(* Title: ZF/Constructible/Wellorderings.thy ID: $Id: Wellorderings.thy,v 1.22 2005/06/17 14:15:10 haftmann Exp $ Author: Lawrence C Paulson, Cambridge University Computer Laboratory *) header {*Relativized Wellorderings*} theory Wellorderings imports Relative begin text{*We define functions analogous to @{term ordermap} @{term ordertype} but without using recursion. Instead, there is a direct appeal to Replacement. This will be the basis for a version relativized to some class @{text M}. The main result is Theorem I 7.6 in Kunen, page 17.*} subsection{*Wellorderings*} constdefs irreflexive :: "[i=>o,i,i]=>o" "irreflexive(M,A,r) == \x[M]. x\A --> \ r" transitive_rel :: "[i=>o,i,i]=>o" "transitive_rel(M,A,r) == \x[M]. x\A --> (\y[M]. y\A --> (\z[M]. z\A --> \r --> \r --> \r))" linear_rel :: "[i=>o,i,i]=>o" "linear_rel(M,A,r) == \x[M]. x\A --> (\y[M]. y\A --> \r | x=y | \r)" wellfounded :: "[i=>o,i]=>o" --{*EVERY non-empty set has an @{text r}-minimal element*} "wellfounded(M,r) == \x[M]. x\0 --> (\y[M]. y\x & ~(\z[M]. z\x & \ r))" wellfounded_on :: "[i=>o,i,i]=>o" --{*every non-empty SUBSET OF @{text A} has an @{text r}-minimal element*} "wellfounded_on(M,A,r) == \x[M]. x\0 --> x\A --> (\y[M]. y\x & ~(\z[M]. z\x & \ r))" wellordered :: "[i=>o,i,i]=>o" --{*linear and wellfounded on @{text A}*} "wellordered(M,A,r) == transitive_rel(M,A,r) & linear_rel(M,A,r) & wellfounded_on(M,A,r)" subsubsection {*Trivial absoluteness proofs*} lemma (in M_basic) irreflexive_abs [simp]: "M(A) ==> irreflexive(M,A,r) <-> irrefl(A,r)" by (simp add: irreflexive_def irrefl_def) lemma (in M_basic) transitive_rel_abs [simp]: "M(A) ==> transitive_rel(M,A,r) <-> trans[A](r)" by (simp add: transitive_rel_def trans_on_def) lemma (in M_basic) linear_rel_abs [simp]: "M(A) ==> linear_rel(M,A,r) <-> linear(A,r)" by (simp add: linear_rel_def linear_def) lemma (in M_basic) wellordered_is_trans_on: "[| wellordered(M,A,r); M(A) |] ==> trans[A](r)" by (auto simp add: wellordered_def) lemma (in M_basic) wellordered_is_linear: "[| wellordered(M,A,r); M(A) |] ==> linear(A,r)" by (auto simp add: wellordered_def) lemma (in M_basic) wellordered_is_wellfounded_on: "[| wellordered(M,A,r); M(A) |] ==> wellfounded_on(M,A,r)" by (auto simp add: wellordered_def) lemma (in M_basic) wellfounded_imp_wellfounded_on: "[| wellfounded(M,r); M(A) |] ==> wellfounded_on(M,A,r)" by (auto simp add: wellfounded_def wellfounded_on_def) lemma (in M_basic) wellfounded_on_subset_A: "[| wellfounded_on(M,A,r); B<=A |] ==> wellfounded_on(M,B,r)" by (simp add: wellfounded_on_def, blast) subsubsection {*Well-founded relations*} lemma (in M_basic) wellfounded_on_iff_wellfounded: "wellfounded_on(M,A,r) <-> wellfounded(M, r \ A*A)" apply (simp add: wellfounded_on_def wellfounded_def, safe) apply force apply (drule_tac x=x in rspec, assumption, blast) done lemma (in M_basic) wellfounded_on_imp_wellfounded: "[|wellfounded_on(M,A,r); r \ A*A|] ==> wellfounded(M,r)" by (simp add: wellfounded_on_iff_wellfounded subset_Int_iff) lemma (in M_basic) wellfounded_on_field_imp_wellfounded: "wellfounded_on(M, field(r), r) ==> wellfounded(M,r)" by (simp add: wellfounded_def wellfounded_on_iff_wellfounded, fast) lemma (in M_basic) wellfounded_iff_wellfounded_on_field: "M(r) ==> wellfounded(M,r) <-> wellfounded_on(M, field(r), r)" by (blast intro: wellfounded_imp_wellfounded_on wellfounded_on_field_imp_wellfounded) (*Consider the least z in domain(r) such that P(z) does not hold...*) lemma (in M_basic) wellfounded_induct: "[| wellfounded(M,r); M(a); M(r); separation(M, \x. ~P(x)); \x. M(x) & (\y. \ r --> P(y)) --> P(x) |] ==> P(a)"; apply (simp (no_asm_use) add: wellfounded_def) apply (drule_tac x="{z \ domain(r). ~P(z)}" in rspec) apply (blast dest: transM)+ done lemma (in M_basic) wellfounded_on_induct: "[| a\A; wellfounded_on(M,A,r); M(A); separation(M, \x. x\A --> ~P(x)); \x\A. M(x) & (\y\A. \ r --> P(y)) --> P(x) |] ==> P(a)"; apply (simp (no_asm_use) add: wellfounded_on_def) apply (drule_tac x="{z\A. z\A --> ~P(z)}" in rspec) apply (blast intro: transM)+ done subsubsection {*Kunen's lemma IV 3.14, page 123*} lemma (in M_basic) linear_imp_relativized: "linear(A,r) ==> linear_rel(M,A,r)" by (simp add: linear_def linear_rel_def) lemma (in M_basic) trans_on_imp_relativized: "trans[A](r) ==> transitive_rel(M,A,r)" by (unfold transitive_rel_def trans_on_def, blast) lemma (in M_basic) wf_on_imp_relativized: "wf[A](r) ==> wellfounded_on(M,A,r)" apply (simp add: wellfounded_on_def wf_def wf_on_def, clarify) apply (drule_tac x=x in spec, blast) done lemma (in M_basic) wf_imp_relativized: "wf(r) ==> wellfounded(M,r)" apply (simp add: wellfounded_def wf_def, clarify) apply (drule_tac x=x in spec, blast) done lemma (in M_basic) well_ord_imp_relativized: "well_ord(A,r) ==> wellordered(M,A,r)" by (simp add: wellordered_def well_ord_def tot_ord_def part_ord_def linear_imp_relativized trans_on_imp_relativized wf_on_imp_relativized) subsection{* Relativized versions of order-isomorphisms and order types *} lemma (in M_basic) order_isomorphism_abs [simp]: "[| M(A); M(B); M(f) |] ==> order_isomorphism(M,A,r,B,s,f) <-> f \ ord_iso(A,r,B,s)" by (simp add: apply_closed order_isomorphism_def ord_iso_def) lemma (in M_basic) pred_set_abs [simp]: "[| M(r); M(B) |] ==> pred_set(M,A,x,r,B) <-> B = Order.pred(A,x,r)" apply (simp add: pred_set_def Order.pred_def) apply (blast dest: transM) done lemma (in M_basic) pred_closed [intro,simp]: "[| M(A); M(r); M(x) |] ==> M(Order.pred(A,x,r))" apply (simp add: Order.pred_def) apply (insert pred_separation [of r x], simp) done lemma (in M_basic) membership_abs [simp]: "[| M(r); M(A) |] ==> membership(M,A,r) <-> r = Memrel(A)" apply (simp add: membership_def Memrel_def, safe) apply (rule equalityI) apply clarify apply (frule transM, assumption) apply blast apply clarify apply (subgoal_tac "M()", blast) apply (blast dest: transM) apply auto done lemma (in M_basic) M_Memrel_iff: "M(A) ==> Memrel(A) = {z \ A*A. \x[M]. \y[M]. z = \x,y\ & x \ y}" apply (simp add: Memrel_def) apply (blast dest: transM) done lemma (in M_basic) Memrel_closed [intro,simp]: "M(A) ==> M(Memrel(A))" apply (simp add: M_Memrel_iff) apply (insert Memrel_separation, simp) done subsection {* Main results of Kunen, Chapter 1 section 6 *} text{*Subset properties-- proved outside the locale*} lemma linear_rel_subset: "[| linear_rel(M,A,r); B<=A |] ==> linear_rel(M,B,r)" by (unfold linear_rel_def, blast) lemma transitive_rel_subset: "[| transitive_rel(M,A,r); B<=A |] ==> transitive_rel(M,B,r)" by (unfold transitive_rel_def, blast) lemma wellfounded_on_subset: "[| wellfounded_on(M,A,r); B<=A |] ==> wellfounded_on(M,B,r)" by (unfold wellfounded_on_def subset_def, blast) lemma wellordered_subset: "[| wellordered(M,A,r); B<=A |] ==> wellordered(M,B,r)" apply (unfold wellordered_def) apply (blast intro: linear_rel_subset transitive_rel_subset wellfounded_on_subset) done lemma (in M_basic) wellfounded_on_asym: "[| wellfounded_on(M,A,r); \r; a\A; x\A; M(A) |] ==> \r" apply (simp add: wellfounded_on_def) apply (drule_tac x="{x,a}" in rspec) apply (blast dest: transM)+ done lemma (in M_basic) wellordered_asym: "[| wellordered(M,A,r); \r; a\A; x\A; M(A) |] ==> \r" by (simp add: wellordered_def, blast dest: wellfounded_on_asym) end