X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=helm%2Fsoftware%2Fmatita%2Fcontribs%2Fformal_topology%2Foverlap%2Fbasic_pairs.ma;h=8e5421c1f0b39617a9896c045a7070b64c606061;hb=05cfeb82d2624860e66941421a937f308d66cf33;hp=6140e278ec5c30e0d8624d90c0b50624f67ccde9;hpb=f4b80554953fa5c452fdc9350d236fb9bcb263dd;p=helm.git diff --git a/helm/software/matita/contribs/formal_topology/overlap/basic_pairs.ma b/helm/software/matita/contribs/formal_topology/overlap/basic_pairs.ma index 6140e278e..8e5421c1f 100644 --- a/helm/software/matita/contribs/formal_topology/overlap/basic_pairs.ma +++ b/helm/software/matita/contribs/formal_topology/overlap/basic_pairs.ma @@ -13,45 +13,28 @@ (**************************************************************************) include "relations.ma". +include "notation.ma". -record basic_pair: Type1 ≝ - { concr: REL; - form: REL; - rel: arrows1 ? concr form - }. +record basic_pair: Type1 ≝ { + concr: REL; form: REL; rel: concr ⇒_\r1 form +}. -interpretation "basic pair relation" 'Vdash2 x y c = (fun21 ___ (rel c) x y). +interpretation "basic pair relation" 'Vdash2 x y c = (fun21 ??? (rel c) x y). interpretation "basic pair relation (non applied)" 'Vdash c = (rel c). -alias symbol "eq" = "setoid1 eq". -alias symbol "compose" = "category1 composition". -record relation_pair (BP1,BP2: basic_pair): Type1 ≝ - { concr_rel: arrows1 ? (concr BP1) (concr BP2); - form_rel: arrows1 ? (form BP1) (form BP2); - commute: ⊩ ∘ concr_rel = form_rel ∘ ⊩ +record relation_pair (BP1,BP2: basic_pair): Type1 ≝ { + concr_rel: (concr BP1) ⇒_\r1 (concr BP2); form_rel: (form BP1) ⇒_\r1 (form BP2); + commute: ⊩ ∘ concr_rel =_1 form_rel ∘ ⊩ }. -notation "hvbox (r \sub \c)" with precedence 90 for @{'concr_rel $r}. -notation "hvbox (r \sub \f)" with precedence 90 for @{'form_rel $r}. - -interpretation "concrete relation" 'concr_rel r = (concr_rel __ r). -interpretation "formal relation" 'form_rel r = (form_rel __ r). +interpretation "concrete relation" 'concr_rel r = (concr_rel ?? r). +interpretation "formal relation" 'form_rel r = (form_rel ?? r). -definition relation_pair_equality: - ∀o1,o2. equivalence_relation1 (relation_pair o1 o2). - intros; - constructor 1; - [ apply (λr,r'. ⊩ ∘ r \sub\c = ⊩ ∘ r' \sub\c); - | simplify; - intros; - apply refl1; - | simplify; - intros 2; - apply sym1; - | simplify; - intros 3; - apply trans1; - ] +definition relation_pair_equality: ∀o1,o2. equivalence_relation1 (relation_pair o1 o2). + intros; constructor 1; [ apply (λr,r'. ⊩ ∘ r \sub\c = ⊩ ∘ r' \sub\c); + | simplify; intros; apply refl1; + | simplify; intros 2; apply sym1; + | simplify; intros 3; apply trans1; ] qed. definition relation_pair_setoid: basic_pair → basic_pair → setoid1. @@ -67,16 +50,12 @@ definition relation_pair_of_relation_pair_setoid : coercion relation_pair_of_relation_pair_setoid. lemma eq_to_eq': - ∀o1,o2.∀r,r':relation_pair_setoid o1 o2. r=r' → r \sub\f ∘ ⊩ = r'\sub\f ∘ ⊩. - intros 7 (o1 o2 r r' H c1 f2); - split; intro H1; - [ lapply (fi ?? (commute ?? r c1 f2) H1) as H2; - lapply (if ?? (H c1 f2) H2) as H3; - apply (if ?? (commute ?? r' c1 f2) H3); - | lapply (fi ?? (commute ?? r' c1 f2) H1) as H2; - lapply (fi ?? (H c1 f2) H2) as H3; - apply (if ?? (commute ?? r c1 f2) H3); - ] + ∀o1,o2.∀r,r':relation_pair_setoid o1 o2. r =_1 r' → r \sub\f ∘ ⊩ = r'\sub\f ∘ ⊩. + intros 5 (o1 o2 r r' H); + apply (.= (commute ?? r)^-1); + change in H with (⊩ ∘ r \sub\c = ⊩ ∘ r' \sub\c); + apply rule (.= H); + apply (commute ?? r'). qed. definition id_relation_pair: ∀o:basic_pair. relation_pair o o. @@ -89,11 +68,11 @@ definition id_relation_pair: ∀o:basic_pair. relation_pair o o. apply (H1 \sup -1);] qed. -definition relation_pair_composition: - ∀o1,o2,o3. binary_morphism1 (relation_pair_setoid o1 o2) (relation_pair_setoid o2 o3) (relation_pair_setoid o1 o3). - intros; - constructor 1; - [ intros (r r1); +lemma relation_pair_composition: + ∀o1,o2,o3: basic_pair. + relation_pair_setoid o1 o2 → relation_pair_setoid o2 o3 → relation_pair_setoid o1 o3. +intros 3 (o1 o2 o3); + intros (r r1); constructor 1; [ apply (r1 \sub\c ∘ r \sub\c) | apply (r1 \sub\f ∘ r \sub\f) @@ -107,7 +86,17 @@ definition relation_pair_composition: apply (.= ASSOC ^ -1); apply (.= H‡#); apply ASSOC] - | intros; +qed. + +lemma relation_pair_composition_is_morphism: + ∀o1,o2,o3: basic_pair. + ∀a,a':relation_pair_setoid o1 o2. + ∀b,b':relation_pair_setoid o2 o3. + a=a' → b=b' → + relation_pair_composition o1 o2 o3 a b + = relation_pair_composition o1 o2 o3 a' b'. +intros 3 (o1 o2 o3); + intros; change with (⊩ ∘ (b\sub\c ∘ a\sub\c) = ⊩ ∘ (b'\sub\c ∘ a'\sub\c)); change in e with (⊩ ∘ a \sub\c = ⊩ ∘ a' \sub\c); change in e1 with (⊩ ∘ b \sub\c = ⊩ ∘ b' \sub\c); @@ -118,29 +107,64 @@ definition relation_pair_composition: apply (.= e‡#); apply (.= ASSOC); apply (.= #‡(commute ?? b')\sup -1); - apply (ASSOC ^ -1)] + apply (ASSOC ^ -1); qed. - -definition BP: category1. + +definition relation_pair_composition_morphism: + ∀o1,o2,o3. binary_morphism1 (relation_pair_setoid o1 o2) (relation_pair_setoid o2 o3) (relation_pair_setoid o1 o3). + intros; constructor 1; - [ apply basic_pair - | apply relation_pair_setoid - | apply id_relation_pair - | apply relation_pair_composition - | intros; + [ apply relation_pair_composition; + | apply relation_pair_composition_is_morphism;] +qed. + +lemma relation_pair_composition_morphism_assoc: +Πo1:basic_pair +.Πo2:basic_pair + .Πo3:basic_pair + .Πo4:basic_pair + .Πa12:relation_pair_setoid o1 o2 + .Πa23:relation_pair_setoid o2 o3 + .Πa34:relation_pair_setoid o3 o4 + .relation_pair_composition_morphism o1 o3 o4 + (relation_pair_composition_morphism o1 o2 o3 a12 a23) a34 + =relation_pair_composition_morphism o1 o2 o4 a12 + (relation_pair_composition_morphism o2 o3 o4 a23 a34). + intros; change with (⊩ ∘ (a34\sub\c ∘ (a23\sub\c ∘ a12\sub\c)) = ⊩ ∘ ((a34\sub\c ∘ a23\sub\c) ∘ a12\sub\c)); alias symbol "refl" = "refl1". alias symbol "prop2" = "prop21". apply (ASSOC‡#); - | intros; +qed. + +lemma relation_pair_composition_morphism_respects_id: + ∀o1,o2:basic_pair.∀a:relation_pair_setoid o1 o2. + relation_pair_composition_morphism o1 o1 o2 (id_relation_pair o1) a=a. + intros; change with (⊩ ∘ (a\sub\c ∘ (id_relation_pair o1)\sub\c) = ⊩ ∘ a\sub\c); - apply ((id_neutral_right1 ????)‡#); - | intros; + apply ((id_neutral_right1 ????)‡#); +qed. + +lemma relation_pair_composition_morphism_respects_id_r: + ∀o1,o2:basic_pair.∀a:relation_pair_setoid o1 o2. + relation_pair_composition_morphism o1 o2 o2 a (id_relation_pair o2)=a. + intros; change with (⊩ ∘ ((id_relation_pair o2)\sub\c ∘ a\sub\c) = ⊩ ∘ a\sub\c); - apply ((id_neutral_left1 ????)‡#);] + apply ((id_neutral_left1 ????)‡#); qed. +definition BP: category1. + constructor 1; + [ apply basic_pair + | apply relation_pair_setoid + | apply id_relation_pair + | apply relation_pair_composition_morphism + | apply relation_pair_composition_morphism_assoc; + | apply relation_pair_composition_morphism_respects_id; + | apply relation_pair_composition_morphism_respects_id_r;] +qed. + definition basic_pair_of_BP : objs1 BP → basic_pair ≝ λx.x. coercion basic_pair_of_BP. @@ -148,7 +172,8 @@ definition relation_pair_setoid_of_arrows1_BP : ∀P,Q. arrows1 BP P Q → relation_pair_setoid P Q ≝ λP,Q,x.x. coercion relation_pair_setoid_of_arrows1_BP. -definition BPext: ∀o: BP. form o ⇒ Ω \sup (concr o). +(* +definition BPext: ∀o: BP. (form o) ⇒_1 Ω^(concr o). intros; constructor 1; [ apply (ext ? ? (rel o)); | intros; @@ -156,13 +181,13 @@ definition BPext: ∀o: BP. form o ⇒ Ω \sup (concr o). apply refl1] qed. -definition BPextS: ∀o: BP. Ω \sup (form o) ⇒ Ω \sup (concr o). +definition BPextS: ∀o: BP. Ω^(form o) ⇒_1 Ω^(concr o). intros; constructor 1; [ apply (minus_image ?? (rel o)); | intros; apply (#‡e); ] qed. -definition fintersects: ∀o: BP. binary_morphism1 (form o) (form o) (Ω \sup (form o)). +definition fintersects: ∀o: BP. (form o) × (form o) ⇒_1 Ω^(form o). intros (o); constructor 1; [ apply (λa,b: form o.{c | BPext o c ⊆ BPext o a ∩ BPext o b }); intros; simplify; apply (.= (†e)‡#); apply refl1 @@ -171,27 +196,28 @@ definition fintersects: ∀o: BP. binary_morphism1 (form o) (form o) (Ω \sup (f | apply (. #‡((†e)‡(†e1))); assumption]] qed. -interpretation "fintersects" 'fintersects U V = (fun21 ___ (fintersects _) U V). +interpretation "fintersects" 'fintersects U V = (fun21 ??? (fintersects ?) U V). definition fintersectsS: - ∀o:BP. binary_morphism1 (Ω \sup (form o)) (Ω \sup (form o)) (Ω \sup (form o)). + ∀o:BP. Ω^(form o) × Ω^(form o) ⇒_1 Ω^(form o). intros (o); constructor 1; - [ apply (λo: basic_pair.λa,b: Ω \sup (form o).{c | BPext o c ⊆ BPextS o a ∩ BPextS o b }); + [ apply (λo: basic_pair.λa,b: Ω^(form o).{c | BPext o c ⊆ BPextS o a ∩ BPextS o b }); intros; simplify; apply (.= (†e)‡#); apply refl1 | intros; split; simplify; intros; [ apply (. #‡((†e^-1)‡(†e1^-1))); assumption | apply (. #‡((†e)‡(†e1))); assumption]] qed. -interpretation "fintersectsS" 'fintersects U V = (fun21 ___ (fintersectsS _) U V). +interpretation "fintersectsS" 'fintersects U V = (fun21 ??? (fintersectsS ?) U V). -definition relS: ∀o: BP. binary_morphism1 (concr o) (Ω \sup (form o)) CPROP. +definition relS: ∀o: BP. (concr o) × Ω^(form o) ⇒_1 CPROP. intros (o); constructor 1; - [ apply (λx:concr o.λS: Ω \sup (form o).∃y:form o.y ∈ S ∧ x ⊩_o y); + [ apply (λx:concr o.λS: Ω^(form o).∃y:form o.y ∈ S ∧ x ⊩⎽o y); | intros; split; intros; cases e2; exists [1,3: apply w] [ apply (. (#‡e1^-1)‡(e^-1‡#)); assumption | apply (. (#‡e1)‡(e‡#)); assumption]] qed. -interpretation "basic pair relation for subsets" 'Vdash2 x y c = (fun21 (concr _) __ (relS c) x y). -interpretation "basic pair relation for subsets (non applied)" 'Vdash c = (fun21 ___ (relS c)). +interpretation "basic pair relation for subsets" 'Vdash2 x y c = (fun21 (concr ?) ?? (relS c) x y). +interpretation "basic pair relation for subsets (non applied)" 'Vdash c = (fun21 ??? (relS c)). +*)