Theory HOL-Analysis.Infinite_Products
section ‹Infinite Products›
theory Infinite_Products
imports Topology_Euclidean_Space Complex_Transcendental
begin
subsection ‹Preliminaries›
lemma sum_le_prod:
fixes f :: "'a ⇒ 'b :: linordered_semidom"
assumes "⋀x. x ∈ A ⟹ f x ≥ 0"
shows "sum f A ≤ (∏x∈A. 1 + f x)"
using assms
proof (induction A rule: infinite_finite_induct)
case (insert x A)
from insert.hyps have "sum f A + f x * (∏x∈A. 1) ≤ (∏x∈A. 1 + f x) + f x * (∏x∈A. 1 + f x)"
by (intro add_mono insert mult_left_mono prod_mono) (auto intro: insert.prems)
with insert.hyps show ?case by (simp add: algebra_simps)
qed simp_all
lemma prod_le_exp_sum:
fixes f :: "'a ⇒ real"
assumes "⋀x. x ∈ A ⟹ f x ≥ 0"
shows "prod (λx. 1 + f x) A ≤ exp (sum f A)"
using assms
proof (induction A rule: infinite_finite_induct)
case (insert x A)
have "(1 + f x) * (∏x∈A. 1 + f x) ≤ exp (f x) * exp (sum f A)"
using insert.prems by (intro mult_mono insert prod_nonneg exp_ge_add_one_self) auto
with insert.hyps show ?case by (simp add: algebra_simps exp_add)
qed simp_all
lemma lim_ln_1_plus_x_over_x_at_0: "(λx::real. ln (1 + x) / x) ─0→ 1"
proof (rule lhopital)
show "(λx::real. ln (1 + x)) ─0→ 0"
by (rule tendsto_eq_intros refl | simp)+
have "eventually (λx::real. x ∈ {-1/2<..<1/2}) (nhds 0)"
by (rule eventually_nhds_in_open) auto
hence *: "eventually (λx::real. x ∈ {-1/2<..<1/2}) (at 0)"
by (rule filter_leD [rotated]) (simp_all add: at_within_def)
show "eventually (λx::real. ((λx. ln (1 + x)) has_field_derivative inverse (1 + x)) (at x)) (at 0)"
using * by eventually_elim (auto intro!: derivative_eq_intros simp: field_simps)
show "eventually (λx::real. ((λx. x) has_field_derivative 1) (at x)) (at 0)"
using * by eventually_elim (auto intro!: derivative_eq_intros simp: field_simps)
show "∀⇩F x in at 0. x ≠ 0" by (auto simp: at_within_def eventually_inf_principal)
show "(λx::real. inverse (1 + x) / 1) ─0→ 1"
by (rule tendsto_eq_intros refl | simp)+
qed auto
subsection‹Definitions and basic properties›
definition raw_has_prod :: "[nat ⇒ 'a::{t2_space, comm_semiring_1}, nat, 'a] ⇒ bool"
where "raw_has_prod f M p ≡ (λn. ∏i≤n. f (i+M)) ⇢ p ∧ p ≠ 0"
text‹The nonzero and zero cases, as in \emph{Complex Analysis} by Joseph Bak and Donald J.Newman, page 241›
text ‹%whitespace›
definition
has_prod :: "(nat ⇒ 'a::{t2_space, comm_semiring_1}) ⇒ 'a ⇒ bool" (infixr "has'_prod" 80)
where "f has_prod p ≡ raw_has_prod f 0 p ∨ (∃i q. p = 0 ∧ f i = 0 ∧ raw_has_prod f (Suc i) q)"
definition convergent_prod :: "(nat ⇒ 'a :: {t2_space,comm_semiring_1}) ⇒ bool" where
"convergent_prod f ≡ ∃M p. raw_has_prod f M p"
definition prodinf :: "(nat ⇒ 'a::{t2_space, comm_semiring_1}) ⇒ 'a"
(binder "∏" 10)
where "prodinf f = (THE p. f has_prod p)"
lemmas prod_defs = raw_has_prod_def has_prod_def convergent_prod_def prodinf_def
lemma has_prod_subst[trans]: "f = g ⟹ g has_prod z ⟹ f has_prod z"
by simp
lemma has_prod_cong: "(⋀n. f n = g n) ⟹ f has_prod c ⟷ g has_prod c"
by presburger
lemma raw_has_prod_nonzero [simp]: "¬ raw_has_prod f M 0"
by (simp add: raw_has_prod_def)
lemma raw_has_prod_eq_0:
fixes f :: "nat ⇒ 'a::{semidom,t2_space}"
assumes p: "raw_has_prod f m p" and i: "f i = 0" "i ≥ m"
shows "p = 0"
proof -
have eq0: "(∏k≤n. f (k+m)) = 0" if "i - m ≤ n" for n
proof -
have "∃k≤n. f (k + m) = 0"
using i that by auto
then show ?thesis
by auto
qed
have "(λn. ∏i≤n. f (i + m)) ⇢ 0"
by (rule LIMSEQ_offset [where k = "i-m"]) (simp add: eq0)
with p show ?thesis
unfolding raw_has_prod_def
using LIMSEQ_unique by blast
qed
lemma raw_has_prod_Suc:
"raw_has_prod f (Suc M) a ⟷ raw_has_prod (λn. f (Suc n)) M a"
unfolding raw_has_prod_def by auto
lemma has_prod_0_iff: "f has_prod 0 ⟷ (∃i. f i = 0 ∧ (∃p. raw_has_prod f (Suc i) p))"
by (simp add: has_prod_def)
lemma has_prod_unique2:
fixes f :: "nat ⇒ 'a::{semidom,t2_space}"
assumes "f has_prod a" "f has_prod b" shows "a = b"
using assms
by (auto simp: has_prod_def raw_has_prod_eq_0) (meson raw_has_prod_def sequentially_bot tendsto_unique)
lemma has_prod_unique:
fixes f :: "nat ⇒ 'a :: {semidom,t2_space}"
shows "f has_prod s ⟹ s = prodinf f"
by (simp add: has_prod_unique2 prodinf_def the_equality)
lemma has_prod_eq_0_iff:
fixes f :: "nat ⇒ 'a :: {semidom, comm_semiring_1, t2_space}"
assumes "f has_prod P"
shows "P = 0 ⟷ 0 ∈ range f"
proof
assume "0 ∈ range f"
then obtain N where N: "f N = 0"
by auto
have "eventually (λn. n > N) at_top"
by (rule eventually_gt_at_top)
hence "eventually (λn. (∏k<n. f k) = 0) at_top"
by eventually_elim (use N in auto)
hence "(λn. ∏k<n. f k) ⇢ 0"
by (simp add: tendsto_eventually)
moreover have "(λn. ∏k<n. f k) ⇢ P"
using assms by (metis N calculation prod_defs(2) raw_has_prod_eq_0 zero_le)
ultimately show "P = 0"
using tendsto_unique by force
qed (use assms in ‹auto simp: has_prod_def›)
lemma has_prod_0D:
fixes f :: "nat ⇒ 'a :: {semidom, comm_semiring_1, t2_space}"
shows "f has_prod 0 ⟹ 0 ∈ range f"
using has_prod_eq_0_iff[of f 0] by auto
lemma has_prod_zeroI:
fixes f :: "nat ⇒ 'a :: {semidom, comm_semiring_1, t2_space}"
assumes "f has_prod P" "f n = 0"
shows "P = 0"
using assms by (auto simp: has_prod_eq_0_iff)
lemma raw_has_prod_in_Reals:
assumes "raw_has_prod (complex_of_real ∘ z) M p"
shows "p ∈ ℝ"
using assms by (auto simp: raw_has_prod_def real_lim_sequentially)
lemma raw_has_prod_of_real_iff: "raw_has_prod (complex_of_real ∘ z) M (of_real p) ⟷ raw_has_prod z M p"
by (auto simp: raw_has_prod_def tendsto_of_real_iff simp flip: of_real_prod)
lemma convergent_prod_of_real_iff: "convergent_prod (complex_of_real ∘ z) ⟷ convergent_prod z"
by (smt (verit, best) Reals_cases convergent_prod_def raw_has_prod_in_Reals raw_has_prod_of_real_iff)
lemma convergent_prod_altdef:
fixes f :: "nat ⇒ 'a :: {t2_space,comm_semiring_1}"
shows "convergent_prod f ⟷ (∃M L. (∀n≥M. f n ≠ 0) ∧ (λn. ∏i≤n. f (i+M)) ⇢ L ∧ L ≠ 0)"
proof
assume "convergent_prod f"
then obtain M L where *: "(λn. ∏i≤n. f (i+M)) ⇢ L" "L ≠ 0"
by (auto simp: prod_defs)
have "f i ≠ 0" if "i ≥ M" for i
proof
assume "f i = 0"
have **: "eventually (λn. (∏i≤n. f (i+M)) = 0) sequentially"
using eventually_ge_at_top[of "i - M"]
proof eventually_elim
case (elim n)
with ‹f i = 0› and ‹i ≥ M› show ?case
by (auto intro!: bexI[of _ "i - M"] prod_zero)
qed
have "(λn. (∏i≤n. f (i+M))) ⇢ 0"
unfolding filterlim_iff
by (auto dest!: eventually_nhds_x_imp_x intro!: eventually_mono[OF **])
from tendsto_unique[OF _ this *(1)] and *(2)
show False by simp
qed
with * show "(∃M L. (∀n≥M. f n ≠ 0) ∧ (λn. ∏i≤n. f (i+M)) ⇢ L ∧ L ≠ 0)"
by blast
qed (auto simp: prod_defs)
lemma raw_has_prod_norm:
fixes a :: "'a ::real_normed_field"
assumes "raw_has_prod f M a"
shows "raw_has_prod (λn. norm (f n)) M (norm a)"
using assms by (auto simp: raw_has_prod_def prod_norm tendsto_norm)
lemma has_prod_norm:
fixes a :: "'a ::real_normed_field"
assumes f: "f has_prod a"
shows "(λn. norm (f n)) has_prod (norm a)"
using f [unfolded has_prod_def]
proof (elim disjE exE conjE)
assume f0: "raw_has_prod f 0 a"
then show "(λn. norm (f n)) has_prod norm a"
using has_prod_def raw_has_prod_norm by blast
next
fix i p
assume "a = 0" and "f i = 0" and p: "raw_has_prod f (Suc i) p"
then have "Ex (raw_has_prod (λn. norm (f n)) (Suc i))"
using raw_has_prod_norm by blast
then show ?thesis
by (metis ‹a = 0› ‹f i = 0› has_prod_0_iff norm_zero)
qed
subsection‹Absolutely convergent products›
definition abs_convergent_prod :: "(nat ⇒ _) ⇒ bool" where
"abs_convergent_prod f ⟷ convergent_prod (λi. 1 + norm (f i - 1))"
lemma abs_convergent_prodI:
assumes "convergent (λn. ∏i≤n. 1 + norm (f i - 1))"
shows "abs_convergent_prod f"
proof -
from assms obtain L where L: "(λn. ∏i≤n. 1 + norm (f i - 1)) ⇢ L"
by (auto simp: convergent_def)
have "L ≥ 1"
proof (rule tendsto_le)
show "eventually (λn. (∏i≤n. 1 + norm (f i - 1)) ≥ 1) sequentially"
proof (intro always_eventually allI)
fix n
have "(∏i≤n. 1 + norm (f i - 1)) ≥ (∏i≤n. 1)"
by (intro prod_mono) auto
thus "(∏i≤n. 1 + norm (f i - 1)) ≥ 1" by simp
qed
qed (use L in simp_all)
hence "L ≠ 0" by auto
with L show ?thesis unfolding abs_convergent_prod_def prod_defs
by (intro exI[of _ "0::nat"] exI[of _ L]) auto
qed
lemma
fixes f :: "nat ⇒ 'a :: {topological_semigroup_mult,t2_space,idom}"
assumes "convergent_prod f"
shows convergent_prod_imp_convergent: "convergent (λn. ∏i≤n. f i)"
and convergent_prod_to_zero_iff [simp]: "(λn. ∏i≤n. f i) ⇢ 0 ⟷ (∃i. f i = 0)"
proof -
from assms obtain M L
where M: "⋀n. n ≥ M ⟹ f n ≠ 0" and "(λn. ∏i≤n. f (i + M)) ⇢ L" and "L ≠ 0"
by (auto simp: convergent_prod_altdef)
note this(2)
also have "(λn. ∏i≤n. f (i + M)) = (λn. ∏i=M..M+n. f i)"
by (intro ext prod.reindex_bij_witness[of _ "λn. n - M" "λn. n + M"]) auto
finally have "(λn. (∏i<M. f i) * (∏i=M..M+n. f i)) ⇢ (∏i<M. f i) * L"
by (intro tendsto_mult tendsto_const)
also have "(λn. (∏i<M. f i) * (∏i=M..M+n. f i)) = (λn. (∏i∈{..<M}∪{M..M+n}. f i))"
by (subst prod.union_disjoint) auto
also have "(λn. {..<M} ∪ {M..M+n}) = (λn. {..n+M})" by auto
finally have lim: "(λn. prod f {..n}) ⇢ prod f {..<M} * L"
by (rule LIMSEQ_offset)
thus "convergent (λn. ∏i≤n. f i)"
by (auto simp: convergent_def)
show "(λn. ∏i≤n. f i) ⇢ 0 ⟷ (∃i. f i = 0)"
proof
assume "∃i. f i = 0"
then obtain i where "f i = 0" by auto
moreover with M have "i < M" by (cases "i < M") auto
ultimately have "(∏i<M. f i) = 0" by auto
with lim show "(λn. ∏i≤n. f i) ⇢ 0" by simp
next
assume "(λn. ∏i≤n. f i) ⇢ 0"
from tendsto_unique[OF _ this lim] and ‹L ≠ 0›
show "∃i. f i = 0" by auto
qed
qed
lemma convergent_prod_iff_nz_lim:
fixes f :: "nat ⇒ 'a :: {topological_semigroup_mult,t2_space,idom}"
assumes "⋀i. f i ≠ 0"
shows "convergent_prod f ⟷ (∃L. (λn. ∏i≤n. f i) ⇢ L ∧ L ≠ 0)"
(is "?lhs ⟷ ?rhs")
proof
assume ?lhs then show ?rhs
using assms convergentD convergent_prod_imp_convergent convergent_prod_to_zero_iff by blast
next
assume ?rhs then show ?lhs
unfolding prod_defs
by (rule_tac x=0 in exI) auto
qed
lemma convergent_prod_iff_convergent:
fixes f :: "nat ⇒ 'a :: {topological_semigroup_mult,t2_space,idom}"
assumes "⋀i. f i ≠ 0"
shows "convergent_prod f ⟷ convergent (λn. ∏i≤n. f i) ∧ lim (λn. ∏i≤n. f i) ≠ 0"
by (force simp: convergent_prod_iff_nz_lim assms convergent_def limI)
lemma bounded_imp_convergent_prod:
fixes a :: "nat ⇒ real"
assumes 1: "⋀n. a n ≥ 1" and bounded: "⋀n. (∏i≤n. a i) ≤ B"
shows "convergent_prod a"
proof -
have "bdd_above (range(λn. ∏i≤n. a i))"
by (meson bdd_aboveI2 bounded)
moreover have "incseq (λn. ∏i≤n. a i)"
unfolding mono_def by (metis 1 prod_mono2 atMost_subset_iff dual_order.trans finite_atMost zero_le_one)
ultimately obtain p where p: "(λn. ∏i≤n. a i) ⇢ p"
using LIMSEQ_incseq_SUP by blast
then have "p ≠ 0"
by (metis "1" not_one_le_zero prod_ge_1 LIMSEQ_le_const)
with 1 p show ?thesis
by (metis convergent_prod_iff_nz_lim not_one_le_zero)
qed
lemma abs_convergent_prod_altdef:
fixes f :: "nat ⇒ 'a :: {one,real_normed_vector}"
shows "abs_convergent_prod f ⟷ convergent (λn. ∏i≤n. 1 + norm (f i - 1))"
proof
assume "abs_convergent_prod f"
thus "convergent (λn. ∏i≤n. 1 + norm (f i - 1))"
by (auto simp: abs_convergent_prod_def intro!: convergent_prod_imp_convergent)
qed (auto intro: abs_convergent_prodI)
lemma Weierstrass_prod_ineq:
fixes f :: "'a ⇒ real"
assumes "⋀x. x ∈ A ⟹ f x ∈ {0..1}"
shows "1 - sum f A ≤ (∏x∈A. 1 - f x)"
using assms
proof (induction A rule: infinite_finite_induct)
case (insert x A)
from insert.hyps and insert.prems
have "1 - sum f A + f x * (∏x∈A. 1 - f x) ≤ (∏x∈A. 1 - f x) + f x * (∏x∈A. 1)"
by (intro insert.IH add_mono mult_left_mono prod_mono) auto
with insert.hyps show ?case by (simp add: algebra_simps)
qed simp_all
lemma norm_prod_minus1_le_prod_minus1:
fixes f :: "nat ⇒ 'a :: {real_normed_div_algebra,comm_ring_1}"
shows "norm (prod (λn. 1 + f n) A - 1) ≤ prod (λn. 1 + norm (f n)) A - 1"
proof (induction A rule: infinite_finite_induct)
case (insert x A)
from insert.hyps have
"norm ((∏n∈insert x A. 1 + f n) - 1) =
norm ((∏n∈A. 1 + f n) - 1 + f x * (∏n∈A. 1 + f n))"
by (simp add: algebra_simps)
also have "… ≤ norm ((∏n∈A. 1 + f n) - 1) + norm (f x * (∏n∈A. 1 + f n))"
by (rule norm_triangle_ineq)
also have "norm (f x * (∏n∈A. 1 + f n)) = norm (f x) * (∏x∈A. norm (1 + f x))"
by (simp add: prod_norm norm_mult)
also have "(∏x∈A. norm (1 + f x)) ≤ (∏x∈A. norm (1::'a) + norm (f x))"
by (intro prod_mono norm_triangle_ineq ballI conjI) auto
also have "norm (1::'a) = 1" by simp
also note insert.IH
also have "(∏n∈A. 1 + norm (f n)) - 1 + norm (f x) * (∏x∈A. 1 + norm (f x)) =
(∏n∈insert x A. 1 + norm (f n)) - 1"
using insert.hyps by (simp add: algebra_simps)
finally show ?case by - (simp_all add: mult_left_mono)
qed simp_all
lemma convergent_prod_imp_ev_nonzero:
fixes f :: "nat ⇒ 'a :: {t2_space,comm_semiring_1}"
assumes "convergent_prod f"
shows "eventually (λn. f n ≠ 0) sequentially"
using assms by (auto simp: eventually_at_top_linorder convergent_prod_altdef)
lemma convergent_prod_imp_LIMSEQ:
fixes f :: "nat ⇒ 'a :: {real_normed_field}"
assumes "convergent_prod f"
shows "f ⇢ 1"
proof -
from assms obtain M L where L: "(λn. ∏i≤n. f (i+M)) ⇢ L" "⋀n. n ≥ M ⟹ f n ≠ 0" "L ≠ 0"
by (auto simp: convergent_prod_altdef)
hence L': "(λn. ∏i≤Suc n. f (i+M)) ⇢ L" by (subst filterlim_sequentially_Suc)
have "(λn. (∏i≤Suc n. f (i+M)) / (∏i≤n. f (i+M))) ⇢ L / L"
using L L' by (intro tendsto_divide) simp_all
also from L have "L / L = 1" by simp
also have "(λn. (∏i≤Suc n. f (i+M)) / (∏i≤n. f (i+M))) = (λn. f (n + Suc M))"
using assms L by (auto simp: fun_eq_iff atMost_Suc)
finally show ?thesis by (rule LIMSEQ_offset)
qed
lemma abs_convergent_prod_imp_summable:
fixes f :: "nat ⇒ 'a :: real_normed_div_algebra"
assumes "abs_convergent_prod f"
shows "summable (λi. norm (f i - 1))"
proof -
from assms have "convergent (λn. ∏i≤n. 1 + norm (f i - 1))"
unfolding abs_convergent_prod_def by (rule convergent_prod_imp_convergent)
then obtain L where L: "(λn. ∏i≤n. 1 + norm (f i - 1)) ⇢ L"
unfolding convergent_def by blast
have "convergent (λn. ∑i≤n. norm (f i - 1))"
proof (rule Bseq_monoseq_convergent)
have "eventually (λn. (∏i≤n. 1 + norm (f i - 1)) < L + 1) sequentially"
using L(1) by (rule order_tendstoD) simp_all
hence "∀⇩F x in sequentially. norm (∑i≤x. norm (f i - 1)) ≤ L + 1"
proof eventually_elim
case (elim n)
have "norm (∑i≤n. norm (f i - 1)) = (∑i≤n. norm (f i - 1))"
unfolding real_norm_def by (intro abs_of_nonneg sum_nonneg) simp_all
also have "… ≤ (∏i≤n. 1 + norm (f i - 1))" by (rule sum_le_prod) auto
also have "… < L + 1" by (rule elim)
finally show ?case by simp
qed
thus "Bseq (λn. ∑i≤n. norm (f i - 1))" by (rule BfunI)
next
show "monoseq (λn. ∑i≤n. norm (f i - 1))"
by (rule mono_SucI1) auto
qed
thus "summable (λi. norm (f i - 1))" by (simp add: summable_iff_convergent')
qed
lemma summable_imp_abs_convergent_prod:
fixes f :: "nat ⇒ 'a :: real_normed_div_algebra"
assumes "summable (λi. norm (f i - 1))"
shows "abs_convergent_prod f"
proof (intro abs_convergent_prodI Bseq_monoseq_convergent)
show "monoseq (λn. ∏i≤n. 1 + norm (f i - 1))"
by (intro mono_SucI1)
(auto simp: atMost_Suc algebra_simps intro!: mult_nonneg_nonneg prod_nonneg)
next
show "Bseq (λn. ∏i≤n. 1 + norm (f i - 1))"
proof (rule Bseq_eventually_mono)
show "eventually (λn. norm (∏i≤n. 1 + norm (f i - 1)) ≤
norm (exp (∑i≤n. norm (f i - 1)))) sequentially"
by (intro always_eventually allI) (auto simp: abs_prod exp_sum intro!: prod_mono)
next
from assms have "(λn. ∑i≤n. norm (f i - 1)) ⇢ (∑i. norm (f i - 1))"
using sums_def_le by blast
hence "(λn. exp (∑i≤n. norm (f i - 1))) ⇢ exp (∑i. norm (f i - 1))"
by (rule tendsto_exp)
hence "convergent (λn. exp (∑i≤n. norm (f i - 1)))"
by (rule convergentI)
thus "Bseq (λn. exp (∑i≤n. norm (f i - 1)))"
by (rule convergent_imp_Bseq)
qed
qed
theorem abs_convergent_prod_conv_summable:
fixes f :: "nat ⇒ 'a :: real_normed_div_algebra"
shows "abs_convergent_prod f ⟷ summable (λi. norm (f i - 1))"
by (blast intro: abs_convergent_prod_imp_summable summable_imp_abs_convergent_prod)
lemma abs_convergent_prod_imp_LIMSEQ:
fixes f :: "nat ⇒ 'a :: {comm_ring_1,real_normed_div_algebra}"
assumes "abs_convergent_prod f"
shows "f ⇢ 1"
proof -
from assms have "summable (λn. norm (f n - 1))"
by (rule abs_convergent_prod_imp_summable)
from summable_LIMSEQ_zero[OF this] have "(λn. f n - 1) ⇢ 0"
by (simp add: tendsto_norm_zero_iff)
from tendsto_add[OF this tendsto_const[of 1]] show ?thesis by simp
qed
lemma abs_convergent_prod_imp_ev_nonzero:
fixes f :: "nat ⇒ 'a :: {comm_ring_1,real_normed_div_algebra}"
assumes "abs_convergent_prod f"
shows "eventually (λn. f n ≠ 0) sequentially"
proof -
from assms have "f ⇢ 1"
by (rule abs_convergent_prod_imp_LIMSEQ)
hence "eventually (λn. dist (f n) 1 < 1) at_top"
by (auto simp: tendsto_iff)
thus ?thesis by eventually_elim auto
qed
subsection ‹Ignoring initial segments›
lemma convergent_prod_offset:
assumes "convergent_prod (λn. f (n + m))"
shows "convergent_prod f"
proof -
from assms obtain M L where "(λn. ∏k≤n. f (k + (M + m))) ⇢ L" "L ≠ 0"
by (auto simp: prod_defs add.assoc)
thus "convergent_prod f"
unfolding prod_defs by blast
qed
lemma abs_convergent_prod_offset:
assumes "abs_convergent_prod (λn. f (n + m))"
shows "abs_convergent_prod f"
using assms unfolding abs_convergent_prod_def by (rule convergent_prod_offset)
lemma raw_has_prod_ignore_initial_segment:
fixes f :: "nat ⇒ 'a :: real_normed_field"
assumes "raw_has_prod f M p" "N ≥ M"
obtains q where "raw_has_prod f N q"
proof -
have p: "(λn. ∏k≤n. f (k + M)) ⇢ p" and "p ≠ 0"
using assms by (auto simp: raw_has_prod_def)
then have nz: "⋀n. n ≥ M ⟹ f n ≠ 0"
using assms by (auto simp: raw_has_prod_eq_0)
define C where "C = (∏k<N-M. f (k + M))"
from nz have [simp]: "C ≠ 0"
by (auto simp: C_def)
from p have "(λi. ∏k≤i + (N-M). f (k + M)) ⇢ p"
by (rule LIMSEQ_ignore_initial_segment)
also have "(λi. ∏k≤i + (N-M). f (k + M)) = (λn. C * (∏k≤n. f (k + N)))"
proof (rule ext, goal_cases)
case (1 n)
have "{..n+(N-M)} = {..<(N-M)} ∪ {(N-M)..n+(N-M)}" by auto
also have "(∏k∈…. f (k + M)) = C * (∏k=(N-M)..n+(N-M). f (k + M))"
unfolding C_def by (rule prod.union_disjoint) auto
also have "(∏k=(N-M)..n+(N-M). f (k + M)) = (∏k≤n. f (k + (N-M) + M))"
by (intro ext prod.reindex_bij_witness[of _ "λk. k + (N-M)" "λk. k - (N-M)"]) auto
finally show ?case
using ‹N ≥ M› by (simp add: add_ac)
qed
finally have "(λn. C * (∏k≤n. f (k + N)) / C) ⇢ p / C"
by (intro tendsto_divide tendsto_const) auto
hence "(λn. ∏k≤n. f (k + N)) ⇢ p / C" by simp
moreover from ‹p ≠ 0› have "p / C ≠ 0" by simp
ultimately show ?thesis
using raw_has_prod_def that by blast
qed
corollary convergent_prod_ignore_initial_segment:
fixes f :: "nat ⇒ 'a :: real_normed_field"
assumes "convergent_prod f"
shows "convergent_prod (λn. f (n + m))"
using assms
unfolding convergent_prod_def
apply clarify
apply (erule_tac N="M+m" in raw_has_prod_ignore_initial_segment)
apply (auto simp add: raw_has_prod_def add_ac)
done
corollary convergent_prod_ignore_nonzero_segment:
fixes f :: "nat ⇒ 'a :: real_normed_field"
assumes f: "convergent_prod f" and nz: "⋀i. i ≥ M ⟹ f i ≠ 0"
shows "∃p. raw_has_prod f M p"
using convergent_prod_ignore_initial_segment [OF f]
by (metis convergent_LIMSEQ_iff convergent_prod_iff_convergent le_add_same_cancel2 nz prod_defs(1) zero_order(1))
corollary abs_convergent_prod_ignore_initial_segment:
assumes "abs_convergent_prod f"
shows "abs_convergent_prod (λn. f (n + m))"
using assms unfolding abs_convergent_prod_def
by (rule convergent_prod_ignore_initial_segment)
subsection‹More elementary properties›
theorem abs_convergent_prod_imp_convergent_prod:
fixes f :: "nat ⇒ 'a :: {real_normed_div_algebra,complete_space,comm_ring_1}"
assumes "abs_convergent_prod f"
shows "convergent_prod f"
proof -
from assms have "eventually (λn. f n ≠ 0) sequentially"
by (rule abs_convergent_prod_imp_ev_nonzero)
then obtain N where N: "f n ≠ 0" if "n ≥ N" for n
by (auto simp: eventually_at_top_linorder)
let ?P = "λn. ∏i≤n. f (i + N)" and ?Q = "λn. ∏i≤n. 1 + norm (f (i + N) - 1)"
have "Cauchy ?P"
proof (rule CauchyI', goal_cases)
case (1 ε)
from assms have "abs_convergent_prod (λn. f (n + N))"
by (rule abs_convergent_prod_ignore_initial_segment)
hence "Cauchy ?Q"
unfolding abs_convergent_prod_def
by (intro convergent_Cauchy convergent_prod_imp_convergent)
from CauchyD[OF this 1] obtain M where M: "norm (?Q m - ?Q n) < ε" if "m ≥ M" "n ≥ M" for m n
by blast
show ?case
proof (rule exI[of _ M], safe, goal_cases)
case (1 m n)
have "dist (?P m) (?P n) = norm (?P n - ?P m)"
by (simp add: dist_norm norm_minus_commute)
also from 1 have "{..n} = {..m} ∪ {m<..n}" by auto
hence "norm (?P n - ?P m) = norm (?P m * (∏k∈{m<..n}. f (k + N)) - ?P m)"
by (subst prod.union_disjoint [symmetric]) (auto simp: algebra_simps)
also have "… = norm (?P m * ((∏k∈{m<..n}. f (k + N)) - 1))"
by (simp add: algebra_simps)
also have "… = (∏k≤m. norm (f (k + N))) * norm ((∏k∈{m<..n}. f (k + N)) - 1)"
by (simp add: norm_mult prod_norm)
also have "… ≤ ?Q m * ((∏k∈{m<..n}. 1 + norm (f (k + N) - 1)) - 1)"
using norm_prod_minus1_le_prod_minus1[of "λk. f (k + N) - 1" "{m<..n}"]
norm_triangle_ineq[of 1 "f k - 1" for k]
by (intro mult_mono prod_mono ballI conjI norm_prod_minus1_le_prod_minus1 prod_nonneg) auto
also have "… = ?Q m * (∏k∈{m<..n}. 1 + norm (f (k + N) - 1)) - ?Q m"
by (simp add: algebra_simps)
also have "?Q m * (∏k∈{m<..n}. 1 + norm (f (k + N) - 1)) =
(∏k∈{..m}∪{m<..n}. 1 + norm (f (k + N) - 1))"
by (rule prod.union_disjoint [symmetric]) auto
also from 1 have "{..m}∪{m<..n} = {..n}" by auto
also have "?Q n - ?Q m ≤ norm (?Q n - ?Q m)" by simp
also from 1 have "… < ε" by (intro M) auto
finally show ?case .
qed
qed
hence conv: "convergent ?P" by (rule Cauchy_convergent)
then obtain L where L: "?P ⇢ L"
by (auto simp: convergent_def)
have "L ≠ 0"
proof
assume [simp]: "L = 0"
from tendsto_norm[OF L] have limit: "(λn. ∏k≤n. norm (f (k + N))) ⇢ 0"
by (simp add: prod_norm)
from assms have "(λn. f (n + N)) ⇢ 1"
by (intro abs_convergent_prod_imp_LIMSEQ abs_convergent_prod_ignore_initial_segment)
hence "eventually (λn. norm (f (n + N) - 1) < 1) sequentially"
by (auto simp: tendsto_iff dist_norm)
then obtain M0 where M0: "norm (f (n + N) - 1) < 1" if "n ≥ M0" for n
by (auto simp: eventually_at_top_linorder)
{
fix M assume M: "M ≥ M0"
with M0 have M: "norm (f (n + N) - 1) < 1" if "n ≥ M" for n using that by simp
have "(λn. ∏k≤n. 1 - norm (f (k+M+N) - 1)) ⇢ 0"
proof (rule tendsto_sandwich)
show "eventually (λn. (∏k≤n. 1 - norm (f (k+M+N) - 1)) ≥ 0) sequentially"
using M by (intro always_eventually prod_nonneg allI ballI) (auto intro: less_imp_le)
have "norm (1::'a) - norm (f (i + M + N) - 1) ≤ norm (f (i + M + N))" for i
using norm_triangle_ineq3[of "f (i + M + N)" 1] by simp
thus "eventually (λn. (∏k≤n. 1 - norm (f (k+M+N) - 1)) ≤ (∏k≤n. norm (f (k+M+N)))) at_top"
using M by (intro always_eventually allI prod_mono ballI conjI) (auto intro: less_imp_le)
define C where "C = (∏k<M. norm (f (k + N)))"
from N have [simp]: "C ≠ 0" by (auto simp: C_def)
from L have "(λn. norm (∏k≤n+M. f (k + N))) ⇢ 0"
by (intro LIMSEQ_ignore_initial_segment) (simp add: tendsto_norm_zero_iff)
also have "(λn. norm (∏k≤n+M. f (k + N))) = (λn. C * (∏k≤n. norm (f (k + M + N))))"
proof (rule ext, goal_cases)
case (1 n)
have "{..n+M} = {..<M} ∪ {M..n+M}" by auto
also have "norm (∏k∈…. f (k + N)) = C * norm (∏k=M..n+M. f (k + N))"
unfolding C_def by (subst prod.union_disjoint) (auto simp: norm_mult prod_norm)
also have "(∏k=M..n+M. f (k + N)) = (∏k≤n. f (k + N + M))"
by (intro prod.reindex_bij_witness[of _ "λi. i + M" "λi. i - M"]) auto
finally show ?case by (simp add: add_ac prod_norm)
qed
finally have "(λn. C * (∏k≤n. norm (f (k + M + N))) / C) ⇢ 0 / C"
by (intro tendsto_divide tendsto_const) auto
thus "(λn. ∏k≤n. norm (f (k + M + N))) ⇢ 0" by simp
qed simp_all
have "1 - (∑i. norm (f (i + M + N) - 1)) ≤ 0"
proof (rule tendsto_le)
show "eventually (λn. 1 - (∑k≤n. norm (f (k+M+N) - 1)) ≤
(∏k≤n. 1 - norm (f (k+M+N) - 1))) at_top"
using M by (intro always_eventually allI Weierstrass_prod_ineq) (auto intro: less_imp_le)
show "(λn. ∏k≤n. 1 - norm (f (k+M+N) - 1)) ⇢ 0" by fact
show "(λn. 1 - (∑k≤n. norm (f (k + M + N) - 1)))
⇢ 1 - (∑i. norm (f (i + M + N) - 1))"
by (intro tendsto_intros summable_LIMSEQ' summable_ignore_initial_segment
abs_convergent_prod_imp_summable assms)
qed simp_all
hence "(∑i. norm (f (i + M + N) - 1)) ≥ 1" by simp
also have "… + (∑i<M. norm (f (i + N) - 1)) = (∑i. norm (f (i + N) - 1))"
by (intro suminf_split_initial_segment [symmetric] summable_ignore_initial_segment
abs_convergent_prod_imp_summable assms)
finally have "1 + (∑i<M. norm (f (i + N) - 1)) ≤ (∑i. norm (f (i + N) - 1))" by simp
} note * = this
have "1 + (∑i. norm (f (i + N) - 1)) ≤ (∑i. norm (f (i + N) - 1))"
proof (rule tendsto_le)
show "(λM. 1 + (∑i<M. norm (f (i + N) - 1))) ⇢ 1 + (∑i. norm (f (i + N) - 1))"
by (intro tendsto_intros summable_LIMSEQ summable_ignore_initial_segment
abs_convergent_prod_imp_summable assms)
show "eventually (λM. 1 + (∑i<M. norm (f (i + N) - 1)) ≤ (∑i. norm (f (i + N) - 1))) at_top"
using eventually_ge_at_top[of M0] by eventually_elim (use * in auto)
qed simp_all
thus False by simp
qed
with L show ?thesis by (auto simp: prod_defs)
qed
lemma raw_has_prod_cases:
fixes f :: "nat ⇒ 'a :: {idom,topological_semigroup_mult,t2_space}"
assumes "raw_has_prod f M p"
obtains i where "i<M" "f i = 0" | p where "raw_has_prod f 0 p"
proof -
have "(λn. ∏i≤n. f (i + M)) ⇢ p" "p ≠ 0"
using assms unfolding raw_has_prod_def by blast+
then have "(λn. prod f {..<M} * (∏i≤n. f (i + M))) ⇢ prod f {..<M} * p"
by (metis tendsto_mult_left)
moreover have "prod f {..<M} * (∏i≤n. f (i + M)) = prod f {..n+M}" for n
proof -
have "{..n+M} = {..<M} ∪ {M..n+M}"
by auto
then have "prod f {..n+M} = prod f {..<M} * prod f {M..n+M}"
by simp (subst prod.union_disjoint; force)
also have "… = prod f {..<M} * (∏i≤n. f (i + M))"
by (metis (mono_tags, lifting) add.left_neutral atMost_atLeast0 prod.shift_bounds_cl_nat_ivl)
finally show ?thesis by metis
qed
ultimately have "(λn. prod f {..n}) ⇢ prod f {..<M} * p"
by (auto intro: LIMSEQ_offset [where k=M])
then have "raw_has_prod f 0 (prod f {..<M} * p)" if "∀i<M. f i ≠ 0"
using ‹p ≠ 0› assms that by (auto simp: raw_has_prod_def)
then show thesis
using that by blast
qed
corollary convergent_prod_offset_0:
fixes f :: "nat ⇒ 'a :: {idom,topological_semigroup_mult,t2_space}"
assumes "convergent_prod f" "⋀i. f i ≠ 0"
shows "∃p. raw_has_prod f 0 p"
using assms convergent_prod_def raw_has_prod_cases by blast
lemma prodinf_eq_lim:
fixes f :: "nat ⇒ 'a :: {idom,topological_semigroup_mult,t2_space}"
assumes "convergent_prod f" "⋀i. f i ≠ 0"
shows "prodinf f = lim (λn. ∏i≤n. f i)"
using assms convergent_prod_offset_0 [OF assms]
by (simp add: prod_defs lim_def) (metis (no_types) assms(1) convergent_prod_to_zero_iff)
lemma prodinf_eq_lim':
fixes f :: "nat ⇒ 'a :: {idom,topological_semigroup_mult,t2_space}"
assumes "convergent_prod f" "⋀i. f i ≠ 0"
shows "prodinf f = lim (λn. ∏i<n. f i)"
by (metis assms prodinf_eq_lim LIMSEQ_lessThan_iff_atMost convergent_prod_iff_nz_lim limI)
lemma prodinf_eq_prod_lim:
fixes a:: "'a :: {topological_semigroup_mult,t2_space,idom}"
assumes "(λn. ∏k≤n. f k) ⇢ a" "a ≠ 0"
shows"(∏k. f k) = a"
by (metis LIMSEQ_prod_0 LIMSEQ_unique assms convergent_prod_iff_nz_lim limI prodinf_eq_lim)
lemma prodinf_eq_prod_lim':
fixes a:: "'a :: {topological_semigroup_mult,t2_space,idom}"
assumes "(λn. ∏k<n. f k) ⇢ a" "a ≠ 0"
shows"(∏k. f k) = a"
using LIMSEQ_lessThan_iff_atMost assms prodinf_eq_prod_lim by blast
lemma has_prod_one[simp, intro]: "(λn. 1) has_prod 1"
unfolding prod_defs by auto
lemma convergent_prod_one[simp, intro]: "convergent_prod (λn. 1)"
unfolding prod_defs by auto
lemma prodinf_cong: "(⋀n. f n = g n) ⟹ prodinf f = prodinf g"
by presburger
lemma convergent_prod_cong:
fixes f g :: "nat ⇒ 'a::{field,topological_semigroup_mult,t2_space}"
assumes ev: "eventually (λx. f x = g x) sequentially" and f: "⋀i. f i ≠ 0" and g: "⋀i. g i ≠ 0"
shows "convergent_prod f = convergent_prod g"
proof -
from assms obtain N where N: "∀n≥N. f n = g n"
by (auto simp: eventually_at_top_linorder)
define C where "C = (∏k<N. f k / g k)"
with g have "C ≠ 0"
by (simp add: f)
have *: "eventually (λn. prod f {..n} = C * prod g {..n}) sequentially"
using eventually_ge_at_top[of N]
proof eventually_elim
case (elim n)
then have "{..n} = {..<N} ∪ {N..n}"
by auto
also have "prod f … = prod f {..<N} * prod f {N..n}"
by (intro prod.union_disjoint) auto
also from N have "prod f {N..n} = prod g {N..n}"
by (intro prod.cong) simp_all
also have "prod f {..<N} * prod g {N..n} = C * (prod g {..<N} * prod g {N..n})"
unfolding C_def by (simp add: g prod_dividef)
also have "prod g {..<N} * prod g {N..n} = prod g ({..<N} ∪ {N..n})"
by (intro prod.union_disjoint [symmetric]) auto
also from elim have "{..<N} ∪ {N..n} = {..n}"
by auto
finally show "prod f {..n} = C * prod g {..n}" .
qed
then have cong: "convergent (λn. prod f {..n}) = convergent (λn. C * prod g {..n})"
by (rule convergent_cong)
show ?thesis
proof
assume cf: "convergent_prod f"
with f have "¬ (λn. prod f {..n}) ⇢ 0"
by simp
then have "¬ (λn. prod g {..n}) ⇢ 0"
using * ‹C ≠ 0› filterlim_cong by fastforce
then show "convergent_prod g"
by (metis convergent_mult_const_iff ‹C ≠ 0› cong cf convergent_LIMSEQ_iff convergent_prod_iff_convergent convergent_prod_imp_convergent g)
next
assume cg: "convergent_prod g"
have "∃a. C * a ≠ 0 ∧ (λn. prod g {..n}) ⇢ a"
by (metis (no_types) ‹C ≠ 0› cg convergent_prod_iff_nz_lim divide_eq_0_iff g nonzero_mult_div_cancel_right)
then show "convergent_prod f"
using "*" tendsto_mult_left filterlim_cong
by (fastforce simp add: convergent_prod_iff_nz_lim f)
qed
qed
lemma has_prod_finite:
fixes f :: "nat ⇒ 'a::{semidom,t2_space}"
assumes [simp]: "finite N"
and f: "⋀n. n ∉ N ⟹ f n = 1"
shows "f has_prod (∏n∈N. f n)"
proof -
have eq: "prod f {..n + Suc (Max N)} = prod f N" for n
proof (rule prod.mono_neutral_right)
show "N ⊆ {..n + Suc (Max N)}"
by (auto simp: le_Suc_eq trans_le_add2)
show "∀i∈{..n + Suc (Max N)} - N. f i = 1"
using f by blast
qed auto
show ?thesis
proof (cases "∀n∈N. f n ≠ 0")
case True
then have "prod f N ≠ 0"
by simp
moreover have "(λn. prod f {..n}) ⇢ prod f N"
by (rule LIMSEQ_offset[of _ "Suc (Max N)"]) (simp add: eq atLeast0LessThan del: add_Suc_right)
ultimately show ?thesis
by (simp add: raw_has_prod_def has_prod_def)
next
case False
then obtain k where "k ∈ N" "f k = 0"
by auto
let ?Z = "{n ∈ N. f n = 0}"
have maxge: "Max ?Z ≥ n" if "f n = 0" for n
using Max_ge [of ?Z] ‹finite N› ‹f n = 0›
by (metis (mono_tags) Collect_mem_eq f finite_Collect_conjI mem_Collect_eq zero_neq_one)
let ?q = "prod f {Suc (Max ?Z)..Max N}"
have [simp]: "?q ≠ 0"
using maxge Suc_n_not_le_n le_trans by force
have eq: "(∏i≤n + Max N. f (Suc (i + Max ?Z))) = ?q" for n
proof -
have "(∏i≤n + Max N. f (Suc (i + Max ?Z))) = prod f {Suc (Max ?Z)..n + Max N + Suc (Max ?Z)}"
proof (rule prod.reindex_cong [where l = "λi. i + Suc (Max ?Z)", THEN sym])
show "{Suc (Max ?Z)..n + Max N + Suc (Max ?Z)} = (λi. i + Suc (Max ?Z)) ` {..n + Max N}"
using le_Suc_ex by fastforce
qed (auto simp: inj_on_def)
also have "… = ?q"
by (rule prod.mono_neutral_right)
(use Max.coboundedI [OF ‹finite N›] f in ‹force+›)
finally show ?thesis .
qed
have q: "raw_has_prod f (Suc (Max ?Z)) ?q"
proof (simp add: raw_has_prod_def)
show "(λn. ∏i≤n. f (Suc (i + Max ?Z))) ⇢ ?q"
by (rule LIMSEQ_offset[of _ "(Max N)"]) (simp add: eq)
qed
show ?thesis
unfolding has_prod_def
proof (intro disjI2 exI conjI)
show "prod f N = 0"
using ‹f k = 0› ‹k ∈ N› ‹finite N› prod_zero by blast
show "f (Max ?Z) = 0"
using Max_in [of ?Z] ‹finite N› ‹f k = 0› ‹k ∈ N› by auto
qed (use q in auto)
qed
qed
corollary has_prod_0:
fixes f :: "nat ⇒ 'a::{semidom,t2_space}"
assumes "⋀n. f n = 1"
shows "f has_prod 1"
by (simp add: assms has_prod_cong)
lemma prodinf_zero[simp]: "prodinf (λn. 1::'a::real_normed_field) = 1"
using has_prod_unique by force
lemma convergent_prod_finite:
fixes f :: "nat ⇒ 'a::{idom,t2_space}"
assumes "finite N" "⋀n. n ∉ N ⟹ f n = 1"
shows "convergent_prod f"
proof -
have "∃n p. raw_has_prod f n p"
using assms has_prod_def has_prod_finite by blast
then show ?thesis
by (simp add: convergent_prod_def)
qed
lemma has_prod_If_finite_set:
fixes f :: "nat ⇒ 'a::{idom,t2_space}"
shows "finite A ⟹ (λr. if r ∈ A then f r else 1) has_prod (∏r∈A. f r)"
using has_prod_finite[of A "(λr. if r ∈ A then f r else 1)"]
by simp
lemma has_prod_If_finite:
fixes f :: "nat ⇒ 'a::{idom,t2_space}"
shows "finite {r. P r} ⟹ (λr. if P r then f r else 1) has_prod (∏r | P r. f r)"
using has_prod_If_finite_set[of "{r. P r}"] by simp
lemma convergent_prod_If_finite_set[simp, intro]:
fixes f :: "nat ⇒ 'a::{idom,t2_space}"
shows "finite A ⟹ convergent_prod (λr. if r ∈ A then f r else 1)"
by (simp add: convergent_prod_finite)
lemma convergent_prod_If_finite[simp, intro]:
fixes f :: "nat ⇒ 'a::{idom,t2_space}"
shows "finite {r. P r} ⟹ convergent_prod (λr. if P r then f r else 1)"
using convergent_prod_def has_prod_If_finite has_prod_def by fastforce
lemma has_prod_single:
fixes f :: "nat ⇒ 'a::{idom,t2_space}"
shows "(λr. if r = i then f r else 1) has_prod f i"
using has_prod_If_finite[of "λr. r = i"] by simp
text ‹The ge1 assumption can probably be weakened, at the expense of extra work›
lemma uniform_limit_prodinf:
fixes f:: "nat ⇒ real ⇒ real"
assumes "uniformly_convergent_on X (λn x. ∏k<n. f k x)"
and ge1: "⋀x k . x ∈ X ⟹ f k x ≥ 1"
shows "uniform_limit X (λn x. ∏k<n. f k x) (λx. ∏k. f k x) sequentially"
proof -
have ul: "uniform_limit X (λn x. ∏k<n. f k x) (λx. lim (λn. ∏k<n. f k x)) sequentially"
using assms uniformly_convergent_uniform_limit_iff by blast
moreover have "(∏k. f k x) = lim (λn. ∏k<n. f k x)" if "x ∈ X" for x
proof (intro prodinf_eq_lim')
have tends: "(λn. ∏k<n. f k x) ⇢ lim (λn. ∏k<n. f k x)"
using tendsto_uniform_limitI [OF ul] that by metis
moreover have "(∏k<n. f k x) ≥ 1" for n
using ge1 by (simp add: prod_ge_1 that)
ultimately have "lim (λn. ∏k<n. f k x) ≥ 1"
by (meson LIMSEQ_le_const)
then have "raw_has_prod (λk. f k x) 0 (lim (λn. ∏k<n. f k x))"
using LIMSEQ_lessThan_iff_atMost tends by (auto simp: raw_has_prod_def)
then show "convergent_prod (λk. f k x)"
unfolding convergent_prod_def by blast
show "⋀k. f k x ≠ 0"
by (smt (verit) ge1 that)
qed
ultimately show ?thesis
by (metis (mono_tags, lifting) uniform_limit_cong')
qed
context
fixes f :: "nat ⇒ 'a :: real_normed_field"
begin
lemma convergent_prod_imp_has_prod:
assumes "convergent_prod f"
shows "∃p. f has_prod p"
proof -
obtain M p where p: "raw_has_prod f M p"
using assms convergent_prod_def by blast
then have "p ≠ 0"
using raw_has_prod_nonzero by blast
with p have fnz: "f i ≠ 0" if "i ≥ M" for i
using raw_has_prod_eq_0 that by blast
define C where "C = (∏n<M. f n)"
show ?thesis
proof (cases "∀n≤M. f n ≠ 0")
case True
then have "C ≠ 0"
by (simp add: C_def)
then show ?thesis
by (meson True assms convergent_prod_offset_0 fnz has_prod_def nat_le_linear)
next
case False
let ?N = "GREATEST n. f n = 0"
have 0: "f ?N = 0"
using fnz False
by (metis (mono_tags, lifting) GreatestI_ex_nat nat_le_linear)
have "f i ≠ 0" if "i > ?N" for i
by (metis (mono_tags, lifting) Greatest_le_nat fnz leD linear that)
then have "∃p. raw_has_prod f (Suc ?N) p"
using assms by (auto simp: intro!: convergent_prod_ignore_nonzero_segment)
then show ?thesis
unfolding has_prod_def using 0 by blast
qed
qed
lemma convergent_prod_has_prod [intro]:
shows "convergent_prod f ⟹ f has_prod (prodinf f)"
unfolding prodinf_def
by (metis convergent_prod_imp_has_prod has_prod_unique theI')
lemma convergent_prod_LIMSEQ:
shows "convergent_prod f ⟹ (λn. ∏i≤n. f i) ⇢ prodinf f"
by (metis convergent_LIMSEQ_iff convergent_prod_has_prod convergent_prod_imp_convergent
convergent_prod_to_zero_iff raw_has_prod_eq_0 has_prod_def prodinf_eq_lim zero_le)
theorem has_prod_iff: "f has_prod x ⟷ convergent_prod f ∧ prodinf f = x"
proof
assume "f has_prod x"
then show "convergent_prod f ∧ prodinf f = x"
apply safe
using convergent_prod_def has_prod_def apply blast
using has_prod_unique by blast
qed auto
lemma convergent_prod_has_prod_iff: "convergent_prod f ⟷ f has_prod prodinf f"
by (auto simp: has_prod_iff convergent_prod_has_prod)
lemma prodinf_finite:
assumes N: "finite N"
and f: "⋀n. n ∉ N ⟹ f n = 1"
shows "prodinf f = (∏n∈N. f n)"
using has_prod_finite[OF assms, THEN has_prod_unique] by simp
end
subsection ‹Infinite products on ordered topological monoids›
context
fixes f :: "nat ⇒ 'a::{linordered_semidom,linorder_topology}"
begin
lemma has_prod_nonzero:
assumes "f has_prod a" "a ≠ 0"
shows "f k ≠ 0"
using assms by (auto simp: has_prod_def raw_has_prod_def LIMSEQ_prod_0 LIMSEQ_unique)
lemma has_prod_le:
assumes f: "f has_prod a" and g: "g has_prod b" and le: "⋀n. 0 ≤ f n ∧ f n ≤ g n"
shows "a ≤ b"
proof (cases "a=0 ∨ b=0")
case True
then show ?thesis
proof
assume [simp]: "a=0"
have "b ≥ 0"
proof (rule LIMSEQ_prod_nonneg)
show "(λn. prod g {..n}) ⇢ b"
using g by (auto simp: has_prod_def raw_has_prod_def LIMSEQ_prod_0)
qed (use le order_trans in auto)
then show ?thesis
by auto
next
assume [simp]: "b=0"
then obtain i where "g i = 0"
using g by (auto simp: prod_defs)
then have "f i = 0"
using antisym le by force
then have "a=0"
using f by (auto simp: prod_defs LIMSEQ_prod_0 LIMSEQ_unique)
then show ?thesis
by auto
qed
next
case False
then show ?thesis
using assms
unfolding has_prod_def raw_has_prod_def
by (force simp: LIMSEQ_prod_0 intro!: LIMSEQ_le prod_mono)
qed
lemma prodinf_le:
assumes f: "f has_prod a" and g: "g has_prod b" and le: "⋀n. 0 ≤ f n ∧ f n ≤ g n"
shows "prodinf f ≤ prodinf g"
using has_prod_le [OF assms] has_prod_unique f g by blast
end
lemma prod_le_prodinf:
fixes f :: "nat ⇒ 'a::{linordered_idom,linorder_topology}"
assumes "f has_prod a" "⋀i. 0 ≤ f i" "⋀i. i≥n ⟹ 1 ≤ f i"
shows "prod f {..<n} ≤ prodinf f"
by(rule has_prod_le[OF has_prod_If_finite_set]) (use assms has_prod_unique in auto)
lemma prodinf_nonneg:
fixes f :: "nat ⇒ 'a::{linordered_idom,linorder_topology}"
assumes "f has_prod a" "⋀i. 1 ≤ f i"
shows "1 ≤ prodinf f"
using prod_le_prodinf[of f a 0] assms
by (metis order_trans prod_ge_1 zero_le_one)
lemma prodinf_le_const:
fixes f :: "nat ⇒ real"
assumes "convergent_prod f" "⋀n. n ≥ N ⟹ prod f {..<n} ≤ x"
shows "prodinf f ≤ x"
by (metis lessThan_Suc_atMost assms convergent_prod_LIMSEQ LIMSEQ_le_const2 atMost_iff lessThan_iff less_le)
lemma prodinf_eq_one_iff [simp]:
fixes f :: "nat ⇒ real"
assumes f: "convergent_prod f" and ge1: "⋀n. 1 ≤ f n"
shows "prodinf f = 1 ⟷ (∀n. f n = 1)"
proof
assume "prodinf f = 1"
then have "(λn. ∏i<n. f i) ⇢ 1"
using convergent_prod_LIMSEQ[of f] assms by (simp add: LIMSEQ_lessThan_iff_atMost)
then have "⋀i. (∏n∈{i}. f n) ≤ 1"
proof (rule LIMSEQ_le_const)
have "1 ≤ prod f n" for n
by (simp add: ge1 prod_ge_1)
have "prod f {..<n} = 1" for n
by (metis ‹⋀n. 1 ≤ prod f n› ‹prodinf f = 1› antisym f convergent_prod_has_prod ge1 order_trans prod_le_prodinf zero_le_one)
then have "(∏n∈{i}. f n) ≤ prod f {..<n}" if "n ≥ Suc i" for i n
by (metis mult.left_neutral order_refl prod.cong prod.neutral_const prod.lessThan_Suc)
then show "∃N. ∀n≥N. (∏n∈{i}. f n) ≤ prod f {..<n}" for i
by blast
qed
with ge1 show "∀n. f n = 1"
by (auto intro!: antisym)
qed (metis prodinf_zero fun_eq_iff)
lemma prodinf_pos_iff:
fixes f :: "nat ⇒ real"
assumes "convergent_prod f" "⋀n. 1 ≤ f n"
shows "1 < prodinf f ⟷ (∃i. 1 < f i)"
using prod_le_prodinf[of f 1] prodinf_eq_one_iff
by (metis convergent_prod_has_prod assms less_le prodinf_nonneg)
lemma less_1_prodinf2:
fixes f :: "nat ⇒ real"
assumes "convergent_prod f" "⋀n. 1 ≤ f n" "1 < f i"
shows "1 < prodinf f"
proof -
have "1 < (∏n<Suc i. f n)"
using assms by (intro less_1_prod2[where i=i]) auto
also have "… ≤ prodinf f"
by (intro prod_le_prodinf) (use assms order_trans zero_le_one in ‹blast+›)
finally show ?thesis .
qed
lemma less_1_prodinf:
fixes f :: "nat ⇒ real"
shows "⟦convergent_prod f; ⋀n. 1 < f n⟧ ⟹ 1 < prodinf f"
by (intro less_1_prodinf2[where i=1]) (auto intro: less_imp_le)
lemma prodinf_nonzero:
fixes f :: "nat ⇒ 'a :: {idom,topological_semigroup_mult,t2_space}"
assumes "convergent_prod f" "⋀i. f i ≠ 0"
shows "prodinf f ≠ 0"
by (metis assms convergent_prod_offset_0 has_prod_unique raw_has_prod_def has_prod_def)
lemma less_0_prodinf:
fixes f :: "nat ⇒ real"
assumes f: "convergent_prod f" and 0: "⋀i. f i > 0"
shows "0 < prodinf f"
proof -
have "prodinf f ≠ 0"
by (metis assms less_irrefl prodinf_nonzero)
moreover have "0 < (∏n<i. f n)" for i
by (simp add: 0 prod_pos)
then have "prodinf f ≥ 0"
using convergent_prod_LIMSEQ [OF f] LIMSEQ_prod_nonneg 0 less_le by blast
ultimately show ?thesis
by auto
qed
lemma prod_less_prodinf2:
fixes f :: "nat ⇒ real"
assumes f: "convergent_prod f" and 1: "⋀m. m≥n ⟹ 1 ≤ f m" and 0: "⋀m. 0 < f m" and i: "n ≤ i" "1 < f i"
shows "prod f {..<n} < prodinf f"
proof -
have "prod f {..<n} ≤ prod f {..<i}"
by (rule prod_mono2) (use assms less_le in auto)
then have "prod f {..<n} < f i * prod f {..<i}"
using mult_less_le_imp_less[of 1 "f i" "prod f {..<n}" "prod f {..<i}"] assms
by (simp add: prod_pos)
moreover have "prod f {..<Suc i} ≤ prodinf f"
using prod_le_prodinf[of f _ "Suc i"]
by (meson "0" "1" Suc_leD convergent_prod_has_prod f ‹n ≤ i› le_trans less_eq_real_def)
ultimately show ?thesis
by (metis le_less_trans mult.commute not_le prod.lessThan_Suc)
qed
lemma prod_less_prodinf:
fixes f :: "nat ⇒ real"
assumes f: "convergent_prod f" and 1: "⋀m. m≥n ⟹ 1 < f m" and 0: "⋀m. 0 < f m"
shows "prod f {..<n} < prodinf f"
by (meson "0" "1" f le_less prod_less_prodinf2)
lemma raw_has_prodI_bounded:
fixes f :: "nat ⇒ real"
assumes pos: "⋀n. 1 ≤ f n"
and le: "⋀n. (∏i<n. f i) ≤ x"
shows "∃p. raw_has_prod f 0 p"
unfolding raw_has_prod_def add_0_right
proof (rule exI LIMSEQ_incseq_SUP conjI)+
show "bdd_above (range (λn. prod f {..n}))"
by (metis bdd_aboveI2 le lessThan_Suc_atMost)
then have "(SUP i. prod f {..i}) > 0"
by (metis UNIV_I cSUP_upper less_le_trans pos prod_pos zero_less_one)
then show "(SUP i. prod f {..i}) ≠ 0"
by auto
show "incseq (λn. prod f {..n})"
using pos order_trans [OF zero_le_one] by (auto simp: mono_def intro!: prod_mono2)
qed
lemma convergent_prodI_nonneg_bounded:
fixes f :: "nat ⇒ real"
assumes "⋀n. 1 ≤ f n" "⋀n. (∏i<n. f i) ≤ x"
shows "convergent_prod f"
using convergent_prod_def raw_has_prodI_bounded [OF assms] by blast
subsection ‹Infinite products on topological spaces›
context
fixes f g :: "nat ⇒ 'a::{t2_space,topological_semigroup_mult,idom}"
begin
lemma raw_has_prod_mult: "⟦raw_has_prod f M a; raw_has_prod g M b⟧ ⟹ raw_has_prod (λn. f n * g n) M (a * b)"
by (force simp add: prod.distrib tendsto_mult raw_has_prod_def)
lemma has_prod_mult_nz: "⟦f has_prod a; g has_prod b; a ≠ 0; b ≠ 0⟧ ⟹ (λn. f n * g n) has_prod (a * b)"
by (simp add: raw_has_prod_mult has_prod_def)
end
context
fixes f g :: "nat ⇒ 'a::real_normed_field"
begin
lemma has_prod_mult:
assumes f: "f has_prod a" and g: "g has_prod b"
shows "(λn. f n * g n) has_prod (a * b)"
using f [unfolded has_prod_def]
proof (elim disjE exE conjE)
assume f0: "raw_has_prod f 0 a"
show ?thesis
using g [unfolded has_prod_def]
proof (elim disjE exE conjE)
assume g0: "raw_has_prod g 0 b"
with f0 show ?thesis
by (force simp add: has_prod_def prod.distrib tendsto_mult raw_has_prod_def)
next
fix j q
assume "b = 0" and "g j = 0" and q: "raw_has_prod g (Suc j) q"
obtain p where p: "raw_has_prod f (Suc j) p"
using f0 raw_has_prod_ignore_initial_segment by blast
then have "Ex (raw_has_prod (λn. f n * g n) (Suc j))"
using q raw_has_prod_mult by blast
then show ?thesis
using ‹b = 0› ‹g j = 0› has_prod_0_iff by fastforce
qed
next
fix i p
assume "a = 0" and "f i = 0" and p: "raw_has_prod f (Suc i) p"
show ?thesis
using g [unfolded has_prod_def]
proof (elim disjE exE conjE)
assume g0: "raw_has_prod g 0 b"
obtain q where q: "raw_has_prod g (Suc i) q"
using g0 raw_has_prod_ignore_initial_segment by blast
then have "Ex (raw_has_prod (λn. f n * g n) (Suc i))"
using raw_has_prod_mult p by blast
then show ?thesis
using ‹a = 0› ‹f i = 0› has_prod_0_iff by fastforce
next
fix j q
assume "b = 0" and "g j = 0" and q: "raw_has_prod g (Suc j) q"
obtain p' where p': "raw_has_prod f (Suc (max i j)) p'"
by (metis raw_has_prod_ignore_initial_segment max_Suc_Suc max_def p)
moreover
obtain q' where q': "raw_has_prod g (Suc (max i j)) q'"
by (metis raw_has_prod_ignore_initial_segment max.cobounded2 max_Suc_Suc q)
ultimately show ?thesis
using ‹b = 0› by (simp add: has_prod_def) (metis ‹f i = 0› ‹g j = 0› raw_has_prod_mult max_def)
qed
qed
lemma convergent_prod_mult:
assumes f: "convergent_prod f" and g: "convergent_prod g"
shows "convergent_prod (λn. f n * g n)"
unfolding convergent_prod_def
proof -
obtain M p N q where p: "raw_has_prod f M p" and q: "raw_has_prod g N q"
using convergent_prod_def f g by blast+
then obtain p' q' where p': "raw_has_prod f (max M N) p'" and q': "raw_has_prod g (max M N) q'"
by (meson raw_has_prod_ignore_initial_segment max.cobounded1 max.cobounded2)
then show "∃M p. raw_has_prod (λn. f n * g n) M p"
using raw_has_prod_mult by blast
qed
lemma prodinf_mult: "convergent_prod f ⟹ convergent_prod g ⟹ prodinf f * prodinf g = (∏n. f n * g n)"
by (intro has_prod_unique has_prod_mult convergent_prod_has_prod)
end
context
fixes f :: "'i ⇒ nat ⇒ 'a::real_normed_field"
and I :: "'i set"
begin
lemma has_prod_prod: "(⋀i. i ∈ I ⟹ (f i) has_prod (x i)) ⟹ (λn. ∏i∈I. f i n) has_prod (∏i∈I. x i)"
by (induct I rule: infinite_finite_induct) (auto intro!: has_prod_mult)
lemma prodinf_prod: "(⋀i. i ∈ I ⟹ convergent_prod (f i)) ⟹ (∏n. ∏i∈I. f i n) = (∏i∈I. ∏n. f i n)"
using has_prod_unique[OF has_prod_prod, OF convergent_prod_has_prod] by simp
lemma convergent_prod_prod: "(⋀i. i ∈ I ⟹ convergent_prod (f i)) ⟹ convergent_prod (λn. ∏i∈I. f i n)"
using convergent_prod_has_prod_iff has_prod_prod prodinf_prod by force
end
subsection ‹Infinite summability on real normed fields›
context
fixes f :: "nat ⇒ 'a::real_normed_field"
begin
lemma raw_has_prod_Suc_iff: "raw_has_prod f M (a * f M) ⟷ raw_has_prod (λn. f (Suc n)) M a ∧ f M ≠ 0"
proof -
have "raw_has_prod f M (a * f M) ⟷ (λi. ∏j≤Suc i. f (j+M)) ⇢ a * f M ∧ a * f M ≠ 0"
by (subst filterlim_sequentially_Suc) (simp add: raw_has_prod_def)
also have "… ⟷ (λi. (∏j≤i. f (Suc j + M)) * f M) ⇢ a * f M ∧ a * f M ≠ 0"
by (simp add: ac_simps atMost_Suc_eq_insert_0 image_Suc_atMost prod.atLeast1_atMost_eq lessThan_Suc_atMost
del: prod.cl_ivl_Suc)
also have "… ⟷ raw_has_prod (λn. f (Suc n)) M a ∧ f M ≠ 0"
proof safe
assume tends: "(λi. (∏j≤i. f (Suc j + M)) * f M) ⇢ a * f M" and 0: "a * f M ≠ 0"
with tendsto_divide[OF tends tendsto_const, of "f M"]
show "raw_has_prod (λn. f (Suc n)) M a"
by (simp add: raw_has_prod_def)
qed (auto intro: tendsto_mult_right simp: raw_has_prod_def)
finally show ?thesis .
qed
lemma has_prod_Suc_iff:
assumes "f 0 ≠ 0" shows "(λn. f (Suc n)) has_prod a ⟷ f has_prod (a * f 0)"
proof (cases "a = 0")
case True
then show ?thesis
proof (simp add: has_prod_def, safe)
fix i x
assume "f (Suc i) = 0" and "raw_has_prod (λn. f (Suc n)) (Suc i) x"
then obtain y where "raw_has_prod f (Suc (Suc i)) y"
by (metis (no_types) raw_has_prod_eq_0 Suc_n_not_le_n raw_has_prod_Suc_iff raw_has_prod_ignore_initial_segment raw_has_prod_nonzero linear)
then show "∃i. f i = 0 ∧ Ex (raw_has_prod f (Suc i))"
using ‹f (Suc i) = 0› by blast
next
fix i x
assume "f i = 0" and x: "raw_has_prod f (Suc i) x"
then obtain j where j: "i = Suc j"
by (metis assms not0_implies_Suc)
moreover have "∃ y. raw_has_prod (λn. f (Suc n)) i y"
using x by (auto simp: raw_has_prod_def)
then show "∃i. f (Suc i) = 0 ∧ Ex (raw_has_prod (λn. f (Suc n)) (Suc i))"
using ‹f i = 0› j by blast
qed
next
case False
then show ?thesis
by (auto simp: has_prod_def raw_has_prod_Suc_iff assms)
qed
lemma convergent_prod_Suc_iff [simp]:
shows "convergent_prod (λn. f (Suc n)) = convergent_prod f"
proof
assume "convergent_prod f"
then obtain M L where M_nz:"∀n≥M. f n ≠ 0" and
M_L:"(λn. ∏i≤n. f (i + M)) ⇢ L" and "L ≠ 0"
unfolding convergent_prod_altdef by auto
have "(λn. ∏i≤n. f (Suc (i + M))) ⇢ L / f M"
proof -
have "(λn. ∏i∈{0..Suc n}. f (i + M)) ⇢ L"
using M_L
apply (subst (asm) filterlim_sequentially_Suc[symmetric])
using atLeast0AtMost by auto
then have "(λn. f M * (∏i∈{0..n}. f (Suc (i + M)))) ⇢ L"
apply (subst (asm) prod.atLeast0_atMost_Suc_shift)
by simp
then have "(λn. (∏i∈{0..n}. f (Suc (i + M)))) ⇢ L/f M"
apply (drule_tac tendsto_divide)
using M_nz[rule_format,of M,simplified] by auto
then show ?thesis unfolding atLeast0AtMost .
qed
then show "convergent_prod (λn. f (Suc n))" unfolding convergent_prod_altdef
apply (rule_tac exI[where x=M])
apply (rule_tac exI[where x="L/f M"])
using M_nz ‹L≠0› by auto
next
assume "convergent_prod (λn. f (Suc n))"
then obtain M where "∃L. (∀n≥M. f (Suc n) ≠ 0) ∧ (λn. ∏i≤n. f (Suc (i + M))) ⇢ L ∧ L ≠ 0"
unfolding convergent_prod_altdef by auto
then show "convergent_prod f" unfolding convergent_prod_altdef
apply (rule_tac exI[where x="Suc M"])
using Suc_le_D by auto
qed
lemma raw_has_prod_inverse:
assumes "raw_has_prod f M a" shows "raw_has_prod (λn. inverse (f n)) M (inverse a)"
using assms unfolding raw_has_prod_def by (auto dest: tendsto_inverse simp: prod_inversef [symmetric])
lemma has_prod_inverse:
assumes "f has_prod a" shows "(λn. inverse (f n)) has_prod (inverse a)"
using assms raw_has_prod_inverse unfolding has_prod_def by auto
lemma convergent_prod_inverse:
assumes "convergent_prod f"
shows "convergent_prod (λn. inverse (f n))"
using assms unfolding convergent_prod_def by (blast intro: raw_has_prod_inverse elim: )
end
context
fixes f :: "nat ⇒ 'a::real_normed_field"
begin
lemma raw_has_prod_Suc_iff': "raw_has_prod f M a ⟷ raw_has_prod (λn. f (Suc n)) M (a / f M) ∧ f M ≠ 0"
by (metis raw_has_prod_eq_0 add.commute add.left_neutral raw_has_prod_Suc_iff raw_has_prod_nonzero le_add1 nonzero_mult_div_cancel_right times_divide_eq_left)
lemma has_prod_divide: "f has_prod a ⟹ g has_prod b ⟹ (λn. f n / g n) has_prod (a / b)"
unfolding divide_inverse by (intro has_prod_inverse has_prod_mult)
lemma convergent_prod_divide:
assumes f: "convergent_prod f" and g: "convergent_prod g"
shows "convergent_prod (λn. f n / g n)"
using f g has_prod_divide has_prod_iff by blast
lemma prodinf_divide: "convergent_prod f ⟹ convergent_prod g ⟹ prodinf f / prodinf g = (∏n. f n / g n)"
by (intro has_prod_unique has_prod_divide convergent_prod_has_prod)
lemma prodinf_inverse: "convergent_prod f ⟹ (∏n. inverse (f n)) = inverse (∏n. f n)"
by (intro has_prod_unique [symmetric] has_prod_inverse convergent_prod_has_prod)
lemma has_prod_Suc_imp:
assumes "(λn. f (Suc n)) has_prod a"
shows "f has_prod (a * f 0)"
proof -
have "f has_prod (a * f 0)" when "raw_has_prod (λn. f (Suc n)) 0 a"
apply (cases "f 0=0")
using that unfolding has_prod_def raw_has_prod_Suc
by (auto simp add: raw_has_prod_Suc_iff)
moreover have "f has_prod (a * f 0)" when
"(∃i q. a = 0 ∧ f (Suc i) = 0 ∧ raw_has_prod (λn. f (Suc n)) (Suc i) q)"
proof -
from that
obtain i q where "a = 0" "f (Suc i) = 0" "raw_has_prod (λn. f (Suc n)) (Suc i) q"
by auto
then show ?thesis unfolding has_prod_def
by (auto intro!:exI[where x="Suc i"] simp:raw_has_prod_Suc)
qed
ultimately show "f has_prod (a * f 0)" using assms unfolding has_prod_def by auto
qed
lemma has_prod_iff_shift:
assumes "⋀i. i < n ⟹ f i ≠ 0"
shows "(λi. f (i + n)) has_prod a ⟷ f has_prod (a * (∏i<n. f i))"
using assms
proof (induct n arbitrary: a)
case 0
then show ?case by simp
next
case (Suc n)
then have "(λi. f (Suc i + n)) has_prod a ⟷ (λi. f (i + n)) has_prod (a * f n)"
by (subst has_prod_Suc_iff) auto
with Suc show ?case
by (simp add: ac_simps)
qed
corollary has_prod_iff_shift':
assumes "⋀i. i < n ⟹ f i ≠ 0"
shows "(λi. f (i + n)) has_prod (a / (∏i<n. f i)) ⟷ f has_prod a"
by (simp add: assms has_prod_iff_shift)
lemma has_prod_one_iff_shift:
assumes "⋀i. i < n ⟹ f i = 1"
shows "(λi. f (i+n)) has_prod a ⟷ (λi. f i) has_prod a"
by (simp add: assms has_prod_iff_shift)
lemma convergent_prod_iff_shift [simp]:
shows "convergent_prod (λi. f (i + n)) ⟷ convergent_prod f"
apply safe
using convergent_prod_offset apply blast
using convergent_prod_ignore_initial_segment convergent_prod_def by blast
lemma has_prod_split_initial_segment:
assumes "f has_prod a" "⋀i. i < n ⟹ f i ≠ 0"
shows "(λi. f (i + n)) has_prod (a / (∏i<n. f i))"
using assms has_prod_iff_shift' by blast
lemma prodinf_divide_initial_segment:
assumes "convergent_prod f" "⋀i. i < n ⟹ f i ≠ 0"
shows "(∏i. f (i + n)) = (∏i. f i) / (∏i<n. f i)"
by (rule has_prod_unique[symmetric]) (auto simp: assms has_prod_iff_shift)
lemma prodinf_split_initial_segment:
assumes "convergent_prod f" "⋀i. i < n ⟹ f i ≠ 0"
shows "prodinf f = (∏i. f (i + n)) * (∏i<n. f i)"
by (auto simp add: assms prodinf_divide_initial_segment)
lemma prodinf_split_head:
assumes "convergent_prod f" "f 0 ≠ 0"
shows "(∏n. f (Suc n)) = prodinf f / f 0"
using prodinf_split_initial_segment[of 1] assms by simp
lemma has_prod_ignore_initial_segment':
assumes "convergent_prod f"
shows "f has_prod ((∏k<n. f k) * (∏k. f (k + n)))"
proof (cases "∃k<n. f k = 0")
case True
hence [simp]: "(∏k<n. f k) = 0"
by (meson finite_lessThan lessThan_iff prod_zero)
thus ?thesis using True assms
by (metis convergent_prod_has_prod_iff has_prod_zeroI mult_not_zero)
next
case False
hence "(λi. f (i + n)) has_prod (prodinf f / prod f {..<n})"
using assms by (intro has_prod_split_initial_segment) (auto simp: convergent_prod_has_prod_iff)
hence "prodinf f = prod f {..<n} * (∏k. f (k + n))"
using False by (simp add: has_prod_iff divide_simps mult_ac)
thus ?thesis
using assms by (simp add: convergent_prod_has_prod_iff)
qed
end
context
fixes f :: "nat ⇒ 'a::real_normed_field"
begin
lemma convergent_prod_inverse_iff [simp]: "convergent_prod (λn. inverse (f n)) ⟷ convergent_prod f"
by (auto dest: convergent_prod_inverse)
lemma convergent_prod_const_iff [simp]:
fixes c :: "'a :: {real_normed_field}"
shows "convergent_prod (λ_. c) ⟷ c = 1"
proof
assume "convergent_prod (λ_. c)"
then show "c = 1"
using convergent_prod_imp_LIMSEQ LIMSEQ_unique by blast
next
assume "c = 1"
then show "convergent_prod (λ_. c)"
by auto
qed
lemma has_prod_power: "f has_prod a ⟹ (λi. f i ^ n) has_prod (a ^ n)"
by (induction n) (auto simp: has_prod_mult)
lemma convergent_prod_power: "convergent_prod f ⟹ convergent_prod (λi. f i ^ n)"
by (induction n) (auto simp: convergent_prod_mult)
lemma prodinf_power: "convergent_prod f ⟹ prodinf (λi. f i ^ n) = prodinf f ^ n"
by (metis has_prod_unique convergent_prod_imp_has_prod has_prod_power)
end
subsection‹Exponentials and logarithms›
context
fixes f :: "nat ⇒ 'a::{real_normed_field,banach}"
begin
lemma sums_imp_has_prod_exp:
assumes "f sums s"
shows "raw_has_prod (λi. exp (f i)) 0 (exp s)"
using assms continuous_on_exp [of UNIV "λx::'a. x"]
using continuous_on_tendsto_compose [of UNIV exp "(λn. sum f {..n})" s]
by (simp add: prod_defs sums_def_le exp_sum)
lemma convergent_prod_exp:
assumes "summable f"
shows "convergent_prod (λi. exp (f i))"
using sums_imp_has_prod_exp assms unfolding summable_def convergent_prod_def by blast
lemma prodinf_exp:
assumes "summable f"
shows "prodinf (λi. exp (f i)) = exp (suminf f)"
proof -
have "f sums suminf f"
using assms by blast
then have "(λi. exp (f i)) has_prod exp (suminf f)"
by (simp add: has_prod_def sums_imp_has_prod_exp)
then show ?thesis
by (rule has_prod_unique [symmetric])
qed
end
theorem convergent_prod_iff_summable_real:
fixes a :: "nat ⇒ real"
assumes "⋀n. a n > 0"
shows "convergent_prod (λk. 1 + a k) ⟷ summable a" (is "?lhs = ?rhs")
proof
assume ?lhs
then obtain p where "raw_has_prod (λk. 1 + a k) 0 p"
by (metis assms add_less_same_cancel2 convergent_prod_offset_0 not_one_less_zero)
then have to_p: "(λn. ∏k≤n. 1 + a k) ⇢ p"
by (auto simp: raw_has_prod_def)
moreover have le: "(∑k≤n. a k) ≤ (∏k≤n. 1 + a k)" for n
by (rule sum_le_prod) (use assms less_le in force)
have "(∏k≤n. 1 + a k) ≤ p" for n
proof (rule incseq_le [OF _ to_p])
show "incseq (λn. ∏k≤n. 1 + a k)"
using assms by (auto simp: mono_def order.strict_implies_order intro!: prod_mono2)
qed
with le have "(∑k≤n. a k) ≤ p" for n
by (metis order_trans)
with assms bounded_imp_summable show ?rhs
by (metis not_less order.asym)
next
assume R: ?rhs
have "(∏k≤n. 1 + a k) ≤ exp (suminf a)" for n
proof -
have "(∏k≤n. 1 + a k) ≤ exp (∑k≤n. a k)" for n
by (rule prod_le_exp_sum) (use assms less_le in force)
moreover have "exp (∑k≤n. a k) ≤ exp (suminf a)" for n
unfolding exp_le_cancel_iff
by (meson sum_le_suminf R assms finite_atMost less_eq_real_def)
ultimately show ?thesis
by (meson order_trans)
qed
then obtain L where L: "(λn. ∏k≤n. 1 + a k) ⇢ L"
by (metis assms bounded_imp_convergent_prod convergent_prod_iff_nz_lim le_add_same_cancel1 le_add_same_cancel2 less_le not_le zero_le_one)
moreover have "L ≠ 0"
proof
assume "L = 0"
with L have "(λn. ∏k≤n. 1 + a k) ⇢ 0"
by simp
moreover have "(∏k≤n. 1 + a k) > 1" for n
by (simp add: assms less_1_prod)
ultimately show False
by (meson Lim_bounded2 not_one_le_zero less_imp_le)
qed
ultimately show ?lhs
using assms convergent_prod_iff_nz_lim
by (metis add_less_same_cancel1 less_le not_le zero_less_one)
qed
lemma exp_suminf_prodinf_real:
fixes f :: "nat ⇒ real"
assumes ge0:"⋀n. f n ≥ 0" and ac: "abs_convergent_prod (λn. exp (f n))"
shows "prodinf (λi. exp (f i)) = exp (suminf f)"
proof -
have "summable f"
using ac unfolding abs_convergent_prod_conv_summable
proof (elim summable_comparison_test')
fix n
have "¦f n¦ = f n"
by (simp add: ge0)
also have "… ≤ exp (f n) - 1"
by (metis diff_diff_add exp_ge_add_one_self ge_iff_diff_ge_0)
finally show "norm (f n) ≤ norm (exp (f n) - 1)"
by simp
qed
then show ?thesis
by (simp add: prodinf_exp)
qed
lemma has_prod_imp_sums_ln_real:
fixes f :: "nat ⇒ real"
assumes "raw_has_prod f 0 p" and 0: "⋀x. f x > 0"
shows "(λi. ln (f i)) sums (ln p)"
proof -
have "p > 0"
using assms unfolding prod_defs by (metis LIMSEQ_prod_nonneg less_eq_real_def)
then show ?thesis
using assms continuous_on_ln [of "{0<..}" "λx. x"]
using continuous_on_tendsto_compose [of "{0<..}" ln "(λn. prod f {..n})" p]
by (auto simp: prod_defs sums_def_le ln_prod order_tendstoD)
qed
lemma summable_ln_real:
fixes f :: "nat ⇒ real"
assumes f: "convergent_prod f" and 0: "⋀x. f x > 0"
shows "summable (λi. ln (f i))"
proof -
obtain M p where "raw_has_prod f M p"
using f convergent_prod_def by blast
then consider i where "i<M" "f i = 0" | p where "raw_has_prod f 0 p"
using raw_has_prod_cases by blast
then show ?thesis
proof cases
case 1
with 0 show ?thesis
by (metis less_irrefl)
next
case 2
then show ?thesis
using "0" has_prod_imp_sums_ln_real summable_def by blast
qed
qed
lemma suminf_ln_real:
fixes f :: "nat ⇒ real"
assumes f: "convergent_prod f" and 0: "⋀x. f x > 0"
shows "suminf (λi. ln (f i)) = ln (prodinf f)"
proof -
have "f has_prod prodinf f"
by (simp add: f has_prod_iff)
then have "raw_has_prod f 0 (prodinf f)"
by (metis "0" has_prod_def less_irrefl)
then have "(λi. ln (f i)) sums ln (prodinf f)"
using "0" has_prod_imp_sums_ln_real by blast
then show ?thesis
by (rule sums_unique [symmetric])
qed
lemma prodinf_exp_real:
fixes f :: "nat ⇒ real"
assumes f: "convergent_prod f" and 0: "⋀x. f x > 0"
shows "prodinf f = exp (suminf (λi. ln (f i)))"
by (simp add: "0" f less_0_prodinf suminf_ln_real)
theorem Ln_prodinf_complex:
fixes z :: "nat ⇒ complex"
assumes z: "⋀j. z j ≠ 0" and ξ: "ξ ≠ 0"
shows "((λn. ∏j≤n. z j) ⇢ ξ) ⟷ (∃k. (λn. (∑j≤n. Ln (z j))) ⇢ Ln ξ + of_int k * (of_real(2*pi) * 𝗂))" (is "?lhs = ?rhs")
proof
assume L: ?lhs
have pnz: "(∏j≤n. z j) ≠ 0" for n
using z by auto
define Θ where "Θ ≡ Arg ξ + 2*pi"
then have "Θ > pi"
using Arg_def mpi_less_Im_Ln by fastforce
have ξ_eq: "ξ = cmod ξ * exp (𝗂 * Θ)"
using Arg_def Arg_eq ξ unfolding Θ_def by (simp add: algebra_simps exp_add)
define θ where "θ ≡ λn. THE t. is_Arg (∏j≤n. z j) t ∧ t ∈ {Θ-pi<..Θ+pi}"
have uniq: "∃!s. is_Arg (∏j≤n. z j) s ∧ s ∈ {Θ-pi<..Θ+pi}" for n
using Argument_exists_unique [OF pnz] by metis
have θ: "is_Arg (∏j≤n. z j) (θ n)" and θ_interval: "θ n ∈ {Θ-pi<..Θ+pi}" for n
unfolding θ_def
using theI' [OF uniq] by metis+
have θ_pos: "⋀j. θ j > 0"
using θ_interval ‹Θ > pi› by simp (meson diff_gt_0_iff_gt less_trans)
have "(∏j≤n. z j) = cmod (∏j≤n. z j) * exp (𝗂 * θ n)" for n
using θ by (auto simp: is_Arg_def)
then have eq: "(λn. ∏j≤n. z j) = (λn. cmod (∏j≤n. z j) * exp (𝗂 * θ n))"
by simp
then have "(λn. (cmod (∏j≤n. z j)) * exp (𝗂 * (θ n))) ⇢ ξ"
using L by force
then obtain k where k: "(λj. θ j - of_int (k j) * (2 * pi)) ⇢ Θ"
using L by (subst (asm) ξ_eq) (auto simp add: eq z ξ polar_convergence)
moreover have "∀⇩F n in sequentially. k n = 0"
proof -
have *: "kj = 0" if "dist (vj - real_of_int kj * 2) V < 1" "vj ∈ {V - 1<..V + 1}" for kj vj V
using that by (auto simp: dist_norm)
have "∀⇩F j in sequentially. dist (θ j - of_int (k j) * (2 * pi)) Θ < pi"
using tendstoD [OF k] pi_gt_zero by blast
then show ?thesis
proof (rule eventually_mono)
fix j
assume d: "dist (θ j - real_of_int (k j) * (2 * pi)) Θ < pi"
show "k j = 0"
by (rule * [of "θ j/pi" _ "Θ/pi"])
(use θ_interval [of j] d in ‹simp_all add: divide_simps dist_norm›)
qed
qed
ultimately have θtoΘ: "θ ⇢ Θ"
apply (simp only: tendsto_def)
apply (erule all_forward imp_forward asm_rl)+
apply (drule (1) eventually_conj)
apply (auto elim: eventually_mono)
done
then have to0: "(λn. ¦θ (Suc n) - θ n¦) ⇢ 0"
by (metis (full_types) diff_self filterlim_sequentially_Suc tendsto_diff tendsto_rabs_zero)
have "∃k. Im (∑j≤n. Ln (z j)) - of_int k * (2*pi) = θ n" for n
proof (rule is_Arg_exp_diff_2pi)
show "is_Arg (exp (∑j≤n. Ln (z j))) (θ n)"
using pnz θ by (simp add: is_Arg_def exp_sum prod_norm)
qed
then have "∃k. (∑j≤n. Im (Ln (z j))) = θ n + of_int k * (2*pi)" for n
by (simp add: algebra_simps)
then obtain k where k: "⋀n. (∑j≤n. Im (Ln (z j))) = θ n + of_int (k n) * (2*pi)"
by metis
obtain K where "∀⇩F n in sequentially. k n = K"
proof -
have k_le: "(2*pi) * ¦k (Suc n) - k n¦ ≤ ¦θ (Suc n) - θ n¦ + ¦Im (Ln (z (Suc n)))¦" for n
proof -
have "(∑j≤Suc n. Im (Ln (z j))) - (∑j≤n. Im (Ln (z j))) = Im (Ln (z (Suc n)))"
by simp
then show ?thesis
using k [of "Suc n"] k [of n] by (auto simp: abs_if algebra_simps)
qed
have "z ⇢ 1"
using L ξ convergent_prod_iff_nz_lim z by (blast intro: convergent_prod_imp_LIMSEQ)
with z have "(λn. Ln (z n)) ⇢ Ln 1"
using isCont_tendsto_compose [OF continuous_at_Ln] nonpos_Reals_one_I by blast
then have "(λn. Ln (z n)) ⇢ 0"
by simp
then have "(λn. ¦Im (Ln (z (Suc n)))¦) ⇢ 0"
by (metis LIMSEQ_unique ‹z ⇢ 1› continuous_at_Ln filterlim_sequentially_Suc isCont_tendsto_compose nonpos_Reals_one_I tendsto_Im tendsto_rabs_zero_iff zero_complex.simps(2))
then have "∀⇩F n in sequentially. ¦Im (Ln (z (Suc n)))¦ < 1"
by (simp add: order_tendsto_iff)
moreover have "∀⇩F n in sequentially. ¦θ (Suc n) - θ n¦ < 1"
using to0 by (simp add: order_tendsto_iff)
ultimately have "∀⇩F n in sequentially. (2*pi) * ¦k (Suc n) - k n¦ < 1 + 1"
proof (rule eventually_elim2)
fix n
assume "¦Im (Ln (z (Suc n)))¦ < 1" and "¦θ (Suc n) - θ n¦ < 1"
with k_le [of n] show "2 * pi * real_of_int ¦k (Suc n) - k n¦ < 1 + 1"
by linarith
qed
then have "∀⇩F n in sequentially. real_of_int¦k (Suc n) - k n¦ < 1"
proof (rule eventually_mono)
fix n :: "nat"
assume "2 * pi * ¦k (Suc n) - k n¦ < 1 + 1"
then have "¦k (Suc n) - k n¦ < 2 / (2*pi)"
by (simp add: field_simps)
also have "... < 1"
using pi_ge_two by auto
finally show "real_of_int ¦k (Suc n) - k n¦ < 1" .
qed
then obtain N where N: "⋀n. n≥N ⟹ ¦k (Suc n) - k n¦ = 0"
using eventually_sequentially less_irrefl of_int_abs by fastforce
have "k (N+i) = k N" for i
proof (induction i)
case (Suc i)
with N [of "N+i"] show ?case
by auto
qed simp
then have "⋀n. n≥N ⟹ k n = k N"
using le_Suc_ex by auto
then show ?thesis
by (force simp add: eventually_sequentially intro: that)
qed
with θtoΘ have "(λn. (∑j≤n. Im (Ln (z j)))) ⇢ Θ + of_int K * (2*pi)"
by (simp add: k tendsto_add tendsto_mult tendsto_eventually)
moreover have "(λn. (∑k≤n. Re (Ln (z k)))) ⇢ Re (Ln ξ)"
using assms continuous_imp_tendsto [OF isCont_ln tendsto_norm [OF L]]
by (simp add: o_def flip: prod_norm ln_prod)
ultimately show ?rhs
by (rule_tac x="K+1" in exI) (auto simp: tendsto_complex_iff Θ_def Arg_def assms algebra_simps)
next
assume ?rhs
then obtain r where r: "(λn. (∑k≤n. Ln (z k))) ⇢ Ln ξ + of_int r * (of_real(2*pi) * 𝗂)" ..
have "(λn. exp (∑k≤n. Ln (z k))) ⇢ ξ"
using assms continuous_imp_tendsto [OF isCont_exp r] exp_integer_2pi [of r]
by (simp add: o_def exp_add algebra_simps)
moreover have "exp (∑k≤n. Ln (z k)) = (∏k≤n. z k)" for n
by (simp add: exp_sum add_eq_0_iff assms)
ultimately show ?lhs
by auto
qed
text‹Prop 17.2 of Bak and Newman, Complex Analysis, p.242›
proposition convergent_prod_iff_summable_complex:
fixes z :: "nat ⇒ complex"
assumes "⋀k. z k ≠ 0"
shows "convergent_prod (λk. z k) ⟷ summable (λk. Ln (z k))" (is "?lhs = ?rhs")
proof
assume ?lhs
then obtain p where p: "(λn. ∏k≤n. z k) ⇢ p" and "p ≠ 0"
using convergent_prod_LIMSEQ prodinf_nonzero add_eq_0_iff assms by fastforce
then show ?rhs
using Ln_prodinf_complex assms
by (auto simp: prodinf_nonzero summable_def sums_def_le)
next
assume R: ?rhs
have "(∏k≤n. z k) = exp (∑k≤n. Ln (z k))" for n
by (simp add: exp_sum add_eq_0_iff assms)
then have "(λn. ∏k≤n. z k) ⇢ exp (suminf (λk. Ln (z k)))"
using continuous_imp_tendsto [OF isCont_exp summable_LIMSEQ' [OF R]] by (simp add: o_def)
then show ?lhs
by (subst convergent_prod_iff_convergent) (auto simp: convergent_def tendsto_Lim assms add_eq_0_iff)
qed
text‹Prop 17.3 of Bak and Newman, Complex Analysis›
proposition summable_imp_convergent_prod_complex:
fixes z :: "nat ⇒ complex"
assumes z: "summable (λk. norm (z k))" and non0: "⋀k. z k ≠ -1"
shows "convergent_prod (λk. 1 + z k)"
proof -
obtain N where "⋀k. k≥N ⟹ norm (z k) < 1/2"
using summable_LIMSEQ_zero [OF z]
by (metis diff_zero dist_norm half_gt_zero_iff less_numeral_extra(1) lim_sequentially tendsto_norm_zero_iff)
then have "summable (λk. Ln (1 + z k))"
by (metis norm_Ln_le summable_comparison_test summable_mult z)
with non0 show ?thesis
by (simp add: add_eq_0_iff convergent_prod_iff_summable_complex)
qed
corollary summable_imp_convergent_prod_real:
fixes z :: "nat ⇒ real"
assumes z: "summable (λk. ¦z k¦)" and non0: "⋀k. z k ≠ -1"
shows "convergent_prod (λk. 1 + z k)"
proof -
have "⋀k. (complex_of_real ∘ z) k ≠ - 1"
by (metis non0 o_apply of_real_1 of_real_eq_iff of_real_minus)
with z
have "convergent_prod (λk. 1 + (complex_of_real ∘ z) k)"
by (auto intro: summable_imp_convergent_prod_complex)
then show ?thesis
using convergent_prod_of_real_iff [of "λk. 1 + z k"] by (simp add: o_def)
qed
lemma summable_Ln_complex:
fixes z :: "nat ⇒ complex"
assumes "convergent_prod z" "⋀k. z k ≠ 0"
shows "summable (λk. Ln (z k))"
using convergent_prod_def assms convergent_prod_iff_summable_complex by blast
subsection ‹Embeddings from the reals into some complete real normed field›
lemma tendsto_eq_of_real_lim:
assumes "(λn. of_real (f n) :: 'a::{complete_space,real_normed_field}) ⇢ q"
shows "q = of_real (lim f)"
proof -
have "convergent (λn. of_real (f n) :: 'a)"
using assms convergent_def by blast
then have "convergent f"
unfolding convergent_def
by (simp add: convergent_eq_Cauchy Cauchy_def)
then show ?thesis
by (metis LIMSEQ_unique assms convergentD sequentially_bot tendsto_Lim tendsto_of_real)
qed
lemma tendsto_eq_of_real:
assumes "(λn. of_real (f n) :: 'a::{complete_space,real_normed_field}) ⇢ q"
obtains r where "q = of_real r"
using tendsto_eq_of_real_lim assms by blast
lemma has_prod_of_real_iff [simp]:
"(λn. of_real (f n) :: 'a::{complete_space,real_normed_field}) has_prod of_real c ⟷ f has_prod c"
(is "?lhs = ?rhs")
proof
assume ?lhs
then show ?rhs
apply (auto simp: prod_defs LIMSEQ_prod_0 tendsto_of_real_iff simp flip: of_real_prod)
using tendsto_eq_of_real
by (metis of_real_0 tendsto_of_real_iff)
next
assume ?rhs
with tendsto_of_real_iff show ?lhs
by (fastforce simp: prod_defs simp flip: of_real_prod)
qed
end