "filterlim f at_top F"
assumes "norm x < 1"
shows "((λy. x ^ (f y)) ⤏ 0) F"
proof (rule tendstoI)
fix e::real assume "0 < e"
from tendstoD[OF LIMSEQ_power_zero[OF ‹norm x < 1›] ‹0 < e›]
have "∀⇩F xa in sequentially. norm (x ^ xa) < e"
by simp
then obtain N where N: "norm (x ^ n) < e" if "n ≥ N" for n
by (auto simp: eventually_sequentially)
have "∀⇩F i in F. f i ≥ N"
using ‹filterlim f sequentially F›
by (simp add: filterlim_at_top)
then show "∀⇩F i in F. dist (x ^ f i) 0 < e"
by eventually_elim (auto simp: N)
qed
text ‹Limit of \<^term>‹c^n› for \<^term>‹¦c¦ < 1›.›
lemma LIMSEQ_abs_realpow_zero: "¦c¦ < 1 ⟹ (λn. ¦c¦ ^ n :: real) ⇢ 0"
by (rule LIMSEQ_realpow_zero [OF abs_ge_zero])
lemma LIMSEQ_abs_realpow_zero2: "¦c¦ < 1 ⟹ (λn. c ^ n :: real) ⇢ 0"
by (rule LIMSEQ_power_zero) simp
subsection ‹Limits of Functions›
lemma LIM_eq: "f ─a→ L = (∀r>0. ∃s>0. ∀x. x ≠ a ∧ norm (x - a) < s ⟶ norm (f x - L) < r)"
for a :: "'a::real_normed_vector" and L :: "'b::real_normed_vector"
by (simp add: LIM_def dist_norm)
lemma LIM_I:
"(⋀r. 0 < r ⟹ ∃s>0. ∀x. x ≠ a ∧ norm (x - a) < s ⟶ norm (f x - L) < r) ⟹ f ─a→ L"
for a :: "'a::real_normed_vector" and L :: "'b::real_normed_vector"
by (simp add: LIM_eq)
lemma LIM_D: "f ─a→ L ⟹ 0 < r ⟹ ∃s>0.∀x. x ≠ a ∧ norm (x - a) < s ⟶ norm (f x - L) < r"
for a :: "'a::real_normed_vector" and L :: "'b::real_normed_vector"
by (simp add: LIM_eq)
lemma LIM_offset: "f ─a→ L ⟹ (λx. f (x + k)) ─(a - k)→ L"
for a :: "'a::real_normed_vector"
by (simp add: filtermap_at_shift[symmetric, of a k] filterlim_def filtermap_filtermap)
lemma LIM_offset_zero: "f ─a→ L ⟹ (λh. f (a + h)) ─0→ L"
for a :: "'a::real_normed_vector"
by (drule LIM_offset [where k = a]) (simp add: add.commute)
lemma LIM_offset_zero_cancel: "(λh. f (a + h)) ─0→ L ⟹ f ─a→ L"
for a :: "'a::real_normed_vector"
by (drule LIM_offset [where k = "- a"]) simp
lemma LIM_offset_zero_iff: "NO_MATCH 0 a ⟹ f ─a→ L ⟷ (λh. f (a + h)) ─0→ L"
for f :: "'a :: real_normed_vector ⇒ _"
using LIM_offset_zero_cancel[of f a L] LIM_offset_zero[of f L a] by auto
lemma tendsto_offset_zero_iff:
fixes f :: "'a :: real_normed_vector ⇒ _"
assumes " NO_MATCH 0 a" "a ∈ S" "open S"
shows "(f ⤏ L) (at a within S) ⟷ ((λh. f (a + h)) ⤏ L) (at 0)"
using assms by (simp add: tendsto_within_open_NO_MATCH LIM_offset_zero_iff)
lemma LIM_zero: "(f ⤏ l) F ⟹ ((λx. f x - l) ⤏ 0) F"
for f :: "'a ⇒ 'b::real_normed_vector"
unfolding tendsto_iff dist_norm by simp
lemma LIM_zero_cancel:
fixes f :: "'a ⇒ 'b::real_normed_vector"
shows "((λx. f x - l) ⤏ 0) F ⟹ (f ⤏ l) F"
unfolding tendsto_iff dist_norm by simp
lemma LIM_zero_iff: "((λx. f x - l) ⤏ 0) F = (f ⤏ l) F"
for f :: "'a ⇒ 'b::real_normed_vector"
unfolding tendsto_iff dist_norm by simp
lemma LIM_imp_LIM:
fixes f :: "'a::topological_space ⇒ 'b::real_normed_vector"
fixes g :: "'a::topological_space ⇒ 'c::real_normed_vector"
assumes f: "f ─a→ l"
and le: "⋀x. x ≠ a ⟹ norm (g x - m) ≤ norm (f x - l)"
shows "g ─a→ m"
by (rule metric_LIM_imp_LIM [OF f]) (simp add: dist_norm le)
lemma LIM_equal2:
fixes f g :: "'a::real_normed_vector ⇒ 'b::topological_space"
assumes "0 < R"
and "⋀x. x ≠ a ⟹ norm (x - a) < R ⟹ f x = g x"
shows "g ─a→ l ⟹ f ─a→ l"
by (rule metric_LIM_equal2 [OF _ assms]) (simp_all add: dist_norm)
lemma LIM_compose2:
fixes a :: "'a::real_normed_vector"
assumes f: "f ─a→ b"
and g: "g ─b→ c"
and inj: "∃d>0. ∀x. x ≠ a ∧ norm (x - a) < d ⟶ f x ≠ b"
shows "(λx. g (f x)) ─a→ c"
by (rule metric_LIM_compose2 [OF f g inj [folded dist_norm]])
lemma real_LIM_sandwich_zero:
fixes f g :: "'a::topological_space ⇒ real"
assumes f: "f ─a→ 0"
and 1: "⋀x. x ≠ a ⟹ 0 ≤ g x"
and 2: "⋀x. x ≠ a ⟹ g x ≤ f x"
shows "g ─a→ 0"
proof (rule LIM_imp_LIM [OF f])
fix x
assume x: "x ≠ a"
with 1 have "norm (g x - 0) = g x" by simp
also have "g x ≤ f x" by (rule 2 [OF x])
also have "f x ≤ ¦f x¦" by (rule abs_ge_self)
also have "¦f x¦ = norm (f x - 0)" by simp
finally show "norm (g x - 0) ≤ norm (f x - 0)" .
qed
subsection ‹Continuity›
lemma LIM_isCont_iff: "(f ─a→ f a) = ((λh. f (a + h)) ─0→ f a)"
for f :: "'a::real_normed_vector ⇒ 'b::topological_space"
by (rule iffI [OF LIM_offset_zero LIM_offset_zero_cancel])
lemma isCont_iff: "isCont f x = (λh. f (x + h)) ─0→ f x"
for f :: "'a::real_normed_vector ⇒ 'b::topological_space"
by (simp add: isCont_def LIM_isCont_iff)
lemma isCont_LIM_compose2:
fixes a :: "'a::real_normed_vector"
assumes f [unfolded isCont_def]: "isCont f a"
and g: "g ─f a→ l"
and inj: "∃d>0. ∀x. x ≠ a ∧ norm (x - a) < d ⟶ f x ≠ f a"
shows "(λx. g (f x)) ─a→ l"
by (rule LIM_compose2 [OF f g inj])
lemma isCont_norm [simp]: "isCont f a ⟹ isCont (λx. norm (f x)) a"
for f :: "'a::t2_space ⇒ 'b::real_normed_vector"
by (fact continuous_norm)
lemma isCont_rabs [simp]: "isCont f a ⟹ isCont (λx. ¦f x¦) a"
for f :: "'a::t2_space ⇒ real"
by (fact continuous_rabs)
lemma isCont_add [simp]: "isCont f a ⟹ isCont g a ⟹ isCont (λx. f x + g x) a"
for f :: "'a::t2_space ⇒ 'b::topological_monoid_add"
by (fact continuous_add)
lemma isCont_minus [simp]: "isCont f a ⟹ isCont (λx. - f x) a"
for f :: "'a::t2_space ⇒ 'b::real_normed_vector"
by (fact continuous_minus)
lemma isCont_diff [simp]: "isCont f a ⟹ isCont g a ⟹ isCont (λx. f x - g x) a"
for f :: "'a::t2_space ⇒ 'b::real_normed_vector"
by (fact continuous_diff)
lemma isCont_mult [simp]: "isCont f a ⟹ isCont g a ⟹ isCont (λx. f x * g x) a"
for f g :: "'a::t2_space ⇒ 'b::real_normed_algebra"
by (fact continuous_mult)
lemma (in bounded_linear) isCont: "isCont g a ⟹ isCont (λx. f (g x)) a"
by (fact continuous)
lemma (in bounded_bilinear) isCont: "isCont f a ⟹ isCont g a ⟹ isCont (λx. f x ** g x) a"
by (fact continuous)
lemmas isCont_scaleR [simp] =
bounded_bilinear.isCont [OF bounded_bilinear_scaleR]
lemmas isCont_of_real [simp] =
bounded_linear.isCont [OF bounded_linear_of_real]
lemma isCont_power [simp]: "isCont f a ⟹ isCont (λx. f x ^ n) a"
for f :: "'a::t2_space ⇒ 'b::{power,real_normed_algebra}"
by (fact continuous_power)
lemma isCont_sum [simp]: "∀i∈A. isCont (f i) a ⟹ isCont (λx. ∑i∈A. f i x) a"
for f :: "'a ⇒ 'b::t2_space ⇒ 'c::topological_comm_monoid_add"
by (auto intro: continuous_sum)
subsection ‹Uniform Continuity›
lemma uniformly_continuous_on_def:
fixes f :: "'a::metric_space ⇒ 'b::metric_space"
shows "uniformly_continuous_on s f ⟷
(∀e>0. ∃d>0. ∀x∈s. ∀x'∈s. dist x' x < d ⟶ dist (f x') (f x) < e)"
unfolding uniformly_continuous_on_uniformity
uniformity_dist filterlim_INF filterlim_principal eventually_inf_principal
by (force simp: Ball_def uniformity_dist[symmetric] eventually_uniformity_metric)
abbreviation isUCont :: "['a::metric_space ⇒ 'b::metric_space] ⇒ bool"
where "isUCont f ≡ uniformly_continuous_on UNIV f"
lemma isUCont_def: "isUCont f ⟷ (∀r>0. ∃s>0. ∀x y. dist x y < s ⟶ dist (f x) (f y) < r)"
by (auto simp: uniformly_continuous_on_def dist_commute)
lemma isUCont_isCont: "isUCont f ⟹ isCont f x"
by (drule uniformly_continuous_imp_continuous) (simp add: continuous_on_eq_continuous_at)
lemma uniformly_continuous_on_Cauchy:
fixes f :: "'a::metric_space ⇒ 'b::metric_space"
assumes "uniformly_continuous_on S f" "Cauchy X" "⋀n. X n ∈ S"
shows "Cauchy (λn. f (X n))"
using assms
unfolding uniformly_continuous_on_def by (meson Cauchy_def)
lemma isUCont_Cauchy: "isUCont f ⟹ Cauchy X ⟹ Cauchy (λn. f (X n))"
by (rule uniformly_continuous_on_Cauchy[where S=UNIV and f=f]) simp_all
lemma (in bounded_linear) isUCont: "isUCont f"
unfolding isUCont_def dist_norm
proof (intro allI impI)
fix r :: real
assume r: "0 < r"
obtain K where K: "0 < K" and norm_le: "norm (f x) ≤ norm x * K" for x
using pos_bounded by blast
show "∃s>0. ∀x y. norm (x - y) < s ⟶ norm (f x - f y) < r"
proof (rule exI, safe)
from r K show "0 < r / K" by simp
next
fix x y :: 'a
assume xy: "norm (x - y) < r / K"
have "norm (f x - f y) = norm (f (x - y))" by (simp only: diff)
also have "… ≤ norm (x - y) * K" by (rule norm_le)
also from K xy have "… < r" by (simp only: pos_less_divide_eq)
finally show "norm (f x - f y) < r" .
qed
qed
lemma (in bounded_linear) Cauchy: "Cauchy X ⟹ Cauchy (λn. f (X n))"
by (rule isUCont [THEN isUCont_Cauchy])
lemma LIM_less_bound:
fixes f :: "real ⇒ real"
assumes ev: "b < x" "∀ x' ∈ { b <..< x}. 0 ≤ f x'" and "isCont f x"
shows "0 ≤ f x"
proof (rule tendsto_lowerbound)
show "(f ⤏ f x) (at_left x)"
using ‹isCont f x› by (simp add: filterlim_at_split isCont_def)
show "eventually (λx. 0 ≤ f x) (at_left x)"
using ev by (auto simp: eventually_at dist_real_def intro!: exI[of _ "x - b"])
qed simp
subsection ‹Nested Intervals and Bisection -- Needed for Compactness›
lemma nested_sequence_unique:
assumes "∀n. f n ≤ f (Suc n)" "∀n. g (Suc n) ≤ g n" "∀n. f n ≤ g n" "(λn. f n - g n) ⇢ 0"
shows "∃l::real. ((∀n. f n ≤ l) ∧ f ⇢ l) ∧ ((∀n. l ≤ g n) ∧ g ⇢ l)"
proof -
have "incseq f" unfolding incseq_Suc_iff by fact
have "decseq g" unfolding decseq_Suc_iff by fact
have "f n ≤ g 0" for n
proof -
from ‹decseq g› have "g n ≤ g 0"
by (rule decseqD) simp
with ‹∀n. f n ≤ g n›[THEN spec, of n] show ?thesis
by auto
qed
then obtain u where "f ⇢ u" "∀i. f i ≤ u"
using incseq_convergent[OF ‹incseq f›] by auto
moreover have "f 0 ≤ g n" for n
proof -
from ‹incseq f› have "f 0 ≤ f n" by (rule incseqD) simp
with ‹∀n. f n ≤ g n›[THEN spec, of n] show ?thesis
by simp
qed
then obtain l where "g ⇢ l" "∀i. l ≤ g i"
using decseq_convergent[OF ‹decseq g›] by auto
moreover note LIMSEQ_unique[OF assms(4) tendsto_diff[OF ‹f ⇢ u› ‹g ⇢ l›]]
ultimately show ?thesis by auto
qed
lemma Bolzano[consumes 1, case_names trans local]:
fixes P :: "real ⇒ real ⇒ bool"
assumes [arith]: "a ≤ b"
and trans: "⋀a b c. P a b ⟹ P b c ⟹ a ≤ b ⟹ b ≤ c ⟹ P a c"
and local: "⋀x. a ≤ x ⟹ x ≤ b ⟹ ∃d>0. ∀a b. a ≤ x ∧ x ≤ b ∧ b - a < d ⟶ P a b"
shows "P a b"
proof -
define bisect where "bisect ≡ λ(x,y). if P x ((x+y) / 2) then ((x+y)/2, y) else (x, (x+y)/2)"
define l u where "l n ≡ fst ((bisect^^n)(a,b))" and "u n ≡ snd ((bisect^^n)(a,b))" for n
have l[simp]: "l 0 = a" "⋀n. l (Suc n) = (if P (l n) ((l n + u n) / 2) then (l n + u n) / 2 else l n)"
and u[simp]: "u 0 = b" "⋀n. u (Suc n) = (if P (l n) ((l n + u n) / 2) then u n else (l n + u n) / 2)"
by (simp_all add: l_def u_def bisect_def split: prod.split)
have [simp]: "l n ≤ u n" for n by (induct n) auto
have "∃x. ((∀n. l n ≤ x) ∧ l ⇢ x) ∧ ((∀n. x ≤ u n) ∧ u ⇢ x)"
proof (safe intro!: nested_sequence_unique)
show "l n ≤ l (Suc n)" "u (Suc n) ≤ u n" for n
by (induct n) auto
next
have "l n - u n = (a - b) / 2^n" for n
by (induct n) (auto simp: field_simps)
then show "(λn. l n - u n) ⇢ 0"
by (simp add: LIMSEQ_divide_realpow_zero)
qed fact
then obtain x where x: "⋀n. l n ≤ x" "⋀n. x ≤ u n" and "l ⇢ x" "u ⇢ x"
by auto
obtain d where "0 < d" and d: "a ≤ x ⟹ x ≤ b ⟹ b - a < d ⟹ P a b" for a b
using ‹l 0 ≤ x› ‹x ≤ u 0› local[of x] by auto
show "P a b"
proof (rule ccontr)
assume "¬ P a b"
have "¬ P (l n) (u n)" for n
proof (induct n)
case 0
then show ?case
by (simp add: ‹¬ P a b›)
next
case (Suc n)
with trans[of "l n" "(l n + u n) / 2" "u n"] show ?case
by auto
qed
moreover
{
have "eventually (λn. x - d / 2 < l n) sequentially"
using ‹0 < d› ‹l ⇢ x› by (intro order_tendstoD[of _ x]) auto
moreover have "eventually (λn. u n < x + d / 2) sequentially"
using ‹0 < d› ‹u ⇢ x› by (intro order_tendstoD[of _ x]) auto
ultimately have "eventually (λn. P (l n) (u n)) sequentially"
proof eventually_elim
case (elim n)
from add_strict_mono[OF this] have "u n - l n < d" by simp
with x show "P (l n) (u n)" by (rule d)
qed
}
ultimately show False by simp
qed
qed
lemma compact_Icc[simp, intro]: "compact {a .. b::real}"
proof (cases "a ≤ b", rule compactI)
fix C
assume C: "a ≤ b" "∀t∈C. open t" "{a..b} ⊆ ⋃C"
define T where "T = {a .. b}"
from C(1,3) show "∃C'⊆C. finite C' ∧ {a..b} ⊆ ⋃C'"
proof (induct rule: Bolzano)
case (trans a b c)
then have *: "{a..c} = {a..b} ∪ {b..c}"
by auto
with trans obtain C1 C2
where "C1⊆C" "finite C1" "{a..b} ⊆ ⋃C1" "C2⊆C" "finite C2" "{b..c} ⊆ ⋃C2"
by auto
with trans show ?case
unfolding * by (intro exI[of _ "C1 ∪ C2"]) auto
next
case (local x)
with C have "x ∈ ⋃C" by auto
with C(2) obtain c where "x ∈ c" "open c" "c ∈ C"
by auto
then obtain e where "0 < e" "{x - e <..< x + e} ⊆ c"
by (auto simp: open_dist dist_real_def subset_eq Ball_def abs_less_iff)
with ‹c ∈ C› show ?case
by (safe intro!: exI[of _ "e/2"] exI[of _ "{c}"]) auto
qed
qed simp
lemma continuous_image_closed_interval:
fixes a b and f :: "real ⇒ real"
defines "S ≡ {a..b}"
assumes "a ≤ b" and f: "continuous_on S f"
shows "∃c d. f`S = {c..d} ∧ c ≤ d"
proof -
have S: "compact S" "S ≠ {}"
using ‹a ≤ b› by (auto simp: S_def)
obtain c where "c ∈ S" "∀d∈S. f d ≤ f c"
using continuous_attains_sup[OF S f] by auto
moreover obtain d where "d ∈ S" "∀c∈S. f d ≤ f c"
using continuous_attains_inf[OF S f] by auto
moreover have "connected (f`S)"
using connected_continuous_image[OF f] connected_Icc by (auto simp: S_def)
ultimately have "f ` S = {f d .. f c} ∧ f d ≤ f c"
by (auto simp: connected_iff_interval)
then show ?thesis
by auto
qed
lemma open_Collect_positive:
fixes f :: "'a::topological_space ⇒ real"
assumes f: "continuous_on s f"
shows "∃A. open A ∧ A ∩ s = {x∈s. 0 < f x}"
using continuous_on_open_invariant[THEN iffD1, OF f, rule_format, of "{0 <..}"]
by (auto simp: Int_def field_simps)
lemma open_Collect_less_Int:
fixes f g :: "'a::topological_space ⇒ real"
assumes f: "continuous_on s f"
and g: "continuous_on s g"
shows "∃A. open A ∧ A ∩ s = {x∈s. f x < g x}"
using open_Collect_positive[OF continuous_on_diff[OF g f]] by (simp add: field_simps)
subsection ‹Boundedness of continuous functions›
text‹By bisection, function continuous on closed interval is bounded above›
lemma isCont_eq_Ub:
fixes f :: "real ⇒ 'a::linorder_topology"
shows "a ≤ b ⟹ ∀x::real. a ≤ x ∧ x ≤ b ⟶ isCont f x ⟹
∃M. (∀x. a ≤ x ∧ x ≤ b ⟶ f x ≤ M) ∧ (∃x. a ≤ x ∧ x ≤ b ∧ f x = M)"
using continuous_attains_sup[of "{a..b}" f]
by (auto simp: continuous_at_imp_continuous_on Ball_def Bex_def)
lemma isCont_eq_Lb:
fixes f :: "real ⇒ 'a::linorder_topology"
shows "a ≤ b ⟹ ∀x. a ≤ x ∧ x ≤ b ⟶ isCont f x ⟹
∃M. (∀x. a ≤ x ∧ x ≤ b ⟶ M ≤ f x) ∧ (∃x. a ≤ x ∧ x ≤ b ∧ f x = M)"
using continuous_attains_inf[of "{a..b}" f]
by (auto simp: continuous_at_imp_continuous_on Ball_def Bex_def)
lemma isCont_bounded:
fixes f :: "real ⇒ 'a::linorder_topology"
shows "a ≤ b ⟹ ∀x. a ≤ x ∧ x ≤ b ⟶ isCont f x ⟹ ∃M. ∀x. a ≤ x ∧ x ≤ b ⟶ f x ≤ M"
using isCont_eq_Ub[of a b f] by auto
lemma isCont_has_Ub:
fixes f :: "real ⇒ 'a::linorder_topology"
shows "a ≤ b ⟹ ∀x. a ≤ x ∧ x ≤ b ⟶ isCont f x ⟹
∃M. (∀x. a ≤ x ∧ x ≤ b ⟶ f x ≤ M) ∧ (∀N. N < M ⟶ (∃x. a ≤ x ∧ x ≤ b ∧ N < f x))"
using isCont_eq_Ub[of a b f] by auto
lemma isCont_Lb_Ub:
fixes f :: "real ⇒ real"
assumes "a ≤ b" "∀x. a ≤ x ∧ x ≤ b ⟶ isCont f x"
shows "∃L M. (∀x. a ≤ x ∧ x ≤ b ⟶ L ≤ f x ∧ f x ≤ M) ∧
(∀y. L ≤ y ∧ y ≤ M ⟶ (∃x. a ≤ x ∧ x ≤ b ∧ (f x = y)))"
proof -
obtain M where M: "a ≤ M" "M ≤ b" "∀x. a ≤ x ∧ x ≤ b ⟶ f x ≤ f M"
using isCont_eq_Ub[OF assms] by auto
obtain L where L: "a ≤ L" "L ≤ b" "∀x. a ≤ x ∧ x ≤ b ⟶ f L ≤ f x"
using isCont_eq_Lb[OF assms] by auto
have "(∀x. a ≤ x ∧ x ≤ b ⟶ f L ≤ f x ∧ f x ≤ f M)"
using M L by simp
moreover
have "(∀y. f L ≤ y ∧ y ≤ f M ⟶ (∃x≥a. x ≤ b ∧ f x = y))"
proof (cases "L ≤ M")
case True then show ?thesis
using IVT[of f L _ M] M L assms by (metis order.trans)
next
case False then show ?thesis
using IVT2[of f L _ M]
by (metis L(2) M(1) assms(2) le_cases order.trans)
qed
ultimately show ?thesis
by blast
qed
text ‹Continuity of inverse function.›
lemma isCont_inverse_function:
fixes f g :: "real ⇒ real"
assumes d: "0 < d"
and inj: "⋀z. ¦z-x¦ ≤ d ⟹ g (f z) = z"
and cont: "⋀z. ¦z-x¦ ≤ d ⟹ isCont f z"
shows "isCont g (f x)"
proof -
let ?A = "f (x - d)"
let ?B = "f (x + d)"
let ?D = "{x - d..x + d}"
have f: "continuous_on ?D f"
using cont by (intro continuous_at_imp_continuous_on ballI) auto
then have g: "continuous_on (f`?D) g"
using inj by (intro continuous_on_inv) auto
from d f have "{min ?A ?B <..< max ?A ?B} ⊆ f ` ?D"
by (intro connected_contains_Ioo connected_continuous_image) (auto split: split_min split_max)
with g have "continuous_on {min ?A ?B <..< max ?A ?B} g"
by (rule continuous_on_subset)
moreover
have "(?A < f x ∧ f x < ?B) ∨ (?B < f x ∧ f x < ?A)"
using d inj by (intro continuous_inj_imp_mono[OF _ _ f] inj_on_imageI2[of g, OF inj_onI]) auto
then have "f x ∈ {min ?A ?B <..< max ?A ?B}"
by auto
ultimately show ?thesis
by (simp add: continuous_on_eq_continuous_at)
qed
lemma isCont_inverse_function2:
fixes f g :: "real ⇒ real"
shows
"⟦a < x; x < b;
⋀z. ⟦a ≤ z; z ≤ b⟧ ⟹ g (f z) = z;
⋀z. ⟦a ≤ z; z ≤ b⟧ ⟹ isCont f z⟧ ⟹ isCont g (f x)"
apply (rule isCont_inverse_function [where f=f and d="min (x - a) (b - x)"])
apply (simp_all add: abs_le_iff)
done
text ‹Bartle/Sherbert: Introduction to Real Analysis, Theorem 4.2.9, p. 110.›
lemma LIM_fun_gt_zero: "f ─c→ l ⟹ 0 < l ⟹ ∃r. 0 < r ∧ (∀x. x ≠ c ∧ ¦c - x¦ < r ⟶ 0 < f x)"
for f :: "real ⇒ real"
by (force simp: dest: LIM_D)
lemma LIM_fun_less_zero: "f ─c→ l ⟹ l < 0 ⟹ ∃r. 0 < r ∧ (∀x. x ≠ c ∧ ¦c - x¦ < r ⟶ f x < 0)"
for f :: "real ⇒ real"
by (drule LIM_D [where r="-l"]) force+
lemma LIM_fun_not_zero: "f ─c→ l ⟹ l ≠ 0 ⟹ ∃r. 0 < r ∧ (∀x. x ≠ c ∧ ¦c - x¦ < r ⟶ f x ≠ 0)"
for f :: "real ⇒ real"
using LIM_fun_gt_zero[of f l c] LIM_fun_less_zero[of f l c] by (auto simp: neq_iff)
lemma Lim_topological:
"(f ⤏ l) net ⟷
trivial_limit net ∨ (∀S. open S ⟶ l ∈ S ⟶ eventually (λx. f x ∈ S) net)"
unfolding tendsto_def trivial_limit_eq by auto
lemma eventually_within_Un:
"eventually P (at x within (s ∪ t)) ⟷
eventually P (at x within s) ∧ eventually P (at x within t)"
unfolding eventually_at_filter
by (auto elim!: eventually_rev_mp)
lemma Lim_within_Un:
"(f ⤏ l) (at x within (s ∪ t)) ⟷
(f ⤏ l) (at x within s) ∧ (f ⤏ l) (at x within t)"
unfolding tendsto_def
by (auto simp: eventually_within_Un)
end