section‹Partial and Total Orderings: Basic Definitions and Properties›
theory Order imports WF Perm begin
text ‹We adopt the following convention: ‹ord› is used for
strict orders and ‹order› is used for their reflexive
counterparts.›
definition
part_ord :: "[i,i]=>o" where
"part_ord(A,r) == irrefl(A,r) & trans[A](r)"
definition
linear :: "[i,i]=>o" where
"linear(A,r) == (∀x∈A. ∀y∈A. <x,y>:r | x=y | <y,x>:r)"
definition
tot_ord :: "[i,i]=>o" where
"tot_ord(A,r) == part_ord(A,r) & linear(A,r)"
definition
"preorder_on(A, r) ≡ refl(A, r) ∧ trans[A](r)"
definition
"partial_order_on(A, r) ≡ preorder_on(A, r) ∧ antisym(r)"
abbreviation
"Preorder(r) ≡ preorder_on(field(r), r)"
abbreviation
"Partial_order(r) ≡ partial_order_on(field(r), r)"
definition
well_ord :: "[i,i]=>o" where
"well_ord(A,r) == tot_ord(A,r) & wf[A](r)"
definition
mono_map :: "[i,i,i,i]=>i" where
"mono_map(A,r,B,s) ==
{f ∈ A->B. ∀x∈A. ∀y∈A. <x,y>:r ⟶ <f`x,f`y>:s}"
definition
ord_iso :: "[i,i,i,i]=>i" (‹(⟨_, _⟩ ≅/ ⟨_, _⟩)› 51) where
"⟨A,r⟩ ≅ ⟨B,s⟩ ==
{f ∈ bij(A,B). ∀x∈A. ∀y∈A. <x,y>:r ⟷ <f`x,f`y>:s}"
definition
pred :: "[i,i,i]=>i" where
"pred(A,x,r) == {y ∈ A. <y,x>:r}"
definition
ord_iso_map :: "[i,i,i,i]=>i" where
"ord_iso_map(A,r,B,s) ==
⋃x∈A. ⋃y∈B. ⋃f ∈ ord_iso(pred(A,x,r), r, pred(B,y,s), s). {<x,y>}"
definition
first :: "[i, i, i] => o" where
"first(u, X, R) == u ∈ X & (∀v∈X. v≠u ⟶ <u,v> ∈ R)"
subsection‹Immediate Consequences of the Definitions›
lemma part_ord_Imp_asym:
"part_ord(A,r) ==> asym(r ∩ A*A)"
by (unfold part_ord_def irrefl_def trans_on_def asym_def, blast)
lemma linearE:
"[| linear(A,r); x ∈ A; y ∈ A;
<x,y>:r ==> P; x=y ==> P; <y,x>:r ==> P |]
==> P"
by (simp add: linear_def, blast)
lemma well_ordI:
"[| wf[A](r); linear(A,r) |] ==> well_ord(A,r)"
apply (simp add: irrefl_def part_ord_def tot_ord_def
trans_on_def well_ord_def wf_on_not_refl)
apply (fast elim: linearE wf_on_asym wf_on_chain3)
done
lemma well_ord_is_wf:
"well_ord(A,r) ==> wf[A](r)"
by (unfold well_ord_def, safe)
lemma well_ord_is_trans_on:
"well_ord(A,r) ==> trans[A](r)"
by (unfold well_ord_def tot_ord_def part_ord_def, safe)
lemma well_ord_is_linear: "well_ord(A,r) ==> linear(A,r)"
by (unfold well_ord_def tot_ord_def, blast)
lemma pred_iff: "y ∈ pred(A,x,r) ⟷ <y,x>:r & y ∈ A"
by (unfold pred_def, blast)
lemmas predI = conjI [THEN pred_iff [THEN iffD2]]
lemma predE: "[| y ∈ pred(A,x,r); [| y ∈ A; <y,x>:r |] ==> P |] ==> P"
by (simp add: pred_def)
lemma pred_subset_under: "pred(A,x,r) ⊆ r -`` {x}"
by (simp add: pred_def, blast)
lemma pred_subset: "pred(A,x,r) ⊆ A"
by (simp add: pred_def, blast)
lemma pred_pred_eq:
"pred(pred(A,x,r), y, r) = pred(A,x,r) ∩ pred(A,y,r)"
by (simp add: pred_def, blast)
lemma trans_pred_pred_eq:
"[| trans[A](r); <y,x>:r; x ∈ A; y ∈ A |]
==> pred(pred(A,x,r), y, r) = pred(A,y,r)"
by (unfold trans_on_def pred_def, blast)
subsection‹Restricting an Ordering's Domain›
lemma part_ord_subset:
"[| part_ord(A,r); B<=A |] ==> part_ord(B,r)"
by (unfold part_ord_def irrefl_def trans_on_def, blast)
lemma linear_subset:
"[| linear(A,r); B<=A |] ==> linear(B,r)"
by (unfold linear_def, blast)
lemma tot_ord_subset:
"[| tot_ord(A,r); B<=A |] ==> tot_ord(B,r)"
apply (unfold tot_ord_def)
apply (fast elim!: part_ord_subset linear_subset)
done
lemma well_ord_subset:
"[| well_ord(A,r); B<=A |] ==> well_ord(B,r)"
apply (unfold well_ord_def)
apply (fast elim!: tot_ord_subset wf_on_subset_A)
done
lemma irrefl_Int_iff: "irrefl(A,r ∩ A*A) ⟷ irrefl(A,r)"
by (unfold irrefl_def, blast)
lemma trans_on_Int_iff: "trans[A](r ∩ A*A) ⟷ trans[A](r)"
by (unfold trans_on_def, blast)
lemma part_ord_Int_iff: "part_ord(A,r ∩ A*A) ⟷ part_ord(A,r)"
apply (unfold part_ord_def)
apply (simp add: irrefl_Int_iff trans_on_Int_iff)
done
lemma linear_Int_iff: "linear(A,r ∩ A*A) ⟷ linear(A,r)"
by (unfold linear_def, blast)
lemma tot_ord_Int_iff: "tot_ord(A,r ∩ A*A) ⟷ tot_ord(A,r)"
apply (unfold tot_ord_def)
apply (simp add: part_ord_Int_iff linear_Int_iff)
done
lemma wf_on_Int_iff: "wf[A](r ∩ A*A) ⟷ wf[A](r)"
apply (unfold wf_on_def wf_def, fast)
done
lemma well_ord_Int_iff: "well_ord(A,r ∩ A*A) ⟷ well_ord(A,r)"
apply (unfold well_ord_def)
apply (simp add: tot_ord_Int_iff wf_on_Int_iff)
done
subsection‹Empty and Unit Domains›
lemma wf_on_any_0: "wf[A](0)"
by (simp add: wf_on_def wf_def, fast)
subsubsection‹Relations over the Empty Set›
lemma irrefl_0: "irrefl(0,r)"
by (unfold irrefl_def, blast)
lemma trans_on_0: "trans[0](r)"
by (unfold trans_on_def, blast)
lemma part_ord_0: "part_ord(0,r)"
apply (unfold part_ord_def)
apply (simp add: irrefl_0 trans_on_0)
done
lemma linear_0: "linear(0,r)"
by (unfold linear_def, blast)
lemma tot_ord_0: "tot_ord(0,r)"
apply (unfold tot_ord_def)
apply (simp add: part_ord_0 linear_0)
done
lemma wf_on_0: "wf[0](r)"
by (unfold wf_on_def wf_def, blast)
lemma well_ord_0: "well_ord(0,r)"
apply (unfold well_ord_def)
apply (simp add: tot_ord_0 wf_on_0)
done
subsubsection‹The Empty Relation Well-Orders the Unit Set›
text‹by Grabczewski›
lemma tot_ord_unit: "tot_ord({a},0)"
by (simp add: irrefl_def trans_on_def part_ord_def linear_def tot_ord_def)
lemma well_ord_unit: "well_ord({a},0)"
apply (unfold well_ord_def)
apply (simp add: tot_ord_unit wf_on_any_0)
done
subsection‹Order-Isomorphisms›
text‹Suppes calls them "similarities"›
lemma mono_map_is_fun: "f ∈ mono_map(A,r,B,s) ==> f ∈ A->B"
by (simp add: mono_map_def)
lemma mono_map_is_inj:
"[| linear(A,r); wf[B](s); f ∈ mono_map(A,r,B,s) |] ==> f ∈ inj(A,B)"
apply (unfold mono_map_def inj_def, clarify)
apply (erule_tac x=w and y=x in linearE, assumption+)
apply (force intro: apply_type dest: wf_on_not_refl)+
done
lemma ord_isoI:
"[| f ∈ bij(A, B);
!!x y. [| x ∈ A; y ∈ A |] ==> <x, y> ∈ r ⟷ <f`x, f`y> ∈ s |]
==> f ∈ ord_iso(A,r,B,s)"
by (simp add: ord_iso_def)
lemma ord_iso_is_mono_map:
"f ∈ ord_iso(A,r,B,s) ==> f ∈ mono_map(A,r,B,s)"
apply (simp add: ord_iso_def mono_map_def)
apply (blast dest!: bij_is_fun)
done
lemma ord_iso_is_bij:
"f ∈ ord_iso(A,r,B,s) ==> f ∈ bij(A,B)"
by (simp add: ord_iso_def)
lemma ord_iso_apply:
"[| f ∈ ord_iso(A,r,B,s); <x,y>: r; x ∈ A; y ∈ A |] ==> <f`x, f`y> ∈ s"
by (simp add: ord_iso_def)
lemma ord_iso_converse:
"[| f ∈ ord_iso(A,r,B,s); <x,y>: s; x ∈ B; y ∈ B |]
==> <converse(f) ` x, converse(f) ` y> ∈ r"
apply (simp add: ord_iso_def, clarify)
apply (erule bspec [THEN bspec, THEN iffD2])
apply (erule asm_rl bij_converse_bij [THEN bij_is_fun, THEN apply_type])+
apply (auto simp add: right_inverse_bij)
done
lemma ord_iso_refl: "id(A): ord_iso(A,r,A,r)"
by (rule id_bij [THEN ord_isoI], simp)
lemma ord_iso_sym: "f ∈ ord_iso(A,r,B,s) ==> converse(f): ord_iso(B,s,A,r)"
apply (simp add: ord_iso_def)
apply (auto simp add: right_inverse_bij bij_converse_bij
bij_is_fun [THEN apply_funtype])
done
lemma mono_map_trans:
"[| g ∈ mono_map(A,r,B,s); f ∈ mono_map(B,s,C,t) |]
==> (f O g): mono_map(A,r,C,t)"
apply (unfold mono_map_def)
apply (auto simp add: comp_fun)
done
lemma ord_iso_trans:
"[| g ∈ ord_iso(A,r,B,s); f ∈ ord_iso(B,s,C,t) |]
==> (f O g): ord_iso(A,r,C,t)"
apply (unfold ord_iso_def, clarify)
apply (frule bij_is_fun [of f])
apply (frule bij_is_fun [of g])
apply (auto simp add: comp_bij)
done
lemma mono_ord_isoI:
"[| f ∈ mono_map(A,r,B,s); g ∈ mono_map(B,s,A,r);
f O g = id(B); g O f = id(A) |] ==> f ∈ ord_iso(A,r,B,s)"
apply (simp add: ord_iso_def mono_map_def, safe)
apply (intro fg_imp_bijective, auto)
apply (subgoal_tac "<g` (f`x), g` (f`y) > ∈ r")
apply (simp add: comp_eq_id_iff [THEN iffD1])
apply (blast intro: apply_funtype)
done
lemma well_ord_mono_ord_isoI:
"[| well_ord(A,r); well_ord(B,s);
f ∈ mono_map(A,r,B,s); converse(f): mono_map(B,s,A,r) |]
==> f ∈ ord_iso(A,r,B,s)"
apply (intro mono_ord_isoI, auto)
apply (frule mono_map_is_fun [THEN fun_is_rel])
apply (erule converse_converse [THEN subst], rule left_comp_inverse)
apply (blast intro: left_comp_inverse mono_map_is_inj well_ord_is_linear
well_ord_is_wf)+
done
lemma part_ord_ord_iso:
"[| part_ord(B,s); f ∈ ord_iso(A,r,B,s) |] ==> part_ord(A,r)"
apply (simp add: part_ord_def irrefl_def trans_on_def ord_iso_def)
apply (fast intro: bij_is_fun [THEN apply_type])
done
lemma linear_ord_iso:
"[| linear(B,s); f ∈ ord_iso(A,r,B,s) |] ==> linear(A,r)"
apply (simp add: linear_def ord_iso_def, safe)
apply (drule_tac x1 = "f`x" and x = "f`y" in bspec [THEN bspec])
apply (safe elim!: bij_is_fun [THEN apply_type])
apply (drule_tac t = "(`) (converse (f))" in subst_context)
apply (simp add: left_inverse_bij)
done
lemma wf_on_ord_iso:
"[| wf[B](s); f ∈ ord_iso(A,r,B,s) |] ==> wf[A](r)"
apply (simp add: wf_on_def wf_def ord_iso_def, safe)
apply (drule_tac x = "{f`z. z ∈ Z ∩ A}" in spec)
apply (safe intro!: equalityI)
apply (blast dest!: equalityD1 intro: bij_is_fun [THEN apply_type])+
done
lemma well_ord_ord_iso:
"[| well_ord(B,s); f ∈ ord_iso(A,r,B,s) |] ==> well_ord(A,r)"
apply (unfold well_ord_def tot_ord_def)
apply (fast elim!: part_ord_ord_iso linear_ord_iso wf_on_ord_iso)
done
subsection‹Main results of Kunen, Chapter 1 section 6›
lemma well_ord_iso_subset_lemma:
"[| well_ord(A,r); f ∈ ord_iso(A,r, A',r); A'<= A; y ∈ A |]
==> ~ <f`y, y>: r"
apply (simp add: well_ord_def ord_iso_def)
apply (elim conjE CollectE)
apply (rule_tac a=y in wf_on_induct, assumption+)
apply (blast dest: bij_is_fun [THEN apply_type])
done
lemma well_ord_iso_predE:
"[| well_ord(A,r); f ∈ ord_iso(A, r, pred(A,x,r), r); x ∈ A |] ==> P"
apply (insert well_ord_iso_subset_lemma [of A r f "pred(A,x,r)" x])
apply (simp add: pred_subset)
apply (drule ord_iso_is_bij [THEN bij_is_fun, THEN apply_type], assumption)
apply (simp add: well_ord_def pred_def)
done
lemma well_ord_iso_pred_eq:
"[| well_ord(A,r); f ∈ ord_iso(pred(A,a,r), r, pred(A,c,r), r);
a ∈ A; c ∈ A |] ==> a=c"
apply (frule well_ord_is_trans_on)
apply (frule well_ord_is_linear)
apply (erule_tac x=a and y=c in linearE, assumption+)
apply (drule ord_iso_sym)
apply (auto elim!: well_ord_subset [OF _ pred_subset, THEN well_ord_iso_predE]
intro!: predI
simp add: trans_pred_pred_eq)
done
lemma ord_iso_image_pred:
"[|f ∈ ord_iso(A,r,B,s); a ∈ A|] ==> f `` pred(A,a,r) = pred(B, f`a, s)"
apply (unfold ord_iso_def pred_def)
apply (erule CollectE)
apply (simp (no_asm_simp) add: image_fun [OF bij_is_fun Collect_subset])
apply (rule equalityI)
apply (safe elim!: bij_is_fun [THEN apply_type])
apply (rule RepFun_eqI)
apply (blast intro!: right_inverse_bij [symmetric])
apply (auto simp add: right_inverse_bij bij_is_fun [THEN apply_funtype])
done
lemma ord_iso_restrict_image:
"[| f ∈ ord_iso(A,r,B,s); C<=A |]
==> restrict(f,C) ∈ ord_iso(C, r, f``C, s)"
apply (simp add: ord_iso_def)
apply (blast intro: bij_is_inj restrict_bij)
done
lemma ord_iso_restrict_pred:
"[| f ∈ ord_iso(A,r,B,s); a ∈ A |]
==> restrict(f, pred(A,a,r)) ∈ ord_iso(pred(A,a,r), r, pred(B, f`a, s), s)"
apply (simp add: ord_iso_image_pred [symmetric])
apply (blast intro: ord_iso_restrict_image elim: predE)
done
lemma well_ord_iso_preserving:
"[| well_ord(A,r); well_ord(B,s); <a,c>: r;
f ∈ ord_iso(pred(A,a,r), r, pred(B,b,s), s);
g ∈ ord_iso(pred(A,c,r), r, pred(B,d,s), s);
a ∈ A; c ∈ A; b ∈ B; d ∈ B |] ==> <b,d>: s"
apply (frule ord_iso_is_bij [THEN bij_is_fun, THEN apply_type], (erule asm_rl predI predE)+)
apply (subgoal_tac "b = g`a")
apply (simp (no_asm_simp))
apply (rule well_ord_iso_pred_eq, auto)
apply (frule ord_iso_restrict_pred, (erule asm_rl predI)+)
apply (simp add: well_ord_is_trans_on trans_pred_pred_eq)
apply (erule ord_iso_sym [THEN ord_iso_trans], assumption)
done
lemma well_ord_iso_unique_lemma:
"[| well_ord(A,r);
f ∈ ord_iso(A,r, B,s); g ∈ ord_iso(A,r, B,s); y ∈ A |]
==> ~ <g`y, f`y> ∈ s"
apply (frule well_ord_iso_subset_lemma)
apply (rule_tac f = "converse (f) " and g = g in ord_iso_trans)
apply auto
apply (blast intro: ord_iso_sym)
apply (frule ord_iso_is_bij [of f])
apply (frule ord_iso_is_bij [of g])
apply (frule ord_iso_converse)
apply (blast intro!: bij_converse_bij
intro: bij_is_fun apply_funtype)+
apply (erule notE)
apply (simp add: left_inverse_bij bij_is_fun comp_fun_apply [of _ A B])
done
lemma well_ord_iso_unique: "[| well_ord(A,r);
f ∈ ord_iso(A,r, B,s); g ∈ ord_iso(A,r, B,s) |] ==> f = g"
apply (rule fun_extension)
apply (erule ord_iso_is_bij [THEN bij_is_fun])+
apply (subgoal_tac "f`x ∈ B & g`x ∈ B & linear(B,s)")
apply (simp add: linear_def)
apply (blast dest: well_ord_iso_unique_lemma)
apply (blast intro: ord_iso_is_bij bij_is_fun apply_funtype
well_ord_is_linear well_ord_ord_iso ord_iso_sym)
done
subsection‹Towards Kunen's Theorem 6.3: Linearity of the Similarity Relation›
lemma ord_iso_map_subset: "ord_iso_map(A,r,B,s) ⊆ A*B"
by (unfold ord_iso_map_def, blast)
lemma domain_ord_iso_map: "domain(ord_iso_map(A,r,B,s)) ⊆ A"
by (unfold ord_iso_map_def, blast)
lemma range_ord_iso_map: "range(ord_iso_map(A,r,B,s)) ⊆ B"
by (unfold ord_iso_map_def, blast)
lemma converse_ord_iso_map:
"converse(ord_iso_map(A,r,B,s)) = ord_iso_map(B,s,A,r)"
apply (unfold ord_iso_map_def)
apply (blast intro: ord_iso_sym)
done
lemma function_ord_iso_map:
"well_ord(B,s) ==> function(ord_iso_map(A,r,B,s))"
apply (unfold ord_iso_map_def function_def)
apply (blast intro: well_ord_iso_pred_eq ord_iso_sym ord_iso_trans)
done
lemma ord_iso_map_fun: "well_ord(B,s) ==> ord_iso_map(A,r,B,s)
∈ domain(ord_iso_map(A,r,B,s)) -> range(ord_iso_map(A,r,B,s))"
by (simp add: Pi_iff function_ord_iso_map
ord_iso_map_subset [THEN domain_times_range])
lemma ord_iso_map_mono_map:
"[| well_ord(A,r); well_ord(B,s) |]
==> ord_iso_map(A,r,B,s)
∈ mono_map(domain(ord_iso_map(A,r,B,s)), r,
range(ord_iso_map(A,r,B,s)), s)"
apply (unfold mono_map_def)
apply (simp (no_asm_simp) add: ord_iso_map_fun)
apply safe
apply (subgoal_tac "x ∈ A & ya:A & y ∈ B & yb:B")
apply (simp add: apply_equality [OF _ ord_iso_map_fun])
apply (unfold ord_iso_map_def)
apply (blast intro: well_ord_iso_preserving, blast)
done
lemma ord_iso_map_ord_iso:
"[| well_ord(A,r); well_ord(B,s) |] ==> ord_iso_map(A,r,B,s)
∈ ord_iso(domain(ord_iso_map(A,r,B,s)), r,
range(ord_iso_map(A,r,B,s)), s)"
apply (rule well_ord_mono_ord_isoI)
prefer 4
apply (rule converse_ord_iso_map [THEN subst])
apply (simp add: ord_iso_map_mono_map
ord_iso_map_subset [THEN converse_converse])
apply (blast intro!: domain_ord_iso_map range_ord_iso_map
intro: well_ord_subset ord_iso_map_mono_map)+
done
lemma domain_ord_iso_map_subset:
"[| well_ord(A,r); well_ord(B,s);
a ∈ A; a ∉ domain(ord_iso_map(A,r,B,s)) |]
==> domain(ord_iso_map(A,r,B,s)) ⊆ pred(A, a, r)"
apply (unfold ord_iso_map_def)
apply (safe intro!: predI)
apply (simp (no_asm_simp))
apply (frule_tac A = A in well_ord_is_linear)
apply (rename_tac b y f)
apply (erule_tac x=b and y=a in linearE, assumption+)
apply clarify
apply blast
apply (frule ord_iso_is_bij [THEN bij_is_fun, THEN apply_type],
(erule asm_rl predI predE)+)
apply (frule ord_iso_restrict_pred)
apply (simp add: pred_iff)
apply (simp split: split_if_asm
add: well_ord_is_trans_on trans_pred_pred_eq domain_UN domain_Union, blast)
done
lemma domain_ord_iso_map_cases:
"[| well_ord(A,r); well_ord(B,s) |]
==> domain(ord_iso_map(A,r,B,s)) = A |
(∃x∈A. domain(ord_iso_map(A,r,B,s)) = pred(A,x,r))"
apply (frule well_ord_is_wf)
apply (unfold wf_on_def wf_def)
apply (drule_tac x = "A-domain (ord_iso_map (A,r,B,s))" in spec)
apply safe
apply (rule domain_ord_iso_map [THEN equalityI])
apply (erule Diff_eq_0_iff [THEN iffD1])
apply (blast del: domainI subsetI
elim!: predE
intro!: domain_ord_iso_map_subset
intro: subsetI)+
done
lemma range_ord_iso_map_cases:
"[| well_ord(A,r); well_ord(B,s) |]
==> range(ord_iso_map(A,r,B,s)) = B |
(∃y∈B. range(ord_iso_map(A,r,B,s)) = pred(B,y,s))"
apply (rule converse_ord_iso_map [THEN subst])
apply (simp add: domain_ord_iso_map_cases)
done
text‹Kunen's Theorem 6.3: Fundamental Theorem for Well-Ordered Sets›
theorem well_ord_trichotomy:
"[| well_ord(A,r); well_ord(B,s) |]
==> ord_iso_map(A,r,B,s) ∈ ord_iso(A, r, B, s) |
(∃x∈A. ord_iso_map(A,r,B,s) ∈ ord_iso(pred(A,x,r), r, B, s)) |
(∃y∈B. ord_iso_map(A,r,B,s) ∈ ord_iso(A, r, pred(B,y,s), s))"
apply (frule_tac B = B in domain_ord_iso_map_cases, assumption)
apply (frule_tac B = B in range_ord_iso_map_cases, assumption)
apply (drule ord_iso_map_ord_iso, assumption)
apply (elim disjE bexE)
apply (simp_all add: bexI)
apply (rule wf_on_not_refl [THEN notE])
apply (erule well_ord_is_wf)
apply assumption
apply (subgoal_tac "<x,y>: ord_iso_map (A,r,B,s) ")
apply (drule rangeI)
apply (simp add: pred_def)
apply (unfold ord_iso_map_def, blast)
done
subsection‹Miscellaneous Results by Krzysztof Grabczewski›
lemma irrefl_converse: "irrefl(A,r) ==> irrefl(A,converse(r))"
by (unfold irrefl_def, blast)
lemma trans_on_converse: "trans[A](r) ==> trans[A](converse(r))"
by (unfold trans_on_def, blast)
lemma part_ord_converse: "part_ord(A,r) ==> part_ord(A,converse(r))"
apply (unfold part_ord_def)
apply (blast intro!: irrefl_converse trans_on_converse)
done
lemma linear_converse: "linear(A,r) ==> linear(A,converse(r))"
by (unfold linear_def, blast)
lemma tot_ord_converse: "tot_ord(A,r) ==> tot_ord(A,converse(r))"
apply (unfold tot_ord_def)
apply (blast intro!: part_ord_converse linear_converse)
done
lemma first_is_elem: "first(b,B,r) ==> b ∈ B"
by (unfold first_def, blast)
lemma well_ord_imp_ex1_first:
"[| well_ord(A,r); B<=A; B≠0 |] ==> (∃!b. first(b,B,r))"
apply (unfold well_ord_def wf_on_def wf_def first_def)
apply (elim conjE allE disjE, blast)
apply (erule bexE)
apply (rule_tac a = x in ex1I, auto)
apply (unfold tot_ord_def linear_def, blast)
done
lemma the_first_in:
"[| well_ord(A,r); B<=A; B≠0 |] ==> (THE b. first(b,B,r)) ∈ B"
apply (drule well_ord_imp_ex1_first, assumption+)
apply (rule first_is_elem)
apply (erule theI)
done
subsection ‹Lemmas for the Reflexive Orders›
lemma subset_vimage_vimage_iff:
"[| Preorder(r); A ⊆ field(r); B ⊆ field(r) |] ==>
r -`` A ⊆ r -`` B ⟷ (∀a∈A. ∃b∈B. <a, b> ∈ r)"
apply (auto simp: subset_def preorder_on_def refl_def vimage_def image_def)
apply blast
unfolding trans_on_def
apply (erule_tac P = "(λx. ∀y∈field(r).
∀z∈field(r). ⟨x, y⟩ ∈ r ⟶ ⟨y, z⟩ ∈ r ⟶ ⟨x, z⟩ ∈ r)" for r in rev_ballE)
apply best
apply blast
done
lemma subset_vimage1_vimage1_iff:
"[| Preorder(r); a ∈ field(r); b ∈ field(r) |] ==>
r -`` {a} ⊆ r -`` {b} ⟷ <a, b> ∈ r"
by (simp add: subset_vimage_vimage_iff)
lemma Refl_antisym_eq_Image1_Image1_iff:
"[| refl(field(r), r); antisym(r); a ∈ field(r); b ∈ field(r) |] ==>
r `` {a} = r `` {b} ⟷ a = b"
apply rule
apply (frule equality_iffD)
apply (drule equality_iffD)
apply (simp add: antisym_def refl_def)
apply best
apply (simp add: antisym_def refl_def)
done
lemma Partial_order_eq_Image1_Image1_iff:
"[| Partial_order(r); a ∈ field(r); b ∈ field(r) |] ==>
r `` {a} = r `` {b} ⟷ a = b"
by (simp add: partial_order_on_def preorder_on_def
Refl_antisym_eq_Image1_Image1_iff)
lemma Refl_antisym_eq_vimage1_vimage1_iff:
"[| refl(field(r), r); antisym(r); a ∈ field(r); b ∈ field(r) |] ==>
r -`` {a} = r -`` {b} ⟷ a = b"
apply rule
apply (frule equality_iffD)
apply (drule equality_iffD)
apply (simp add: antisym_def refl_def)
apply best
apply (simp add: antisym_def refl_def)
done
lemma Partial_order_eq_vimage1_vimage1_iff:
"[| Partial_order(r); a ∈ field(r); b ∈ field(r) |] ==>
r -`` {a} = r -`` {b} ⟷ a = b"
by (simp add: partial_order_on_def preorder_on_def
Refl_antisym_eq_vimage1_vimage1_iff)
end