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Diffstat (limited to 'theories7/Sets/Relations_1_facts.v')
-rwxr-xr-x | theories7/Sets/Relations_1_facts.v | 109 |
1 files changed, 109 insertions, 0 deletions
diff --git a/theories7/Sets/Relations_1_facts.v b/theories7/Sets/Relations_1_facts.v new file mode 100755 index 00000000..cf73ce8b --- /dev/null +++ b/theories7/Sets/Relations_1_facts.v @@ -0,0 +1,109 @@ +(************************************************************************) +(* v * The Coq Proof Assistant / The Coq Development Team *) +(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *) +(* \VV/ **************************************************************) +(* // * This file is distributed under the terms of the *) +(* * GNU Lesser General Public License Version 2.1 *) +(************************************************************************) +(****************************************************************************) +(* *) +(* 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. *) +(****************************************************************************) + +(*i $Id: Relations_1_facts.v,v 1.1.2.1 2004/07/16 19:31:40 herbelin Exp $ i*) + +Require Export Relations_1. + +Definition Complement : (U: Type) (Relation U) -> (Relation U) := + [U: Type] [R: (Relation U)] [x,y: U] ~ (R x y). + +Theorem Rsym_imp_notRsym: (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 : + (U: Type) (R: (Relation U)) (Preorder U R) -> + (Equivalence U [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. +2:Red; Intros x y h; Elim h; Intros H'3 H'4; 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. +Qed. +Hints Resolve Equiv_from_preorder. + +Theorem Equiv_from_order : + (U: Type) (R: (Relation U)) (Order U R) -> + (Equivalence U [x,y: U] (R x y) /\ (R y x)). +Proof. +Intros U R H'; Elim H'; Auto 10 with sets. +Qed. +Hints Resolve Equiv_from_order. + +Theorem contains_is_preorder : + (U: Type) (Preorder (Relation U) (contains U)). +Proof. +Auto 10 with sets. +Qed. +Hints Resolve contains_is_preorder. + +Theorem same_relation_is_equivalence : + (U: Type) (Equivalence (Relation U) (same_relation U)). +Proof. +Unfold 1 same_relation; Auto 10 with sets. +Qed. +Hints Resolve same_relation_is_equivalence. + +Theorem cong_reflexive_same_relation: + (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: + (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: + (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: + (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. |