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Quellcode-Bibliothek© Kompilation durch diese Firma[Weder Korrektheit noch Funktionsfähigkeit der Software werden zugesichert.]Datei: Relations_1_facts.v Sprache: CoqOriginal von: Coq© |
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(* * The Coq Proof Assistant / The Coq Development Team *) (* v * INRIA, CNRS and contributors - Copyright 1999-2018 *) (* <O___,, * (see CREDITS file for the list of authors) *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (* * (see LICENSE file for the text of the license) *) (************************************************************************) (****************************************************************************) (* *) (* Naive Set Theory in Coq *) (* *) (* INRIA INRIA *) (* Rocquencourt Sophia-Antipolis *) (* *) (* Coq V6.1 *) (* *) (* Gilles Kahn *) (* Gerard Huet *) (* *) (* *) (* *) (* Acknowledgments: This work was started in July 1993 by F. Prost. Thanks *) (* to the Newton Institute for providing an exceptional work environment *) (* in Summer 1995. Several developments by E. Ledinot were an inspiration. *) (****************************************************************************) Require Export Relations_1. Definition Complement (U:Type) (R:Relation U) : Relation U := fun x y:U => ~ R x y. Theorem Rsym_imp_notRsym : forall (U:Type) (R:Relation U), Symmetric U R -> Symmetric U (Complement U R). Proof. unfold Symmetric, Complement. intros U R H' x y H'0; red; intro H'1; apply H'0; auto with sets. Qed. Theorem Equiv_from_preorder : forall (U:Type) (R:Relation U), Preorder U R -> Equivalence U (fun x y:U => R x y /\ R y x). Proof. intros U R H'; elim H'; intros H'0 H'1. apply Definition_of_equivalence. - red in H'0; auto 10 with sets. - red in H'1; red; auto 10 with sets. intros x y z h; elim h; intros H'3 H'4; clear h. intro h; elim h; intros H'5 H'6; clear h. split; apply H'1 with y; auto 10 with sets. - red; intros x y h; elim h; intros H'3 H'4; auto 10 with sets. Qed. Hint Resolve Equiv_from_preorder : core. Theorem Equiv_from_order : forall (U:Type) (R:Relation U), Order U R -> Equivalence U (fun x y:U => R x y /\ R y x). Proof. intros U R H'; elim H'; auto 10 with sets. Qed. Hint Resolve Equiv_from_order : core. Theorem contains_is_preorder : forall U:Type, Preorder (Relation U) (contains U). Proof. auto 10 with sets. Qed. Hint Resolve contains_is_preorder : core. Theorem same_relation_is_equivalence : forall U:Type, Equivalence (Relation U) (same_relation U). Proof. unfold same_relation at 1; auto 10 with sets. Qed. Hint Resolve same_relation_is_equivalence : core. Theorem cong_reflexive_same_relation : forall (U:Type) (R R':Relation U), same_relation U R R' -> Reflexive U R -> Reflexive U R'. Proof. unfold same_relation; intuition. Qed. Theorem cong_symmetric_same_relation : forall (U:Type) (R R':Relation U), same_relation U R R' -> Symmetric U R -> Symmetric U R'. Proof. compute; intros; elim H; intros; clear H; apply (H3 y x (H0 x y (H2 x y H1))). (*Intuition.*) Qed. Theorem cong_antisymmetric_same_relation : forall (U:Type) (R R':Relation U), same_relation U R R' -> Antisymmetric U R -> Antisymmetric U R'. Proof. compute; intros; elim H; intros; clear H; apply (H0 x y (H3 x y H1) (H3 y x H2)). (*Intuition.*) Qed. Theorem cong_transitive_same_relation : forall (U:Type) (R R':Relation U), same_relation U R R' -> Transitive U R -> Transitive U R'. Proof. intros U R R' H' H'0; red. elim H'. intros H'1 H'2 x y z H'3 H'4; apply H'2. apply H'0 with y; auto with sets. Qed. ¤ Dauer der Verarbeitung: 0.0 Sekunden (vorverarbeitet) ¤ |
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