theory Set_F_cms
imports Set_F RS
begin
declare Union_image_eq [simp del]
declare Inter_image_eq [simp del]
instance setF :: (type) ms0
by (intro_classes)
consts
restF :: "'a setF => nat => 'a failure set" ("_ restF _" [84,900] 84)
LimitF :: "'a setF infinite_seq => 'a failure set"
Limit_setF :: "'a setF infinite_seq => 'a setF"
defs
restF_def :
"F restF n == {(s, X) |s X. (s, X) :f F &
(lengtht s < n |
lengtht s = n & (EX s'. s = s' ^^^ <Tick> & noTick s'))}"
LimitF_def :
"LimitF Fs == {(s, X) |s X.
((s, X) :f Fs (Suc (lengtht s)) |
(s, X) :f Fs (lengtht s) & (EX s'. s = s' ^^^ <Tick> & noTick s'))}"
Limit_setF_def :
"Limit_setF Fs == Abs_setF (LimitF Fs)"
defs (overloaded)
rest_setF_def : "F .|. n == Abs_setF (F restF n)"
lemma restF_in[simp] : "F restF n : setF"
apply (simp add: restF_def)
apply (simp add: setF_def HC_F2_def)
apply (intro allI impI)
apply (elim conjE)
apply (rule memF_F2)
by (simp_all)
lemma rest_setF_iff: "F .|. n =
{f. EX s X. f = (s, X) & (s, X) :f F &
(lengtht s < n |
lengtht s = n & (EX s'. s = s' ^^^ <Tick> & noTick s'))}f"
apply (simp add: rest_setF_def)
apply (subgoal_tac
"{(s, X).
(s, X) :f F &
(lengtht s < n |
lengtht s = n & (EX s'. s = s' ^^^ <Tick> & noTick s'))} : setF")
apply (simp add: Abs_setF_inject)
apply (simp add: restF_def)
apply (insert restF_in[simplified restF_def])
apply (auto)
done
lemma in_rest_setF: "(s, X) :f F .|. n =
((s, X) :f F &
(lengtht s < n |
lengtht s = n & (EX s'. s = s' ^^^ <Tick> & noTick s')))"
apply (simp add: memF_def rest_setF_def)
apply (simp add: Abs_setF_inverse)
apply (simp add: memF_def restF_def)
done
lemma rest_setF_eq_iff:
"(F .|. n = E .|. m) =
(ALL s X.
((s, X) :f F &
(lengtht s < n |
lengtht s = n & (EX s'. s = s' ^^^ <Tick> & noTick s')))
= ((s, X) :f E &
(lengtht s < m |
lengtht s = m & (EX s'. s = s' ^^^ <Tick> & noTick s'))))"
apply (simp add: rest_setF_def Abs_setF_inject)
apply (simp add: restF_def)
by (auto)
lemma rest_setF_eq:
"[| (s, X) :f F ; F restF Suc (lengtht s) =
E restF Suc (lengtht s) |]
==> (s, X) :f E"
by (auto simp add: restF_def)
lemma contra_zero_setF: "(F::'a setF) restF n ~= {} ==> 0 < n"
apply (simp add: restF_def)
apply (elim conjE exE)
apply (erule disjE)
apply (simp)
apply (elim conjE exE)
by (simp)
lemma zero_setF: "(F::'a setF) restF 0 = {}"
apply (insert contra_zero_setF[of F 0])
apply (case_tac "F restF 0 = {}")
by (simp_all)
lemma zero_rs_setF: "(F::'a setF) .|. 0 = {}f"
apply (simp add: rest_setF_def empF_def Abs_setF_inject)
apply (simp add: zero_setF)
done
lemma zero_eq_rs_setF: "(F::'a setF) .|. 0 = E .|. 0"
by (simp add: zero_rs_setF)
lemma min_rs_setF:
"((F::'a setF) .|. m) .|. n = F .|. (min m n)"
apply (simp add: rest_setF_eq_iff)
apply (simp add: in_rest_setF)
apply (intro allI)
apply (rule iffI)
apply (elim conjE exE disjE)
apply (simp_all add: min_is)
apply (rule_tac x="s'" in exI, simp)+
apply (elim conjE exE disjE)
apply (simp_all)
apply (case_tac "m < n")
apply (simp add: min_is)
apply (rule_tac x="s'" in exI, simp)
apply (case_tac "m = n")
apply (simp add: min_is)
apply (rule_tac x="s'" in exI, simp)
apply (case_tac "n < m")
apply (simp add: min_is)
apply (rule_tac x="s'" in exI, simp)
by (force)
lemma contra_diff_rs_setF_left:
"(ALL n. (F::'a setF) .|. n = E .|. n) ==> F <= E"
apply (simp add: rest_setF_eq_iff)
apply (rule subsetFI)
apply (drule_tac x="Suc (lengtht s)" in spec)
apply (drule_tac x="s" in spec)
apply (drule_tac x="X" in spec)
by (simp)
lemma contra_diff_rs_setF:
"(ALL n. (F::'a setF) .|. n = E .|. n) ==> F = E"
apply (rule order_antisym)
by (simp_all add: contra_diff_rs_setF_left)
lemma diff_rs_setF:
"(F::'a setF) ~= E ==> (EX (n::nat). F .|. n ~= E .|. n)"
apply (erule contrapos_np)
apply (rule contra_diff_rs_setF)
by (simp)
instance setF :: (type) rs
apply (intro_classes)
apply (simp add: zero_eq_rs_setF)
apply (simp add: min_rs_setF)
apply (simp add: diff_rs_setF)
done
instance setF :: (type) ms
apply (intro_classes)
apply (simp)
apply (simp add: diagonal_rs)
apply (simp add: symmetry_rs)
apply (simp add: triangle_inequality_rs)
done
instance setF :: (type) ms_rs
by (intro_classes)
lemma normal_seq_setF_less:
"[| normal (Fs::'a setF infinite_seq) ; lengtht s < n |]
==> ((s,X) :f Fs (Suc (lengtht s))) = ((s,X) :f Fs n)"
apply (simp add: normal_def)
apply (drule_tac x="Suc (lengtht s)" in spec)
apply (drule_tac x="n" in spec)
apply (simp add: distance_rs_le_1[THEN sym])
apply (simp add: min_is)
apply (simp add: rest_setF_eq_iff)
apply (drule_tac x="s" in spec)
apply (drule_tac x="X" in spec)
by (simp)
lemma normal_seq_setF_less_only_if:
"[| normal (Fs::'a setF infinite_seq) ; lengtht s < n ;
(s,X) :f Fs (Suc (lengtht s)) |]
==> ((s,X) :f Fs n)"
by (simp add: normal_seq_setF_less)
lemma normal_seq_setF_Tick:
"[| normal (Fs::'a setF infinite_seq) ; lengtht (s' ^^^ <Tick>) <= n ;
noTick s' |]
==> ((s' ^^^ <Tick>,X) :f Fs (lengtht (s' ^^^ <Tick>))) =
((s' ^^^ <Tick>,X) :f Fs n)"
apply (simp add: normal_def)
apply (drule_tac x="lengtht (s' ^^^ <Tick>)" in spec)
apply (drule_tac x="n" in spec)
apply (simp add: distance_rs_le_1[THEN sym])
apply (simp add: min_is)
apply (simp add: rest_setF_eq_iff)
apply (drule_tac x="s' ^^^ <Tick>" in spec)
apply (drule_tac x="X" in spec)
apply (simp)
apply (rule)
apply (erule iffE)
apply (drule mp)
apply (rule conjI)
apply (simp)
apply (simp)
apply (rule_tac x="s'" in exI)
apply (simp)
apply (simp)
apply (erule iffE)
apply (rotate_tac -1)
apply (drule mp)
apply (rule conjI)
apply (simp)
apply (simp)
apply (rule_tac x="s'" in exI)
apply (simp)
apply (simp)
done
lemma normal_seq_setF_Tick_only_if:
"[| normal (Fs::'a setF infinite_seq) ; lengtht (s' ^^^ <Tick>) <= n ;
(s' ^^^ <Tick>,X) :f Fs (lengtht (s' ^^^ <Tick>)) ; noTick s' |]
==> ((s' ^^^ <Tick>,X) :f Fs n)"
by (simp only: normal_seq_setF_Tick)
lemma normal_seq_setF_Tick_only_ifE:
"[| (s' ^^^ <Tick>,X) :f Fs n ;
normal (Fs::'a setF infinite_seq) ; lengtht (s' ^^^ <Tick>) <= n ; noTick s' ;
(s' ^^^ <Tick>,X) :f Fs (lengtht (s' ^^^ <Tick>)) ==> R |]
==> R"
by (simp only: normal_seq_setF_Tick)
lemma LimitF_in[simp]:
"LimitF (Fs::'a setF infinite_seq) : setF"
apply (simp add: LimitF_def)
apply (simp add: setF_def HC_F2_def)
apply (intro allI impI)
apply (erule conjE)
apply (erule disjE)
apply (rule disjI1)
apply (rule memF_F2)
apply (simp_all)
apply (elim conjE exE)
apply (rule disjI2)
apply (rule memF_F2)
apply (simp_all)
done
lemma Limit_setF_memF:
"((s, X) :f Limit_setF Fs) =
((s, X) :f Fs (Suc (lengtht s)) |
(s, X) :f Fs (lengtht s) & (EX s'. s = s' ^^^ <Tick> & noTick s'))"
apply (simp add: Limit_setF_def memF_def)
apply (simp add: Abs_setF_inverse)
apply (simp add: LimitF_def memF_def)
done
lemma Limit_setF_Limit_lm:
"normal (Fs::'a setF infinite_seq)
==> (ALL n. (Limit_setF Fs) .|. n = (Fs n) .|. n)"
apply (simp add: rest_setF_eq_iff)
apply (intro allI)
apply (simp add: Limit_setF_memF)
apply (rule iffI)
apply (elim conjE disjE)
apply (simp_all add: normal_seq_setF_less)
apply (elim conjE exE)
apply (simp)
apply (erule normal_seq_setF_Tick_only_ifE)
apply (simp_all)
apply (elim conjE exE)
apply (simp)
apply (rule normal_seq_setF_Tick_only_if)
apply (simp_all)
apply (elim conjE disjE)
apply (simp add: normal_seq_setF_less)
apply (simp)
done
lemma Limit_setF_Limit:
"normal (Fs::'a setF infinite_seq) ==> Fs convergeTo (Limit_setF Fs)"
by (simp add: Limit_setF_Limit_lm rest_Limit)
lemma cauchy_Limit_setF_Limit:
"cauchy (Fs::'a setF infinite_seq) ==> Fs convergeTo (Limit_setF (NF Fs))"
apply (simp add: normal_form_seq_same_Limit)
apply (simp add: Limit_setF_Limit normal_form_seq_normal)
done
lemma setF_cms:
"cauchy (Fs::'a setF infinite_seq) ==> (EX F. Fs convergeTo F)"
apply (rule_tac x="Limit_setF (NF Fs)" in exI)
by (simp add: cauchy_Limit_setF_Limit)
instance setF :: (type) cms
apply (intro_classes)
by (simp add: setF_cms)
instance setF :: (type) cms_rs
by (intro_classes)
lemma Limit_setF_Limit_eq:
"normal (Fs::'a setF infinite_seq) ==> Limit Fs = Limit_setF Fs"
apply (insert unique_convergence[of Fs "Limit Fs" "Limit_setF Fs"])
by (simp add: Limit_setF_Limit Limit_is normal_cauchy)
instance setF :: (type) rs_order0
apply (intro_classes)
done
instance setF :: (type) rs_order
apply (intro_classes)
apply (intro allI)
apply (rule iffI)
apply (simp add: rest_setF_def)
apply (simp add: subsetF_def)
apply (simp add: Abs_setF_inverse)
apply (fold subsetF_def)
apply (rule)
apply (drule_tac x="Suc (lengtht s)" in spec)
apply (simp add: restF_def)
apply (erule subsetE)
apply (simp)
apply (intro allI)
apply (simp add: rest_setF_def)
apply (simp add: subsetF_def)
apply (simp add: Abs_setF_inverse)
apply (fold subsetF_def)
apply (rule)
apply (simp add: restF_def)
apply (force)
done
instance setF :: (type) ms_rs_order
by (intro_classes)
instance setF :: (type) cms_rs_order
by (intro_classes)
declare Union_image_eq [simp]
declare Inter_image_eq [simp]
end