From: Andrea Asperti Date: Mon, 10 Dec 2012 08:55:22 +0000 (+0000) Subject: Porting chebyshev X-Git-Tag: make_still_working~1400 X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=commitdiff_plain;h=9b93455c674edb6e5d5d034df52666fedfe04bd4;p=helm.git Porting chebyshev --- diff --git a/matita/matita/lib/arithmetics/bigops.ma b/matita/matita/lib/arithmetics/bigops.ma index 97bda394d..247af0b92 100644 --- a/matita/matita/lib/arithmetics/bigops.ma +++ b/matita/matita/lib/arithmetics/bigops.ma @@ -314,46 +314,45 @@ theorem bigop_distr: ∀n,p,B,nil.∀R:Dop B nil.∀f,a. ] qed. -(* Sigma e Pi +(* Sigma e Pi *) - -notation "Σ_{ ident i < n | p } f" +notation "∑_{ ident i < n | p } f" with precedence 80 -for @{'bigop $n plus 0 (λ${ident i}.p) (λ${ident i}. $f)}. +for @{'bigop $n plus 0 (λ${ident i}. $p) (λ${ident i}. $f)}. -notation "Σ_{ ident i < n } f" +notation "∑_{ ident i < n } f" with precedence 80 for @{'bigop $n plus 0 (λ${ident i}.true) (λ${ident i}. $f)}. -notation "Σ_{ ident j ∈ [a,b[ } f" +notation "∑_{ ident j ∈ [a,b[ } f" with precedence 80 for @{'bigop ($b-$a) plus 0 (λ${ident j}.((λ${ident j}.true) (${ident j}+$a))) (λ${ident j}.((λ${ident j}.$f)(${ident j}+$a)))}. -notation "Σ_{ ident j ∈ [a,b[ | p } f" +notation "∑_{ ident j ∈ [a,b[ | p } f" with precedence 80 for @{'bigop ($b-$a) plus 0 (λ${ident j}.((λ${ident j}.$p) (${ident j}+$a))) (λ${ident j}.((λ${ident j}.$f)(${ident j}+$a)))}. -notation "Π_{ ident i < n | p} f" +notation "∏_{ ident i < n | p} f" with precedence 80 for @{'bigop $n times 1 (λ${ident i}.$p) (λ${ident i}. $f)}. -notation "Π_{ ident i < n } f" +notation "∏_{ ident i < n } f" with precedence 80 for @{'bigop $n times 1 (λ${ident i}.true) (λ${ident i}. $f)}. -notation "Π_{ ident j ∈ [a,b[ } f" +notation "∏_{ ident j ∈ [a,b[ } f" with precedence 80 for @{'bigop ($b-$a) times 1 (λ${ident j}.((λ${ident j}.true) (${ident j}+$a))) (λ${ident j}.((λ${ident j}.$f)(${ident j}+$a)))}. -notation "Π_{ ident j ∈ [a,b[ | p } f" +notation "∏_{ ident j ∈ [a,b[ | p } f" with precedence 80 for @{'bigop ($b-$a) times 1 (λ${ident j}.((λ${ident j}.$p) (${ident j}+$a))) (λ${ident j}.((λ${ident j}.$f)(${ident j}+$a)))}. -*) + (* definition p_ord_times \def diff --git a/matita/matita/lib/arithmetics/log.ma b/matita/matita/lib/arithmetics/log.ma index b48aea3f8..513c11e06 100644 --- a/matita/matita/lib/arithmetics/log.ma +++ b/matita/matita/lib/arithmetics/log.ma @@ -1,474 +1,226 @@ -(**************************************************************************) -(* ___ *) -(* ||M|| *) -(* ||A|| A project by Andrea Asperti *) -(* ||T|| *) -(* ||I|| Developers: *) -(* ||T|| A.Asperti, C.Sacerdoti Coen, *) -(* ||A|| E.Tassi, S.Zacchiroli *) -(* \ / *) -(* \ / Matita is distributed under the terms of the *) -(* v GNU Lesser General Public License Version 2.1 *) -(* *) -(**************************************************************************) - (* -include "datatypes/constructors.ma". -include "nat/minimization.ma". -include "nat/relevant_equations.ma". -include "nat/primes.ma". -include "nat/iteration2.ma". -include "nat/div_and_mod_diseq.ma". + ||M|| This file is part of HELM, an Hypertextual, Electronic + ||A|| Library of Mathematics, developed at the Computer Science + ||T|| Department of the University of Bologna, Italy. + ||I|| + ||T|| + ||A|| This file is distributed under the terms of the + \ / GNU General Public License Version 2 + \ / + V_______________________________________________________________ *) + +include "arithmetics/exp.ma". +include "arithmetics/minimization.ma". +include "arithmetics/div_and_mod.ma". -definition log \def \lambda p,n. -max n (\lambda x.leb (exp p x) n). +definition log ≝ λp,n. + max n (λx.leb (exp p x) n). -theorem le_exp_log: \forall p,n. O < n \to -exp p (log p n) \le n. -intros. -apply leb_true_to_le. -unfold log. -apply (f_max_true (\lambda x.leb (exp p x) n)). -apply (ex_intro ? ? O). -split - [apply le_O_n - |apply le_to_leb_true.simplify.assumption +lemma tech_log : ∀p,n. 1

Hleb % ] +qed. + +theorem le_exp_log: ∀p,n. O < n → + exp p (log p n) ≤ n. +#a #n #posn @leb_true_to_le +(* whd in match (log ??); *) +@(f_max_true (λx.leb (exp a x) n)) %{0} % // +@le_to_leb_true // qed. -theorem log_SO: \forall n. S O < n \to log n (S O) = O. -intros. -apply sym_eq.apply le_n_O_to_eq. -apply (le_exp_to_le n) - [assumption - |simplify in ⊢ (? ? %). - apply le_exp_log. - apply le_n - ] +theorem log_SO: ∀n. 1 < n → log n 1 = O. +#n #lt1n @sym_eq @le_n_O_to_eq @(le_exp_to_le n) // qed. -theorem lt_to_log_O: \forall n,m. O < m \to m < n \to log n m = O. -intros. -apply sym_eq.apply le_n_O_to_eq. -apply le_S_S_to_le. -apply (lt_exp_to_lt n) - [apply (le_to_lt_to_lt ? m);assumption - |simplify in ⊢ (? ? %). - rewrite < times_n_SO. - apply (le_to_lt_to_lt ? m) - [apply le_exp_log.assumption - |assumption - ] +theorem lt_to_log_O: ∀n,m. O < m → m < n → log n m = O. +#n #m #posm #ltnm @sym_eq @le_n_O_to_eq @le_S_S_to_le @(lt_exp_to_lt n) + [@(le_to_lt_to_lt ? m) // + |normalize in ⊢ (??%); (exp_n_SO p). -apply (lt_max_to_false ? ? ? H2). -assumption. +theorem lt_O_log: ∀p, n. 1 < n → p ≤ n → O < log p n. +#p #n #lt1p #lepn whd in match (log ??); +@not_lt_to_le % #H lapply (lt_max_to_false ??? lt1p H) +(le_to_leb_true … lepn) #H destruct qed. -theorem le_log_n_n: \forall p,n. S O < p \to log p n \le n. -intros. -cases n - [apply le_n - |apply lt_to_le. - apply lt_log_n_n - [assumption|apply lt_O_S] - ] +theorem le_log_n_n: ∀p,n. 1 < p → log p n ≤ n. +#p #n #lt1p cases n [@le_n |#m @lt_to_le @lt_log_n_n //] qed. -theorem lt_exp_log: \forall p,n. S O < p \to n < exp p (S (log p n)). -intros.cases n - [simplify.rewrite < times_n_SO.apply lt_to_le.assumption - |apply not_le_to_lt. - apply leb_false_to_not_le. - apply (lt_max_to_false ? (S n1) (S (log p (S n1)))) - [apply le_S_S.apply le_n - |apply lt_log_n_n - [assumption|apply lt_O_S] - ] - ] -qed. +axiom daemon : ∀P:Prop.P. + +theorem lt_exp_log: ∀p,n. 1 < p → n < exp p (S (log p n)). +#p #n #lt1p cases n + [normalize times_n_SO. - apply le_times;assumption +theorem log_times1: ∀p,n,m. 1 < p → O < n → O < m → + log p (n*m) ≤ S(log p n+log p m). +#p #n #m #lt1p #posn #posm +whd in ⊢ (?(%??)?); @f_false_to_le_max + [%{O} % + [>(times_n_O 0) in ⊢ (?%%); @lt_times // + |@le_to_leb_true normalize >(times_n_O 0) in ⊢ (?%%); @lt_times // ] - |intros. - apply lt_to_leb_false. - apply (lt_to_le_to_lt ? ((exp p (S(log p n)))*(exp p (S(log p m))))) - [apply lt_times;apply lt_exp_log;assumption - |rewrite < exp_plus_times. - apply le_exp - [apply lt_to_le.assumption - |simplify. - rewrite < plus_n_Sm. - assumption - ] + |#i #Hm @lt_to_leb_false + @(lt_to_le_to_lt ? ((exp p (S(log p n)))*(exp p (S(log p m))))) + [@lt_times @lt_exp_log // + | log_SO - [simplify. - rewrite < plus_n_O. - apply le_log_n_n. - assumption - |assumption - ] - |elim H1 - [rewrite > log_SO - [rewrite < plus_n_O. - rewrite < times_n_SO. - apply le_log_n_n. - assumption - |assumption - ] - |apply (trans_le ? (S n1 + S n2)) - [apply le_plus;apply le_log_n_n;assumption - |simplify. - apply le_S_S. - rewrite < plus_n_Sm. - change in ⊢ (? % ?) with ((S n1)+n2). - rewrite > sym_plus. - apply le_plus_r. - change with (n1 < n1*S n2). - rewrite > times_n_SO in ⊢ (? % ?). - apply lt_times_r1 - [assumption - |apply le_S_S.assumption - ] +theorem log_times: ∀p,n,m. 1 < p → + log p (n*m) ≤ S(log p n+log p m). +#p #n #m #lt1p cases n // -n #n cases m + [(log_SO … lt1p) >commutative_times (log_SO … lt1p) < plus_n_O commutative_plus normalize >plus_n_Sm + @monotonic_le_plus_r >(times_n_1 n) in ⊢ (?%?); + @monotonic_lt_times_r // @le_S_S // ] ] ] - |apply le_to_leb_true. - rewrite > exp_plus_times. - apply le_times;apply le_exp_log;assumption + |@le_to_leb_true >exp_plus_times @le_times @le_exp_log // ] qed. -theorem log_exp: \forall p,n,m.S O < p \to O < m \to -log p ((exp p n)*m)=n+log p m. -intros. -unfold log in ⊢ (? ? (% ? ?) ?). -apply max_spec_to_max. -unfold max_spec. -split - [split - [elim n - [simplify. - rewrite < plus_n_O. - apply le_log_n_n. - assumption - |simplify. - rewrite > assoc_times. - apply (trans_le ? ((S(S O))*(p\sup n1*m))) - [apply le_S_times_SSO - [rewrite > (times_n_O O) in ⊢ (? % ?). - apply lt_times - [apply lt_O_exp. - apply lt_to_le. - assumption - |assumption - ] - |assumption - ] - |apply le_times - [assumption - |apply le_n - ] - ] - ] - |simplify. - apply le_to_leb_true. - rewrite > exp_plus_times. - apply le_times_r. - apply le_exp_log. - assumption +theorem log_exp: ∀p,n,m. 1 < p → O < m → + log p ((exp p n)*m)=n+log p m. +#p #n #m #lt1p #posm whd in ⊢ (??(%??)?); +@max_spec_to_max % + [elim n + [<(exp_n_O p) >commutative_times (commutative_times ? p) + >associative_times >(times_n_1 (p^a * m)) in ⊢ (?%?); + >commutative_times in ⊢ (?%?); @monotonic_lt_times_l // + >(times_n_O 0) @lt_times // @lt_O_exp @lt_to_le // ] - |intros. - simplify. - apply lt_to_leb_false. - apply (lt_to_le_to_lt ? ((exp p n)*(exp p (S(log p m))))) - [apply lt_times_r1 - [apply lt_O_exp.apply lt_to_le.assumption - |apply lt_exp_log.assumption - ] - |rewrite < exp_plus_times. - apply le_exp - [apply lt_to_le.assumption - |rewrite < plus_n_Sm. - assumption - ] + |@le_to_leb_true >exp_plus_times + @monotonic_le_times_r @le_exp_log // + |#i #Hi #Hm @lt_to_leb_false + @(lt_to_le_to_lt ? ((exp p n)*(exp p (S(log p m))))) + [@monotonic_lt_times_r [@lt_O_exp @lt_to_le // |@lt_exp_log //] + | times_n_SO in ⊢ (? ? (? ? %) ?). -rewrite > log_exp - [rewrite > log_SO - [rewrite < plus_n_O.reflexivity - |assumption - ] - |assumption - |apply le_n - ] +theorem eq_log_exp: ∀p,n. 1< p → + log p (exp p n)=n. +#p #n #lt1p >(times_n_1 (p^n)) in ⊢ (??(??%)?); >log_exp // >log_SO // qed. -theorem log_exp1: \forall p,n,m.S O < p \to -log p (exp n m) \le m*S(log p n). -intros.elim m - [simplify in ⊢ (? (? ? %) ?). - rewrite > log_SO - [apply le_O_n - |assumption - ] - |simplify. - apply (trans_le ? (S (log p n+log p (n\sup n1)))) - [apply log_times.assumption - |apply le_S_S. - apply le_plus_r. - assumption - ] +theorem log_exp1: ∀p,n,m. 1 < p → + log p (exp n m) ≤ m*S(log p n). +#p #n #m #lt1p elim m // -m #m #Hind +@(transitive_le ? (S (log p n+log p (n\sup m)))) + [whd in match (exp ??); >commutative_times @log_times // + |@le_S_S @monotonic_le_plus_r // ] qed. -theorem log_exp2: \forall p,n,m.S O < p \to O < n \to -m*(log p n) \le log p (exp n m). -intros. -apply le_S_S_to_le. -apply (lt_exp_to_lt p) - [assumption - |rewrite > sym_times. - rewrite < exp_exp_times. - apply (le_to_lt_to_lt ? (exp n m)) - [elim m - [simplify.apply le_n - |simplify.apply le_times - [apply le_exp_log. - assumption - |assumption - ] - ] - |apply lt_exp_log. - assumption +theorem log_exp2: ∀p,n,m. 1 < p → 0 < n → + m*(log p n) ≤ log p (exp n m). +#p #n #m #ltp1 #posn @le_S_S_to_le @(lt_exp_to_lt p) + [@lt_to_le // + |>commutative_times H1;simplify;apply (trans_le ? n) - [apply le_log_n_n;assumption - |apply le_n_Sn] - |intro;unfold log;simplify;rewrite > H1;simplify;apply le_max_f_max_g; - intros;apply le_to_leb_true;constructor 2;apply leb_true_to_le;assumption] +lemma le_log_S: ∀p,n.1 < p → + log p n ≤ log p (S n). +#p #n #lt1p normalize cases (leb (exp p n) (S n)) normalize // +@le_max_f_max_g #i #ltin #H @le_to_leb_true @le_S @leb_true_to_le // qed. -theorem le_log: \forall p,n,m. S O < p \to n \le m \to -log p n \le log p m. -intros.elim H1 - [constructor 1 - |apply (trans_le ? ? ? H3);apply le_log_plus;assumption] +theorem le_log: ∀p,n,m. 1 < p → n ≤ m → + log p n ≤ log p m. +#p #n #m #lt1p #lenm elim lenm // -m #m #lenm #Hind +@(transitive_le … Hind) @le_log_S // qed. -theorem log_div: \forall p,n,m. S O < p \to O < m \to m \le n \to -log p (n/m) \le log p n -log p m. -intros. -apply le_plus_to_minus_r. -apply (trans_le ? (log p ((n/m)*m))) - [apply log_times_l - [apply le_times_to_le_div - [assumption - |rewrite < times_n_SO. - assumption - ] - |assumption - |assumption - ] - |apply le_log - [assumption - |rewrite > (div_mod n m) in ⊢ (? ? %) - [apply le_plus_n_r - |assumption - ] - ] - ] -qed. - -theorem log_n_n: \forall n. S O < n \to log n n = S O. -intros. -rewrite > exp_n_SO in ⊢ (? ? (? ? %) ?). -rewrite > times_n_SO in ⊢ (? ? (? ? %) ?). -rewrite > log_exp - [rewrite > log_SO - [reflexivity - |assumption - ] - |assumption - |apply le_n - ] -qed. - -theorem log_i_SSOn: \forall n,i. S O < n \to n < i \to i \le ((S(S O))*n) \to -log i ((S(S O))*n) = S O. -intros. -apply antisymmetric_le - [apply not_lt_to_le.intro. - apply (lt_to_not_le ((S(S O)) * n) (exp i (S(S O)))) - [rewrite > exp_SSO. - apply lt_times - [apply (le_to_lt_to_lt ? n);assumption - |assumption - ] - |apply (trans_le ? (exp i (log i ((S(S O))*n)))) - [apply le_exp - [apply (ltn_to_ltO ? ? H1) - |assumption - ] - |apply le_exp_log. - rewrite > (times_n_O O) in ⊢ (? % ?). - apply lt_times - [apply lt_O_S - |apply lt_to_le.assumption - ] +theorem log_div: ∀p,n,m. 1 < p → O < m → m ≤ n → + log p (n/m) ≤ log p n -log p m. +#p #n #m #lt1p #posn #lemn +@le_plus_to_minus_r @(transitive_le ? (log p ((n/m)*m))) + [@log_times_l // @le_times_to_le_div // + |@le_log // + ] +qed. + +theorem log_n_n: ∀n. 1 < n → log n n = 1. +#n #lt1n >(exp_n_1 n) in ⊢ (??(??%)?); +>(times_n_1 (n^1)) in ⊢ (??(??%)?); >log_exp // +qed. + +theorem log_i_2n: ∀n,i. 1 < n → n < i → i ≤ 2*n → + log i (2*n) = 1. +#n #i #lt1n #ltni #lei +cut (∀a,b. a≤b → b≤a → a=b) + [#a #b #leab #leba cases (le_to_or_lt_eq … leab) + [#ltab @False_ind @(absurd ? ltab) @le_to_not_lt // | //]] #Hcut +@Hcut + [@not_lt_to_le % #H + @(absurd ?? (lt_to_not_le (2 * n) (exp i 2) ?)) + [@(transitive_le ? (exp i (log i (2*n)))) + [@le_exp // @(ltn_to_ltO ? ? ltni) + |@le_exp_log >(times_n_O O) in ⊢ (?%?); @lt_times // @lt_to_le // ] + |>exp_2 @lt_times @(le_to_lt_to_lt ? n) // ] - |apply (trans_le ? (log i i)) - [rewrite < (log_n_n i) in ⊢ (? % ?) - [apply le_log - [apply (trans_lt ? n);assumption - |apply le_n - ] - |apply (trans_lt ? n);assumption - ] - |apply le_log - [apply (trans_lt ? n);assumption - |assumption - ] + |@(transitive_le ? (log i i)) + [<(log_n_n i) in ⊢ (?%?); // @(transitive_lt … lt1n) // + |@le_log // @(transitive_lt … lt1n) // ] ] qed. -theorem exp_n_O: \forall n. O < n \to exp O n = O. -intros.apply (lt_O_n_elim ? H).intros. -simplify.reflexivity. +theorem exp_n_O: ∀n. O < n → exp O n = O. +#n #posn @(lt_O_n_elim ? posn) normalize // qed. -(* -theorem tech1: \forall n,i.O < n \to -(exp (S n) (S(S i)))/(exp n (S i)) \le ((exp n i) + (exp (S n) (S i)))/(exp n i). -intros. -simplify in ⊢ (? (? ? %) ?). -rewrite < eq_div_div_div_times - [apply monotonic_div - [apply lt_O_exp.assumption - |apply le_S_S_to_le. - apply lt_times_to_lt_div. - change in ⊢ (? % ?) with ((exp (S n) (S i)) + n*(exp (S n) (S i))). - - - |apply (trans_le ? ((n)\sup(i)*(S n)\sup(S i)/(n)\sup(S i))) - [apply le_times_div_div_times. - apply lt_O_exp.assumption - |apply le_times_to_le_div2 - [apply lt_O_exp.assumption - |simplify. - -theorem tech1: \forall a,b,n,m.O < m \to -n/m \le b \to (a*n)/m \le a*b. -intros. -apply le_times_to_le_div2 - [assumption - | - -theorem tech2: \forall n,m. O < n \to -(exp (S n) m) / (exp n m) \le (n + m)/n. -intros. -elim m - [rewrite < plus_n_O.simplify. - rewrite > div_n_n.apply le_n - |apply le_times_to_le_div - [assumption - |apply (trans_le ? (n*(S n)\sup(S n1)/(n)\sup(S n1))) - [apply le_times_div_div_times. - apply lt_O_exp - |simplify in ⊢ (? (? ? %) ?). - rewrite > sym_times in ⊢ (? (? ? %) ?). - rewrite < eq_div_div_div_times - [apply le_times_to_le_div2 - [assumption - | - - -theorem le_log_sigma_p:\forall n,m,p. O < m \to S O < p \to -log p (exp n m) \le sigma_p n (\lambda i.true) (\lambda i. (m / i)). -intros. -elim n - [rewrite > exp_n_O - [simplify.apply le_n - |assumption - ] - |rewrite > true_to_sigma_p_Sn - [apply (trans_le ? (m/n1+(log p (exp n1 m)))) - [ -*) -*) diff --git a/matita/matita/lib/arithmetics/minimization.ma b/matita/matita/lib/arithmetics/minimization.ma index 35f177331..27629180c 100644 --- a/matita/matita/lib/arithmetics/minimization.ma +++ b/matita/matita/lib/arithmetics/minimization.ma @@ -140,6 +140,13 @@ theorem f_max_true : ∀ f.∀n. #Hall * #x * #ltx #fx @False_ind @(absurd … fx) >Hall /2/ qed. +theorem f_false_to_le_max: ∀f,n,p. (∃i:nat.iext // |(cases (g b)) normalize /2/ @Hind #i #ltb #ltim #fi @ext /2/ + ] qed. theorem f_min_true : ∀ f.∀n,b.