Theory HOL-Cardinals.Cardinal_Order_Relation
section ‹Cardinal-Order Relations›
theory Cardinal_Order_Relation
imports Wellorder_Constructions
begin
declare
card_order_on_well_order_on[simp]
card_of_card_order_on[simp]
card_of_well_order_on[simp]
Field_card_of[simp]
card_of_Card_order[simp]
card_of_Well_order[simp]
card_of_least[simp]
card_of_unique[simp]
card_of_mono1[simp]
card_of_mono2[simp]
card_of_cong[simp]
card_of_Field_ordIso[simp]
card_of_underS[simp]
ordLess_Field[simp]
card_of_empty[simp]
card_of_empty1[simp]
card_of_image[simp]
card_of_singl_ordLeq[simp]
Card_order_singl_ordLeq[simp]
card_of_Pow[simp]
Card_order_Pow[simp]
card_of_Plus1[simp]
Card_order_Plus1[simp]
card_of_Plus2[simp]
Card_order_Plus2[simp]
card_of_Plus_mono1[simp]
card_of_Plus_mono2[simp]
card_of_Plus_mono[simp]
card_of_Plus_cong2[simp]
card_of_Plus_cong[simp]
card_of_Un_Plus_ordLeq[simp]
card_of_Times1[simp]
card_of_Times2[simp]
card_of_Times3[simp]
card_of_Times_mono1[simp]
card_of_Times_mono2[simp]
card_of_ordIso_finite[simp]
card_of_Times_same_infinite[simp]
card_of_Times_infinite_simps[simp]
card_of_Plus_infinite1[simp]
card_of_Plus_infinite2[simp]
card_of_Plus_ordLess_infinite[simp]
card_of_Plus_ordLess_infinite_Field[simp]
infinite_cartesian_product[simp]
cardSuc_Card_order[simp]
cardSuc_greater[simp]
cardSuc_ordLeq[simp]
cardSuc_ordLeq_ordLess[simp]
cardSuc_mono_ordLeq[simp]
cardSuc_invar_ordIso[simp]
card_of_cardSuc_finite[simp]
cardSuc_finite[simp]
card_of_Plus_ordLeq_infinite_Field[simp]
curr_in[intro, simp]
subsection ‹Cardinal of a set›
lemma card_of_inj_rel: assumes INJ: "⋀x y y'. ⟦(x,y) ∈ R; (x,y') ∈ R⟧ ⟹ y = y'"
shows "|{y. ∃x. (x,y) ∈ R}| <=o |{x. ∃y. (x,y) ∈ R}|"
proof-
let ?Y = "{y. ∃x. (x,y) ∈ R}" let ?X = "{x. ∃y. (x,y) ∈ R}"
let ?f = "λy. SOME x. (x,y) ∈ R"
have "?f ` ?Y <= ?X" by (auto dest: someI)
moreover have "inj_on ?f ?Y"
by (metis (mono_tags, lifting) assms inj_onI mem_Collect_eq)
ultimately show "|?Y| <=o |?X|" using card_of_ordLeq by blast
qed
lemma card_of_unique2: "⟦card_order_on B r; bij_betw f A B⟧ ⟹ r =o |A|"
using card_of_ordIso card_of_unique ordIso_equivalence by blast
lemma internalize_card_of_ordLess2:
"( |A| <o |C| ) = (∃B < C. |A| =o |B| ∧ |B| <o |C| )"
using internalize_card_of_ordLess[of "A" "|C|"] Field_card_of[of C] by auto
lemma Card_order_omax:
assumes "finite R" and "R ≠ {}" and "∀r∈R. Card_order r"
shows "Card_order (omax R)"
by (simp add: assms omax_in)
lemma Card_order_omax2:
assumes "finite I" and "I ≠ {}"
shows "Card_order (omax {|A i| | i. i ∈ I})"
proof-
let ?R = "{|A i| | i. i ∈ I}"
have "finite ?R" and "?R ≠ {}" using assms by auto
moreover have "∀r∈?R. Card_order r"
using card_of_Card_order by auto
ultimately show ?thesis by(rule Card_order_omax)
qed
subsection ‹Cardinals versus set operations on arbitrary sets›
lemma card_of_set_type[simp]: "|UNIV::'a set| <o |UNIV::'a set set|"
using card_of_Pow[of "UNIV::'a set"] by simp
lemma card_of_Un1[simp]: "|A| ≤o |A ∪ B| "
by fastforce
lemma card_of_diff[simp]: "|A - B| ≤o |A|"
by fastforce
lemma subset_ordLeq_strict:
assumes "A ≤ B" and "|A| <o |B|"
shows "A < B"
using assms ordLess_irreflexive by blast
corollary subset_ordLeq_diff:
assumes "A ≤ B" and "|A| <o |B|"
shows "B - A ≠ {}"
using assms subset_ordLeq_strict by blast
lemma card_of_empty4:
"|{}::'b set| <o |A::'a set| = (A ≠ {})"
by (metis card_of_empty card_of_ordLess2 image_is_empty not_ordLess_ordLeq)
lemma card_of_empty5:
"|A| <o |B| ⟹ B ≠ {}"
using card_of_empty not_ordLess_ordLeq by blast
lemma Well_order_card_of_empty:
"Well_order r ⟹ |{}| ≤o r"
by simp
lemma card_of_UNIV[simp]:
"|A :: 'a set| ≤o |UNIV :: 'a set|"
by simp
lemma card_of_UNIV2[simp]:
"Card_order r ⟹ (r :: 'a rel) ≤o |UNIV :: 'a set|"
using card_of_UNIV[of "Field r"] card_of_Field_ordIso
ordIso_symmetric ordIso_ordLeq_trans by blast
lemma card_of_Pow_mono[simp]:
assumes "|A| ≤o |B|"
shows "|Pow A| ≤o |Pow B|"
proof-
obtain f where "inj_on f A ∧ f ` A ≤ B"
using assms card_of_ordLeq[of A B] by auto
hence "inj_on (image f) (Pow A) ∧ (image f) ` (Pow A) ≤ (Pow B)"
by (auto simp: inj_on_image_Pow image_Pow_mono)
thus ?thesis using card_of_ordLeq[of "Pow A"] by metis
qed
lemma ordIso_Pow_mono[simp]:
assumes "r ≤o r'"
shows "|Pow(Field r)| ≤o |Pow(Field r')|"
using assms card_of_mono2 card_of_Pow_mono by blast
lemma card_of_Pow_cong[simp]:
assumes "|A| =o |B|"
shows "|Pow A| =o |Pow B|"
by (meson assms card_of_Pow_mono ordIso_iff_ordLeq)
lemma ordIso_Pow_cong[simp]:
assumes "r =o r'"
shows "|Pow(Field r)| =o |Pow(Field r')|"
using assms card_of_cong card_of_Pow_cong by blast
corollary Card_order_Plus_empty1:
"Card_order r ⟹ r =o |(Field r) <+> {}|"
using card_of_Plus_empty1 card_of_Field_ordIso ordIso_equivalence by blast
corollary Card_order_Plus_empty2:
"Card_order r ⟹ r =o |{} <+> (Field r)|"
using card_of_Plus_empty2 card_of_Field_ordIso ordIso_equivalence by blast
lemma card_of_Un2[simp]:
shows "|A| ≤o |B ∪ A|"
by fastforce
lemma Un_Plus_bij_betw:
assumes "A Int B = {}"
shows "∃f. bij_betw f (A ∪ B) (A <+> B)"
proof-
have "bij_betw (λ c. if c ∈ A then Inl c else Inr c) (A ∪ B) (A <+> B)"
using assms unfolding bij_betw_def inj_on_def by auto
thus ?thesis by blast
qed
lemma card_of_Un_Plus_ordIso:
assumes "A Int B = {}"
shows "|A ∪ B| =o |A <+> B|"
by (meson Un_Plus_bij_betw assms card_of_ordIso)
lemma card_of_Un_Plus_ordIso1:
"|A ∪ B| =o |A <+> (B - A)|"
using card_of_Un_Plus_ordIso[of A "B - A"] by auto
lemma card_of_Un_Plus_ordIso2:
"|A ∪ B| =o |(A - B) <+> B|"
using card_of_Un_Plus_ordIso[of "A - B" B] by auto
lemma card_of_Times_singl1: "|A| =o |A × {b}|"
proof-
have "bij_betw fst (A × {b}) A" unfolding bij_betw_def inj_on_def by force
thus ?thesis using card_of_ordIso ordIso_symmetric by blast
qed
corollary Card_order_Times_singl1:
"Card_order r ⟹ r =o |(Field r) × {b}|"
using card_of_Times_singl1[of _ b] card_of_Field_ordIso ordIso_equivalence by blast
lemma card_of_Times_singl2: "|A| =o |{b} × A|"
proof-
have "bij_betw snd ({b} × A) A"
unfolding bij_betw_def inj_on_def by force
thus ?thesis using card_of_ordIso ordIso_symmetric by blast
qed
corollary Card_order_Times_singl2:
"Card_order r ⟹ r =o |{a} × (Field r)|"
using card_of_Times_singl2[of _ a] card_of_Field_ordIso ordIso_equivalence by blast
lemma card_of_Times_assoc: "|(A × B) × C| =o |A × B × C|"
proof -
let ?f = "λ((a,b),c). (a,(b,c))"
have "A × B × C ⊆ ?f ` ((A × B) × C)"
proof
fix x assume "x ∈ A × B × C"
then obtain a b c where *: "a ∈ A" "b ∈ B" "c ∈ C" "x = (a, b, c)" by blast
let ?x = "((a, b), c)"
from * have "?x ∈ (A × B) × C" "x = ?f ?x" by auto
thus "x ∈ ?f ` ((A × B) × C)" by blast
qed
hence "bij_betw ?f ((A × B) × C) (A × B × C)"
unfolding bij_betw_def inj_on_def by auto
thus ?thesis using card_of_ordIso by blast
qed
lemma card_of_Times_cong1[simp]:
assumes "|A| =o |B|"
shows "|A × C| =o |B × C|"
using assms by (simp add: ordIso_iff_ordLeq)
lemma card_of_Times_cong2[simp]:
assumes "|A| =o |B|"
shows "|C × A| =o |C × B|"
using assms by (simp add: ordIso_iff_ordLeq)
lemma card_of_Times_mono[simp]:
assumes "|A| ≤o |B|" and "|C| ≤o |D|"
shows "|A × C| ≤o |B × D|"
using assms card_of_Times_mono1[of A B C] card_of_Times_mono2[of C D B]
ordLeq_transitive[of "|A × C|"] by blast
corollary ordLeq_Times_mono:
assumes "r ≤o r'" and "p ≤o p'"
shows "|(Field r) × (Field p)| ≤o |(Field r') × (Field p')|"
using assms card_of_mono2[of r r'] card_of_mono2[of p p'] card_of_Times_mono by blast
corollary ordIso_Times_cong1[simp]:
assumes "r =o r'"
shows "|(Field r) × C| =o |(Field r') × C|"
using assms card_of_cong card_of_Times_cong1 by blast
corollary ordIso_Times_cong2:
assumes "r =o r'"
shows "|A × (Field r)| =o |A × (Field r')|"
using assms card_of_cong card_of_Times_cong2 by blast
lemma card_of_Times_cong[simp]:
assumes "|A| =o |B|" and "|C| =o |D|"
shows "|A × C| =o |B × D|"
using assms
by (auto simp: ordIso_iff_ordLeq)
corollary ordIso_Times_cong:
assumes "r =o r'" and "p =o p'"
shows "|(Field r) × (Field p)| =o |(Field r') × (Field p')|"
using assms card_of_cong[of r r'] card_of_cong[of p p'] card_of_Times_cong by blast
lemma card_of_Sigma_mono2:
assumes "inj_on f (I::'i set)" and "f ` I ≤ (J::'j set)"
shows "|SIGMA i : I. (A::'j ⇒ 'a set) (f i)| ≤o |SIGMA j : J. A j|"
proof-
let ?LEFT = "SIGMA i : I. A (f i)"
let ?RIGHT = "SIGMA j : J. A j"
obtain u where u_def: "u = (λ(i::'i,a::'a). (f i,a))" by blast
have "inj_on u ?LEFT ∧ u `?LEFT ≤ ?RIGHT"
using assms unfolding u_def inj_on_def by auto
thus ?thesis using card_of_ordLeq by blast
qed
lemma card_of_Sigma_mono:
assumes INJ: "inj_on f I" and IM: "f ` I ≤ J" and
LEQ: "∀j ∈ J. |A j| ≤o |B j|"
shows "|SIGMA i : I. A (f i)| ≤o |SIGMA j : J. B j|"
proof-
have "∀i ∈ I. |A(f i)| ≤o |B(f i)|"
using IM LEQ by blast
hence "|SIGMA i : I. A (f i)| ≤o |SIGMA i : I. B (f i)|"
using card_of_Sigma_mono1[of I] by metis
moreover have "|SIGMA i : I. B (f i)| ≤o |SIGMA j : J. B j|"
using INJ IM card_of_Sigma_mono2 by blast
ultimately show ?thesis using ordLeq_transitive by blast
qed
lemma ordLeq_Sigma_mono1:
assumes "∀i ∈ I. p i ≤o r i"
shows "|SIGMA i : I. Field(p i)| ≤o |SIGMA i : I. Field(r i)|"
using assms by (auto simp: card_of_Sigma_mono1)
lemma ordLeq_Sigma_mono:
assumes "inj_on f I" and "f ` I ≤ J" and
"∀j ∈ J. p j ≤o r j"
shows "|SIGMA i : I. Field(p(f i))| ≤o |SIGMA j : J. Field(r j)|"
using assms card_of_mono2 card_of_Sigma_mono [of f I J "λ i. Field(p i)"] by metis
lemma ordIso_Sigma_cong1:
assumes "∀i ∈ I. p i =o r i"
shows "|SIGMA i : I. Field(p i)| =o |SIGMA i : I. Field(r i)|"
using assms by (auto simp: card_of_Sigma_cong1)
lemma ordLeq_Sigma_cong:
assumes "bij_betw f I J" and
"∀j ∈ J. p j =o r j"
shows "|SIGMA i : I. Field(p(f i))| =o |SIGMA j : J. Field(r j)|"
using assms card_of_cong card_of_Sigma_cong
[of f I J "λ j. Field(p j)" "λ j. Field(r j)"] by blast
lemma card_of_UNION_Sigma2:
assumes "⋀i j. ⟦{i,j} <= I; i ≠ j⟧ ⟹ A i Int A j = {}"
shows "|⋃i∈I. A i| =o |Sigma I A|"
proof-
let ?L = "⋃i∈I. A i" let ?R = "Sigma I A"
have "|?L| <=o |?R|" using card_of_UNION_Sigma .
moreover have "|?R| <=o |?L|"
proof-
have "inj_on snd ?R"
unfolding inj_on_def using assms by auto
moreover have "snd ` ?R <= ?L" by auto
ultimately show ?thesis using card_of_ordLeq by blast
qed
ultimately show ?thesis by(simp add: ordIso_iff_ordLeq)
qed
corollary Plus_into_Times:
assumes A2: "a1 ≠ a2 ∧ {a1,a2} ≤ A" and B2: "b1 ≠ b2 ∧ {b1,b2} ≤ B"
shows "∃f. inj_on f (A <+> B) ∧ f ` (A <+> B) ≤ A × B"
using assms by (auto simp: card_of_Plus_Times card_of_ordLeq)
corollary Plus_into_Times_types:
assumes A2: "(a1::'a) ≠ a2" and B2: "(b1::'b) ≠ b2"
shows "∃(f::'a + 'b ⇒ 'a * 'b). inj f"
using assms Plus_into_Times[of a1 a2 UNIV b1 b2 UNIV]
by auto
corollary Times_same_infinite_bij_betw:
assumes "¬finite A"
shows "∃f. bij_betw f (A × A) A"
using assms by (auto simp: card_of_ordIso)
corollary Times_same_infinite_bij_betw_types:
assumes INF: "¬finite(UNIV::'a set)"
shows "∃(f::('a * 'a) => 'a). bij f"
using assms Times_same_infinite_bij_betw[of "UNIV::'a set"]
by auto
corollary Times_infinite_bij_betw:
assumes INF: "¬finite A" and NE: "B ≠ {}" and INJ: "inj_on g B ∧ g ` B ≤ A"
shows "(∃f. bij_betw f (A × B) A) ∧ (∃h. bij_betw h (B × A) A)"
proof-
have "|B| ≤o |A|" using INJ card_of_ordLeq by blast
thus ?thesis using INF NE
by (auto simp: card_of_ordIso card_of_Times_infinite)
qed
corollary Times_infinite_bij_betw_types:
assumes "¬finite(UNIV::'a set)" and "inj(g::'b ⇒ 'a)"
shows "(∃(f::('b * 'a) => 'a). bij f) ∧ (∃(h::('a * 'b) => 'a). bij h)"
using assms Times_infinite_bij_betw[of "UNIV::'a set" "UNIV::'b set" g]
by auto
lemma card_of_Times_ordLeq_infinite:
"⟦¬finite C; |A| ≤o |C|; |B| ≤o |C|⟧ ⟹ |A × B| ≤o |C|"
by(simp add: card_of_Sigma_ordLeq_infinite)
corollary Plus_infinite_bij_betw:
assumes INF: "¬finite A" and INJ: "inj_on g B ∧ g ` B ≤ A"
shows "(∃f. bij_betw f (A <+> B) A) ∧ (∃h. bij_betw h (B <+> A) A)"
proof-
have "|B| ≤o |A|" using INJ card_of_ordLeq by blast
thus ?thesis using INF
by (auto simp: card_of_ordIso)
qed
corollary Plus_infinite_bij_betw_types:
assumes "¬finite(UNIV::'a set)" and "inj(g::'b ⇒ 'a)"
shows "(∃(f::('b + 'a) => 'a). bij f) ∧ (∃(h::('a + 'b) => 'a). bij h)"
using assms Plus_infinite_bij_betw[of "UNIV::'a set" g "UNIV::'b set"]
by auto
lemma card_of_Un_infinite:
assumes INF: "¬finite A" and LEQ: "|B| ≤o |A|"
shows "|A ∪ B| =o |A| ∧ |B ∪ A| =o |A|"
by (simp add: INF LEQ card_of_Un_ordLeq_infinite_Field ordIso_iff_ordLeq)
lemma card_of_Un_infinite_simps[simp]:
"⟦¬finite A; |B| ≤o |A| ⟧ ⟹ |A ∪ B| =o |A|"
"⟦¬finite A; |B| ≤o |A| ⟧ ⟹ |B ∪ A| =o |A|"
using card_of_Un_infinite by auto
lemma card_of_Un_diff_infinite:
assumes INF: "¬finite A" and LESS: "|B| <o |A|"
shows "|A - B| =o |A|"
proof-
obtain C where C_def: "C = A - B" by blast
have "|A ∪ B| =o |A|"
using assms ordLeq_iff_ordLess_or_ordIso card_of_Un_infinite by blast
moreover have "C ∪ B = A ∪ B" unfolding C_def by auto
ultimately have 1: "|C ∪ B| =o |A|" by auto
{assume *: "|C| ≤o |B|"
moreover
{assume **: "finite B"
hence "finite C"
using card_of_ordLeq_finite * by blast
hence False using ** INF card_of_ordIso_finite 1 by blast
}
hence "¬finite B" by auto
ultimately have False
using card_of_Un_infinite 1 ordIso_equivalence(1,3) LESS not_ordLess_ordIso by metis
}
hence 2: "|B| ≤o |C|" using card_of_Well_order ordLeq_total by blast
{assume *: "finite C"
hence "finite B" using card_of_ordLeq_finite 2 by blast
hence False using * INF card_of_ordIso_finite 1 by blast
}
hence "¬finite C" by auto
hence "|C| =o |A|"
using card_of_Un_infinite 1 2 ordIso_equivalence(1,3) by metis
thus ?thesis unfolding C_def .
qed
corollary Card_order_Un_infinite:
assumes INF: "¬finite(Field r)" and CARD: "Card_order r" and
LEQ: "p ≤o r"
shows "| (Field r) ∪ (Field p) | =o r ∧ | (Field p) ∪ (Field r) | =o r"
proof-
have "| Field r ∪ Field p | =o | Field r | ∧
| Field p ∪ Field r | =o | Field r |"
using assms by (auto simp: card_of_Un_infinite)
thus ?thesis
using assms card_of_Field_ordIso[of r]
ordIso_transitive[of "|Field r ∪ Field p|"]
ordIso_transitive[of _ "|Field r|"] by blast
qed
corollary subset_ordLeq_diff_infinite:
assumes INF: "¬finite B" and SUB: "A ≤ B" and LESS: "|A| <o |B|"
shows "¬finite (B - A)"
using assms card_of_Un_diff_infinite card_of_ordIso_finite by blast
lemma card_of_Times_ordLess_infinite[simp]:
assumes INF: "¬finite C" and
LESS1: "|A| <o |C|" and LESS2: "|B| <o |C|"
shows "|A × B| <o |C|"
proof(cases "A = {} ∨ B = {}")
assume Case1: "A = {} ∨ B = {}"
hence "A × B = {}" by blast
moreover have "C ≠ {}" using
LESS1 card_of_empty5 by blast
ultimately show ?thesis by(auto simp: card_of_empty4)
next
assume Case2: "¬(A = {} ∨ B = {})"
{assume *: "|C| ≤o |A × B|"
hence "¬finite (A × B)" using INF card_of_ordLeq_finite by blast
hence 1: "¬finite A ∨ ¬finite B" using finite_cartesian_product by blast
{assume Case21: "|A| ≤o |B|"
hence "¬finite B" using 1 card_of_ordLeq_finite by blast
hence "|A × B| =o |B|" using Case2 Case21
by (auto simp: card_of_Times_infinite)
hence False using LESS2 not_ordLess_ordLeq * ordLeq_ordIso_trans by blast
}
moreover
{assume Case22: "|B| ≤o |A|"
hence "¬finite A" using 1 card_of_ordLeq_finite by blast
hence "|A × B| =o |A|" using Case2 Case22
by (auto simp: card_of_Times_infinite)
hence False using LESS1 not_ordLess_ordLeq * ordLeq_ordIso_trans by blast
}
ultimately have False using ordLeq_total card_of_Well_order[of A]
card_of_Well_order[of B] by blast
}
thus ?thesis using ordLess_or_ordLeq[of "|A × B|" "|C|"]
card_of_Well_order[of "A × B"] card_of_Well_order[of "C"] by auto
qed
lemma card_of_Times_ordLess_infinite_Field[simp]:
assumes INF: "¬finite (Field r)" and r: "Card_order r" and
LESS1: "|A| <o r" and LESS2: "|B| <o r"
shows "|A × B| <o r"
proof-
let ?C = "Field r"
have 1: "r =o |?C| ∧ |?C| =o r" using r card_of_Field_ordIso
ordIso_symmetric by blast
hence "|A| <o |?C|" "|B| <o |?C|"
using LESS1 LESS2 ordLess_ordIso_trans by blast+
hence "|A × B| <o |?C|" using INF
card_of_Times_ordLess_infinite by blast
thus ?thesis using 1 ordLess_ordIso_trans by blast
qed
lemma ordLeq_finite_Field:
assumes "r ≤o s" and "finite (Field s)"
shows "finite (Field r)"
by (metis assms card_of_mono2 card_of_ordLeq_infinite)
lemma ordIso_finite_Field:
assumes "r =o s"
shows "finite (Field r) ⟷ finite (Field s)"
by (metis assms ordIso_iff_ordLeq ordLeq_finite_Field)
subsection ‹Cardinals versus set operations involving infinite sets›
lemma finite_iff_cardOf_nat:
"finite A = ( |A| <o |UNIV :: nat set| )"
by (meson card_of_Well_order infinite_iff_card_of_nat not_ordLeq_iff_ordLess)
lemma finite_ordLess_infinite2[simp]:
assumes "finite A" and "¬finite B"
shows "|A| <o |B|"
by (meson assms card_of_Well_order card_of_ordLeq_finite not_ordLeq_iff_ordLess)
lemma infinite_card_of_insert:
assumes "¬finite A"
shows "|insert a A| =o |A|"
proof-
have iA: "insert a A = A ∪ {a}" by simp
show ?thesis
using infinite_imp_bij_betw2[OF assms] unfolding iA
by (metis bij_betw_inv card_of_ordIso)
qed
lemma card_of_Un_singl_ordLess_infinite1:
assumes "¬finite B" and "|A| <o |B|"
shows "|{a} Un A| <o |B|"
by (metis assms card_of_Un_ordLess_infinite finite.emptyI finite_insert finite_ordLess_infinite2)
lemma card_of_Un_singl_ordLess_infinite:
assumes "¬finite B"
shows "|A| <o |B| ⟷ |{a} Un A| <o |B|"
using assms card_of_Un_singl_ordLess_infinite1[of B A]
using card_of_Un2 ordLeq_ordLess_trans by blast
subsection ‹Cardinals versus lists›
text‹The next is an auxiliary operator, which shall be used for inductive
proofs of facts concerning the cardinality of ‹List› :›
definition nlists :: "'a set ⇒ nat ⇒ 'a list set"
where "nlists A n ≡ {l. set l ≤ A ∧ length l = n}"
lemma lists_UNION_nlists: "lists A = (⋃n. nlists A n)"
unfolding lists_eq_set nlists_def by blast
lemma card_of_lists: "|A| ≤o |lists A|"
proof-
let ?h = "λ a. [a]"
have "inj_on ?h A ∧ ?h ` A ≤ lists A"
unfolding inj_on_def lists_eq_set by auto
thus ?thesis by (metis card_of_ordLeq)
qed
lemma nlists_0: "nlists A 0 = {[]}"
unfolding nlists_def by auto
lemma nlists_not_empty:
assumes "A ≠ {}"
shows "nlists A n ≠ {}"
proof (induction n)
case (Suc n)
then obtain a and l where "a ∈ A ∧ l ∈ nlists A n" using assms by auto
hence "a # l ∈ nlists A (Suc n)" unfolding nlists_def by auto
then show ?case by auto
qed (simp add: nlists_0)
lemma card_of_nlists_Succ: "|nlists A (Suc n)| =o |A × (nlists A n)|"
proof-
let ?B = "A × (nlists A n)" let ?h = "λ(a,l). a # l"
have "inj_on ?h ?B ∧ ?h ` ?B ≤ nlists A (Suc n)"
unfolding inj_on_def nlists_def by auto
moreover have "nlists A (Suc n) ≤ ?h ` ?B"
proof clarify
fix l assume "l ∈ nlists A (Suc n)"
hence 1: "length l = Suc n ∧ set l ≤ A" unfolding nlists_def by auto
then obtain a and l' where 2: "l = a # l'" by (auto simp: length_Suc_conv)
hence "a ∈ A ∧ set l' ≤ A ∧ length l' = n" using 1 by auto
thus "l ∈ ?h ` ?B" using 2 unfolding nlists_def by auto
qed
ultimately have "bij_betw ?h ?B (nlists A (Suc n))"
unfolding bij_betw_def by auto
thus ?thesis using card_of_ordIso ordIso_symmetric by blast
qed
lemma card_of_nlists_infinite:
assumes "¬finite A"
shows "|nlists A n| ≤o |A|"
proof(induction n)
case 0
have "A ≠ {}" using assms by auto
then show ?case
by (simp add: nlists_0)
next
case (Suc n)
have "|nlists A (Suc n)| =o |A × (nlists A n)|"
using card_of_nlists_Succ by blast
moreover
have "nlists A n ≠ {}" using assms nlists_not_empty[of A] by blast
hence "|A × (nlists A n)| =o |A|"
using Suc assms by auto
ultimately show ?case
using ordIso_transitive ordIso_iff_ordLeq by blast
qed
lemma Card_order_lists: "Card_order r ⟹ r ≤o |lists(Field r) |"
using card_of_lists card_of_Field_ordIso ordIso_ordLeq_trans ordIso_symmetric by blast
lemma Union_set_lists: "⋃(set ` (lists A)) = A"
proof -
{ fix a assume "a ∈ A"
hence "set [a] ≤ A ∧ a ∈ set [a]" by auto
hence "∃l. set l ≤ A ∧ a ∈ set l" by blast }
then show ?thesis by force
qed
lemma inj_on_map_lists:
assumes "inj_on f A"
shows "inj_on (map f) (lists A)"
using assms Union_set_lists[of A] inj_on_mapI[of f "lists A"] by auto
lemma map_lists_mono:
assumes "f ` A ≤ B"
shows "(map f) ` (lists A) ≤ lists B"
using assms by force
lemma map_lists_surjective:
assumes "f ` A = B"
shows "(map f) ` (lists A) = lists B"
by (metis assms lists_image)
lemma bij_betw_map_lists:
assumes "bij_betw f A B"
shows "bij_betw (map f) (lists A) (lists B)"
using assms unfolding bij_betw_def
by(auto simp: inj_on_map_lists map_lists_surjective)
lemma card_of_lists_mono[simp]:
assumes "|A| ≤o |B|"
shows "|lists A| ≤o |lists B|"
proof-
obtain f where "inj_on f A ∧ f ` A ≤ B"
using assms card_of_ordLeq[of A B] by auto
hence "inj_on (map f) (lists A) ∧ (map f) ` (lists A) ≤ (lists B)"
by (auto simp: inj_on_map_lists map_lists_mono)
thus ?thesis using card_of_ordLeq[of "lists A"] by metis
qed
lemma ordIso_lists_mono:
assumes "r ≤o r'"
shows "|lists(Field r)| ≤o |lists(Field r')|"
using assms card_of_mono2 card_of_lists_mono by blast
lemma card_of_lists_cong[simp]:
assumes "|A| =o |B|"
shows "|lists A| =o |lists B|"
by (meson assms card_of_lists_mono ordIso_iff_ordLeq)
lemma card_of_lists_infinite[simp]:
assumes "¬finite A"
shows "|lists A| =o |A|"
proof-
have "|lists A| ≤o |A|" unfolding lists_UNION_nlists
by (rule card_of_UNION_ordLeq_infinite[OF assms _ ballI[OF card_of_nlists_infinite[OF assms]]])
(metis infinite_iff_card_of_nat assms)
thus ?thesis using card_of_lists ordIso_iff_ordLeq by blast
qed
lemma Card_order_lists_infinite:
assumes "Card_order r" and "¬finite(Field r)"
shows "|lists(Field r)| =o r"
using assms card_of_lists_infinite card_of_Field_ordIso ordIso_transitive by blast
lemma ordIso_lists_cong:
assumes "r =o r'"
shows "|lists(Field r)| =o |lists(Field r')|"
using assms card_of_cong card_of_lists_cong by blast
corollary lists_infinite_bij_betw:
assumes "¬finite A"
shows "∃f. bij_betw f (lists A) A"
using assms card_of_lists_infinite card_of_ordIso by blast
corollary lists_infinite_bij_betw_types:
assumes "¬finite(UNIV :: 'a set)"
shows "∃(f::'a list ⇒ 'a). bij f"
using assms lists_infinite_bij_betw by fastforce
subsection ‹Cardinals versus the finite powerset operator›
lemma card_of_Fpow[simp]: "|A| ≤o |Fpow A|"
proof-
let ?h = "λ a. {a}"
have "inj_on ?h A ∧ ?h ` A ≤ Fpow A"
unfolding inj_on_def Fpow_def by auto
thus ?thesis using card_of_ordLeq by metis
qed
lemma Card_order_Fpow: "Card_order r ⟹ r ≤o |Fpow(Field r) |"
using card_of_Fpow card_of_Field_ordIso ordIso_ordLeq_trans ordIso_symmetric by blast
lemma image_Fpow_surjective:
assumes "f ` A = B"
shows "(image f) ` (Fpow A) = Fpow B"
proof -
have "⋀C. ⟦C ⊆ f ` A; finite C⟧ ⟹ C ∈ (`) f ` {X. X ⊆ A ∧ finite X}"
by (simp add: finite_subset_image image_iff)
then show ?thesis
using assms by (force simp add: Fpow_def)
qed
lemma bij_betw_image_Fpow:
assumes "bij_betw f A B"
shows "bij_betw (image f) (Fpow A) (Fpow B)"
using assms unfolding bij_betw_def
by (auto simp: inj_on_image_Fpow image_Fpow_surjective)
lemma card_of_Fpow_mono[simp]:
assumes "|A| ≤o |B|"
shows "|Fpow A| ≤o |Fpow B|"
proof-
obtain f where "inj_on f A ∧ f ` A ≤ B"
using assms card_of_ordLeq[of A B] by auto
hence "inj_on (image f) (Fpow A) ∧ (image f) ` (Fpow A) ≤ (Fpow B)"
by (auto simp: inj_on_image_Fpow image_Fpow_mono)
thus ?thesis using card_of_ordLeq[of "Fpow A"] by auto
qed
lemma ordIso_Fpow_mono:
assumes "r ≤o r'"
shows "|Fpow(Field r)| ≤o |Fpow(Field r')|"
using assms card_of_mono2 card_of_Fpow_mono by blast
lemma card_of_Fpow_cong[simp]:
assumes "|A| =o |B|"
shows "|Fpow A| =o |Fpow B|"
by (meson assms card_of_Fpow_mono ordIso_iff_ordLeq)
lemma ordIso_Fpow_cong:
assumes "r =o r'"
shows "|Fpow(Field r)| =o |Fpow(Field r')|"
using assms card_of_cong card_of_Fpow_cong by blast
lemma card_of_Fpow_lists: "|Fpow A| ≤o |lists A|"
proof-
have "set ` (lists A) = Fpow A"
unfolding lists_eq_set Fpow_def using finite_list finite_set by blast
thus ?thesis using card_of_ordLeq2[of "Fpow A"] Fpow_not_empty[of A] by blast
qed
lemma card_of_Fpow_infinite[simp]:
assumes "¬finite A"
shows "|Fpow A| =o |A|"
using assms card_of_Fpow_lists card_of_lists_infinite card_of_Fpow
ordLeq_ordIso_trans ordIso_iff_ordLeq by blast
corollary Fpow_infinite_bij_betw:
assumes "¬finite A"
shows "∃f. bij_betw f (Fpow A) A"
using assms card_of_Fpow_infinite card_of_ordIso by blast
subsection ‹The cardinal $\omega$ and the finite cardinals›
subsubsection ‹First as well-orders›
lemma Field_natLess: "Field natLess = (UNIV::nat set)"
by (auto simp: Field_def natLess_def)
lemma natLeq_well_order_on: "well_order_on UNIV natLeq"
using natLeq_Well_order Field_natLeq by auto
lemma natLeq_wo_rel: "wo_rel natLeq"
unfolding wo_rel_def using natLeq_Well_order .
lemma natLeq_ofilter_less: "ofilter natLeq {0 ..< n}"
proof -
have "∀t<n. t ∈ Field natLeq"
by (simp add: Field_natLeq)
moreover have "∀x<n. ∀t. (t, x) ∈ natLeq ⟶ t < n"
by (simp add: natLeq_def)
ultimately show ?thesis
by (auto simp: natLeq_wo_rel wo_rel.ofilter_def under_def)
qed
lemma natLeq_ofilter_leq: "ofilter natLeq {0 .. n}"
by (metis (no_types) atLeastLessThanSuc_atLeastAtMost natLeq_ofilter_less)
lemma natLeq_UNIV_ofilter: "wo_rel.ofilter natLeq UNIV"
using natLeq_wo_rel Field_natLeq wo_rel.Field_ofilter[of natLeq] by auto
lemma closed_nat_set_iff:
assumes "∀(m::nat) n. n ∈ A ∧ m ≤ n ⟶ m ∈ A"
shows "A = UNIV ∨ (∃n. A = {0 ..< n})"
proof-
{assume "A ≠ UNIV" hence "∃n. n ∉ A" by blast
moreover obtain n where n_def: "n = (LEAST n. n ∉ A)" by blast
ultimately have 1: "n ∉ A ∧ (∀m. m < n ⟶ m ∈ A)"
using LeastI_ex[of "λ n. n ∉ A"] n_def Least_le[of "λ n. n ∉ A"] by fastforce
then have "A = {0 ..< n}"
proof(auto simp: 1)
fix m assume *: "m ∈ A"
{assume "n ≤ m" with assms * have "n ∈ A" by blast
hence False using 1 by auto
}
thus "m < n" by fastforce
qed
hence "∃n. A = {0 ..< n}" by blast
}
thus ?thesis by blast
qed
lemma natLeq_ofilter_iff:
"ofilter natLeq A = (A = UNIV ∨ (∃n. A = {0 ..< n}))"
proof(rule iffI)
assume "ofilter natLeq A"
hence "∀m n. n ∈ A ∧ m ≤ n ⟶ m ∈ A" using natLeq_wo_rel
by(auto simp: natLeq_def wo_rel.ofilter_def under_def)
thus "A = UNIV ∨ (∃n. A = {0 ..< n})" using closed_nat_set_iff by blast
next
assume "A = UNIV ∨ (∃n. A = {0 ..< n})"
thus "ofilter natLeq A"
by(auto simp: natLeq_ofilter_less natLeq_UNIV_ofilter)
qed
lemma natLeq_under_leq: "under natLeq n = {0 .. n}"
unfolding under_def natLeq_def by auto
lemma natLeq_on_ofilter_less_eq:
"n ≤ m ⟹ wo_rel.ofilter (natLeq_on m) {0 ..< n}"
by (auto simp: natLeq_on_wo_rel wo_rel.ofilter_def Field_natLeq_on under_def)
lemma natLeq_on_ofilter_iff:
"wo_rel.ofilter (natLeq_on m) A = (∃n ≤ m. A = {0 ..< n})"
proof(rule iffI)
assume *: "wo_rel.ofilter (natLeq_on m) A"
hence 1: "A ≤ {0..<m}"
by (auto simp: natLeq_on_wo_rel wo_rel.ofilter_def under_def Field_natLeq_on)
hence "∀n1 n2. n2 ∈ A ∧ n1 ≤ n2 ⟶ n1 ∈ A"
using * by(fastforce simp add: natLeq_on_wo_rel wo_rel.ofilter_def under_def)
hence "A = UNIV ∨ (∃n. A = {0 ..< n})" using closed_nat_set_iff by blast
thus "∃n ≤ m. A = {0 ..< n}" using 1 atLeastLessThan_less_eq by blast
next
assume "(∃n≤m. A = {0 ..< n})"
thus "wo_rel.ofilter (natLeq_on m) A" by (auto simp: natLeq_on_ofilter_less_eq)
qed
corollary natLeq_on_ofilter:
"ofilter(natLeq_on n) {0 ..< n}"
by (auto simp: natLeq_on_ofilter_less_eq)
lemma natLeq_on_ofilter_less:
assumes "n < m" shows "ofilter (natLeq_on m) {0 .. n}"
proof -
have "Suc n ≤ m"
using assms by simp
then show ?thesis
using natLeq_on_ofilter_iff by auto
qed
lemma natLeq_on_ordLess_natLeq: "natLeq_on n <o natLeq"
proof -
have "well_order natLeq"
using Field_natLeq natLeq_Well_order by auto
moreover have "⋀n. well_order_on {na. na < n} (natLeq_on n)"
using Field_natLeq_on natLeq_on_Well_order by presburger
ultimately show ?thesis
by (simp add: Field_natLeq Field_natLeq_on finite_ordLess_infinite)
qed
lemma natLeq_on_injective:
"natLeq_on m = natLeq_on n ⟹ m = n"
using Field_natLeq_on[of m] Field_natLeq_on[of n]
atLeastLessThan_injective[of m n, unfolded atLeastLessThan_def] by blast
lemma natLeq_on_injective_ordIso:
"(natLeq_on m =o natLeq_on n) = (m = n)"
proof(auto simp: natLeq_on_Well_order ordIso_reflexive)
assume "natLeq_on m =o natLeq_on n"
then obtain f where "bij_betw f {x. x<m} {x. x<n}"
using Field_natLeq_on unfolding ordIso_def iso_def[abs_def] by auto
thus "m = n" using atLeastLessThan_injective2[of f m n]
unfolding atLeast_0 atLeastLessThan_def lessThan_def Int_UNIV_left by blast
qed
subsubsection ‹Then as cardinals›
lemma ordIso_natLeq_infinite1:
"|A| =o natLeq ⟹ ¬finite A"
by (meson finite_iff_ordLess_natLeq not_ordLess_ordIso)
lemma ordIso_natLeq_infinite2:
"natLeq =o |A| ⟹ ¬finite A"
using ordIso_imp_ordLeq infinite_iff_natLeq_ordLeq by blast
lemma ordIso_natLeq_on_imp_finite:
"|A| =o natLeq_on n ⟹ finite A"
unfolding ordIso_def iso_def[abs_def]
by (auto simp: Field_natLeq_on bij_betw_finite)
lemma natLeq_on_Card_order: "Card_order (natLeq_on n)"
proof -
{ fix r assume "well_order_on {x. x < n} r"
hence "natLeq_on n ≤o r"
using finite_atLeastLessThan natLeq_on_well_order_on
finite_well_order_on_ordIso ordIso_iff_ordLeq by blast
}
then show ?thesis
unfolding card_order_on_def using Field_natLeq_on natLeq_on_Well_order by presburger
qed
corollary card_of_Field_natLeq_on:
"|Field (natLeq_on n)| =o natLeq_on n"
using Field_natLeq_on natLeq_on_Card_order
Card_order_iff_ordIso_card_of[of "natLeq_on n"]
ordIso_symmetric[of "natLeq_on n"] by blast
corollary card_of_less:
"|{0 ..< n}| =o natLeq_on n"
using Field_natLeq_on card_of_Field_natLeq_on
unfolding atLeast_0 atLeastLessThan_def lessThan_def Int_UNIV_left by auto
lemma natLeq_on_ordLeq_less_eq:
"((natLeq_on m) ≤o (natLeq_on n)) = (m ≤ n)"
proof
assume "natLeq_on m ≤o natLeq_on n"
then obtain f where "inj_on f {x. x < m} ∧ f ` {x. x < m} ≤ {x. x < n}"
unfolding ordLeq_def using
embed_inj_on[OF natLeq_on_Well_order[of m], of "natLeq_on n", unfolded Field_natLeq_on]
embed_Field Field_natLeq_on by blast
thus "m ≤ n" using atLeastLessThan_less_eq2
unfolding atLeast_0 atLeastLessThan_def lessThan_def Int_UNIV_left by blast
next
assume "m ≤ n"
hence "inj_on id {0..<m} ∧ id ` {0..<m} ≤ {0..<n}" unfolding inj_on_def by auto
hence "|{0..<m}| ≤o |{0..<n}|" using card_of_ordLeq by blast
thus "natLeq_on m ≤o natLeq_on n"
using card_of_less ordIso_ordLeq_trans ordLeq_ordIso_trans ordIso_symmetric by blast
qed
lemma natLeq_on_ordLeq_less:
"((natLeq_on m) <o (natLeq_on n)) = (m < n)"
using not_ordLeq_iff_ordLess[OF natLeq_on_Well_order natLeq_on_Well_order, of n m]
natLeq_on_ordLeq_less_eq[of n m] by linarith
lemma ordLeq_natLeq_on_imp_finite:
assumes "|A| ≤o natLeq_on n"
shows "finite A"
proof-
have "|A| ≤o |{0 ..< n}|"
using assms card_of_less ordIso_symmetric ordLeq_ordIso_trans by blast
thus ?thesis by (auto simp: card_of_ordLeq_finite)
qed
subsubsection ‹"Backward compatibility" with the numeric cardinal operator for finite sets›
lemma finite_card_of_iff_card2:
assumes FIN: "finite A" and FIN': "finite B"
shows "( |A| ≤o |B| ) = (card A ≤ card B)"
using assms card_of_ordLeq[of A B] inj_on_iff_card_le[of A B] by blast
lemma finite_imp_card_of_natLeq_on:
assumes "finite A"
shows "|A| =o natLeq_on (card A)"
proof-
obtain h where "bij_betw h A {0 ..< card A}"
using assms ex_bij_betw_finite_nat by blast
thus ?thesis using card_of_ordIso card_of_less ordIso_equivalence by blast
qed
lemma finite_iff_card_of_natLeq_on:
"finite A = (∃n. |A| =o natLeq_on n)"
using finite_imp_card_of_natLeq_on[of A]
by(auto simp: ordIso_natLeq_on_imp_finite)
lemma finite_card_of_iff_card:
assumes FIN: "finite A" and FIN': "finite B"
shows "( |A| =o |B| ) = (card A = card B)"
using assms card_of_ordIso[of A B] bij_betw_iff_card[of A B] by blast
lemma finite_card_of_iff_card3:
assumes FIN: "finite A" and FIN': "finite B"
shows "( |A| <o |B| ) = (card A < card B)"
proof-
have "( |A| <o |B| ) = (~ ( |B| ≤o |A| ))" by simp
also have "… = (~ (card B ≤ card A))"
using assms by(simp add: finite_card_of_iff_card2)
also have "… = (card A < card B)" by auto
finally show ?thesis .
qed
lemma card_Field_natLeq_on:
"card(Field(natLeq_on n)) = n"
using Field_natLeq_on card_atLeastLessThan by auto
subsection ‹The successor of a cardinal›
lemma embed_implies_ordIso_Restr:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and EMB: "embed r' r f"
shows "r' =o Restr r (f ` (Field r'))"
using assms embed_implies_iso_Restr Well_order_Restr unfolding ordIso_def by blast
lemma cardSuc_mono_ordLess[simp]:
assumes CARD: "Card_order r" and CARD': "Card_order r'"
shows "(cardSuc r <o cardSuc r') = (r <o r')"
proof-
have 0: "Well_order r ∧ Well_order r' ∧ Well_order(cardSuc r) ∧ Well_order(cardSuc r')"
using assms by auto
thus ?thesis
using not_ordLeq_iff_ordLess not_ordLeq_iff_ordLess[of r r']
using cardSuc_mono_ordLeq[of r' r] assms by blast
qed
lemma cardSuc_natLeq_on_Suc:
"cardSuc(natLeq_on n) =o natLeq_on(Suc n)"
proof-
obtain r r' p where r_def: "r = natLeq_on n" and
r'_def: "r' = cardSuc(natLeq_on n)" and
p_def: "p = natLeq_on(Suc n)" by blast
have CARD: "Card_order r ∧ Card_order r' ∧ Card_order p" unfolding r_def r'_def p_def
using cardSuc_ordLess_ordLeq natLeq_on_Card_order cardSuc_Card_order by blast
hence WELL: "Well_order r ∧ Well_order r' ∧ Well_order p"
unfolding card_order_on_def by force
have FIELD: "Field r = {0..<n} ∧ Field p = {0..<(Suc n)}"
unfolding r_def p_def Field_natLeq_on atLeast_0 atLeastLessThan_def lessThan_def by simp
hence FIN: "finite (Field r)" by force
have "r <o r'" using CARD unfolding r_def r'_def using cardSuc_greater by blast
hence "|Field r| <o r'" using CARD card_of_Field_ordIso ordIso_ordLess_trans by blast
hence LESS: "|Field r| <o |Field r'|"
using CARD card_of_Field_ordIso ordLess_ordIso_trans ordIso_symmetric by blast
have "r' ≤o p" using CARD unfolding r_def r'_def p_def
using natLeq_on_ordLeq_less cardSuc_ordLess_ordLeq by blast
moreover have "p ≤o r'"
proof-
{assume "r' <o p"
then obtain f where 0: "embedS r' p f" unfolding ordLess_def by force
let ?q = "Restr p (f ` Field r')"
have 1: "embed r' p f" using 0 unfolding embedS_def by force
hence 2: "f ` Field r' < {0..<(Suc n)}"
using WELL FIELD 0 by (auto simp: embedS_iff)
have "wo_rel.ofilter p (f ` Field r')" using embed_Field_ofilter 1 WELL by blast
then obtain m where "m ≤ Suc n" and 3: "f ` (Field r') = {0..<m}"
unfolding p_def by (auto simp: natLeq_on_ofilter_iff)
hence 4: "m ≤ n" using 2 by force
have "bij_betw f (Field r') (f ` (Field r'))"
using WELL embed_inj_on[OF _ 1] unfolding bij_betw_def by blast
moreover have "finite(f ` (Field r'))" using 3 finite_atLeastLessThan[of 0 m] by force
ultimately have 5: "finite (Field r') ∧ card(Field r') = card (f ` (Field r'))"
using bij_betw_same_card bij_betw_finite by metis
hence "card(Field r') ≤ card(Field r)" using 3 4 FIELD by force
hence "|Field r'| ≤o |Field r|" using FIN 5 finite_card_of_iff_card2 by blast
hence False using LESS not_ordLess_ordLeq by auto
}
thus ?thesis using WELL CARD by fastforce
qed
ultimately show ?thesis using ordIso_iff_ordLeq unfolding r'_def p_def by blast
qed
lemma card_of_Plus_ordLeq_infinite[simp]:
assumes "¬finite C" and "|A| ≤o |C|" and "|B| ≤o |C|"
shows "|A <+> B| ≤o |C|"
by (simp add: assms)
lemma card_of_Un_ordLeq_infinite[simp]:
assumes "¬finite C" and "|A| ≤o |C|" and "|B| ≤o |C|"
shows "|A Un B| ≤o |C|"
using assms card_of_Plus_ordLeq_infinite card_of_Un_Plus_ordLeq ordLeq_transitive by metis
subsection ‹Others›
lemma under_mono[simp]:
assumes "Well_order r" and "(i,j) ∈ r"
shows "under r i ⊆ under r j"
using assms unfolding under_def order_on_defs trans_def by blast
lemma underS_under:
assumes "i ∈ Field r"
shows "underS r i = under r i - {i}"
using assms unfolding underS_def under_def by auto
lemma relChain_under:
assumes "Well_order r"
shows "relChain r (λ i. under r i)"
using assms unfolding relChain_def by auto
lemma card_of_infinite_diff_finite:
assumes "¬finite A" and "finite B"
shows "|A - B| =o |A|"
by (metis assms card_of_Un_diff_infinite finite_ordLess_infinite2)
lemma infinite_card_of_diff_singl:
assumes "¬finite A"
shows "|A - {a}| =o |A|"
by (metis assms card_of_infinite_diff_finite finite.emptyI finite_insert)
lemma card_of_vimage:
assumes "B ⊆ range f"
shows "|B| ≤o |f -` B|"
by (metis Int_absorb2 assms image_vimage_eq order_refl surj_imp_ordLeq)
lemma surj_card_of_vimage:
assumes "surj f"
shows "|B| ≤o |f -` B|"
by (metis assms card_of_vimage subset_UNIV)
definition Bpow where
"Bpow r A ≡ {X . X ⊆ A ∧ |X| ≤o r}"
lemma Bpow_empty[simp]:
assumes "Card_order r"
shows "Bpow r {} = {{}}"
using assms unfolding Bpow_def by auto
lemma singl_in_Bpow:
assumes rc: "Card_order r"
and r: "Field r ≠ {}" and a: "a ∈ A"
shows "{a} ∈ Bpow r A"
proof-
have "|{a}| ≤o r" using r rc by auto
thus ?thesis unfolding Bpow_def using a by auto
qed
lemma ordLeq_card_Bpow:
assumes rc: "Card_order r" and r: "Field r ≠ {}"
shows "|A| ≤o |Bpow r A|"
proof-
have "inj_on (λ a. {a}) A" unfolding inj_on_def by auto
moreover have "(λ a. {a}) ` A ⊆ Bpow r A"
using singl_in_Bpow[OF assms] by auto
ultimately show ?thesis unfolding card_of_ordLeq[symmetric] by blast
qed
lemma infinite_Bpow:
assumes rc: "Card_order r" and r: "Field r ≠ {}"
and A: "¬finite A"
shows "¬finite (Bpow r A)"
using ordLeq_card_Bpow[OF rc r]
by (metis A card_of_ordLeq_infinite)
definition Func_option where
"Func_option A B ≡
{f. (∀ a. f a ≠ None ⟷ a ∈ A) ∧ (∀ a ∈ A. case f a of Some b ⇒ b ∈ B |None ⇒ True)}"
lemma card_of_Func_option_Func:
"|Func_option A B| =o |Func A B|"
proof (rule ordIso_symmetric, unfold card_of_ordIso[symmetric], intro exI)
let ?F = "λ f a. if a ∈ A then Some (f a) else None"
show "bij_betw ?F (Func A B) (Func_option A B)"
unfolding bij_betw_def unfolding inj_on_def proof(intro conjI ballI impI)
fix f g assume f: "f ∈ Func A B" and g: "g ∈ Func A B" and eq: "?F f = ?F g"
show "f = g"
proof(rule ext)
fix a
show "f a = g a"
by (smt (verit) Func_def eq f g mem_Collect_eq option.inject)
qed
next
show "?F ` Func A B = Func_option A B"
proof safe
fix f assume f: "f ∈ Func_option A B"
define g where [abs_def]: "g a = (case f a of Some b ⇒ b | None ⇒ undefined)" for a
have "g ∈ Func A B"
using f unfolding g_def Func_def Func_option_def by force+
moreover have "f = ?F g"
proof(rule ext)
fix a show "f a = ?F g a"
using f unfolding Func_option_def g_def by (cases "a ∈ A") force+
qed
ultimately show "f ∈ ?F ` (Func A B)" by blast
qed(unfold Func_def Func_option_def, auto)
qed
qed
definition Pfunc where
"Pfunc A B ≡
{f. (∀a. f a ≠ None ⟶ a ∈ A) ∧
(∀a. case f a of None ⇒ True | Some b ⇒ b ∈ B)}"
lemma Func_Pfunc:
"Func_option A B ⊆ Pfunc A B"
unfolding Func_option_def Pfunc_def by auto
lemma Pfunc_Func_option:
"Pfunc A B = (⋃A' ∈ Pow A. Func_option A' B)"
proof safe
fix f assume f: "f ∈ Pfunc A B"
show "f ∈ (⋃A'∈Pow A. Func_option A' B)"
proof (intro UN_I)
let ?A' = "{a. f a ≠ None}"
show "?A' ∈ Pow A" using f unfolding Pow_def Pfunc_def by auto
show "f ∈ Func_option ?A' B" using f unfolding Func_option_def Pfunc_def by auto
qed
next
fix f A' assume "f ∈ Func_option A' B" and "A' ⊆ A"
thus "f ∈ Pfunc A B" unfolding Func_option_def Pfunc_def by auto
qed
lemma card_of_Func_mono:
fixes A1 A2 :: "'a set" and B :: "'b set"
assumes A12: "A1 ⊆ A2" and B: "B ≠ {}"
shows "|Func A1 B| ≤o |Func A2 B|"
proof-
obtain bb where bb: "bb ∈ B" using B by auto
define F where [abs_def]: "F f1 a =
(if a ∈ A2 then (if a ∈ A1 then f1 a else bb) else undefined)" for f1 :: "'a ⇒ 'b" and a
show ?thesis unfolding card_of_ordLeq[symmetric]
proof(intro exI[of _ F] conjI)
show "inj_on F (Func A1 B)" unfolding inj_on_def
proof safe
fix f g assume f: "f ∈ Func A1 B" and g: "g ∈ Func A1 B" and eq: "F f = F g"
show "f = g"
proof(rule ext)
fix a show "f a = g a"
by (smt (verit) A12 F_def Func_def eq f g mem_Collect_eq subsetD)
qed
qed
qed(insert bb, unfold Func_def F_def, force)
qed
lemma card_of_Func_option_mono:
fixes A1 A2 :: "'a set" and B :: "'b set"
assumes A12: "A1 ⊆ A2" and B: "B ≠ {}"
shows "|Func_option A1 B| ≤o |Func_option A2 B|"
by (metis card_of_Func_mono[OF A12 B] card_of_Func_option_Func
ordIso_ordLeq_trans ordLeq_ordIso_trans ordIso_symmetric)
lemma card_of_Pfunc_Pow_Func_option:
assumes "B ≠ {}"
shows "|Pfunc A B| ≤o |Pow A × Func_option A B|"
proof-
have "|Pfunc A B| =o |⋃A' ∈ Pow A. Func_option A' B|" (is "_ =o ?K")
unfolding Pfunc_Func_option by(rule card_of_refl)
also have "?K ≤o |Sigma (Pow A) (λ A'. Func_option A' B)|" using card_of_UNION_Sigma .
also have "|Sigma (Pow A) (λ A'. Func_option A' B)| ≤o |Pow A × Func_option A B|"
by (simp add: assms card_of_Func_option_mono card_of_Sigma_mono1)
finally show ?thesis .
qed
lemma Bpow_ordLeq_Func_Field:
assumes rc: "Card_order r" and r: "Field r ≠ {}" and A: "¬finite A"
shows "|Bpow r A| ≤o |Func (Field r) A|"
proof-
let ?F = "λ f. {x | x a. f a = x ∧ a ∈ Field r}"
{fix X assume "X ∈ Bpow r A - {{}}"
hence XA: "X ⊆ A" and "|X| ≤o r"
and X: "X ≠ {}" unfolding Bpow_def by auto
hence "|X| ≤o |Field r|" by (metis Field_card_of card_of_mono2)
then obtain F where 1: "X = F ` (Field r)"
using card_of_ordLeq2[OF X] by metis
define f where [abs_def]: "f i = (if i ∈ Field r then F i else undefined)" for i
have "∃ f ∈ Func (Field r) A. X = ?F f"
apply (intro bexI[of _ f]) using 1 XA unfolding Func_def f_def by auto
}
hence "Bpow r A - {{}} ⊆ ?F ` (Func (Field r) A)" by auto
hence "|Bpow r A - {{}}| ≤o |Func (Field r) A|"
by (rule surj_imp_ordLeq)
moreover
{have 2: "¬finite (Bpow r A)" using infinite_Bpow[OF rc r A] .
have "|Bpow r A| =o |Bpow r A - {{}}|"
by (metis 2 infinite_card_of_diff_singl ordIso_symmetric)
}
ultimately show ?thesis by (metis ordIso_ordLeq_trans)
qed
lemma empty_in_Func[simp]:
"B ≠ {} ⟹ (λx. undefined) ∈ Func {} B"
by simp
lemma Func_mono[simp]:
assumes "B1 ⊆ B2"
shows "Func A B1 ⊆ Func A B2"
using assms unfolding Func_def by force
lemma Pfunc_mono[simp]:
assumes "A1 ⊆ A2" and "B1 ⊆ B2"
shows "Pfunc A B1 ⊆ Pfunc A B2"
using assms unfolding Pfunc_def
by (force split: option.split_asm option.split)
lemma card_of_Func_UNIV_UNIV:
"|Func (UNIV::'a set) (UNIV::'b set)| =o |UNIV::('a ⇒ 'b) set|"
using card_of_Func_UNIV[of "UNIV::'b set"] by auto
lemma ordLeq_Func:
assumes "{b1,b2} ⊆ B" "b1 ≠ b2"
shows "|A| ≤o |Func A B|"
unfolding card_of_ordLeq[symmetric] proof(intro exI conjI)
let ?F = "λx a. if a ∈ A then (if a = x then b1 else b2) else undefined"
show "inj_on ?F A" using assms unfolding inj_on_def fun_eq_iff by auto
show "?F ` A ⊆ Func A B" using assms unfolding Func_def by auto
qed
lemma infinite_Func:
assumes A: "¬finite A" and B: "{b1,b2} ⊆ B" "b1 ≠ b2"
shows "¬finite (Func A B)"
using ordLeq_Func[OF B] by (metis A card_of_ordLeq_finite)
subsection ‹Infinite cardinals are limit ordinals›
lemma card_order_infinite_isLimOrd:
assumes c: "Card_order r" and i: "¬finite (Field r)"
shows "isLimOrd r"
proof-
have 0: "wo_rel r" and 00: "Well_order r"
using c unfolding card_order_on_def wo_rel_def by auto
hence rr: "Refl r" by (metis wo_rel.REFL)
show ?thesis unfolding wo_rel.isLimOrd_def[OF 0] wo_rel.isSuccOrd_def[OF 0]
proof safe
fix j assume "j ∈ Field r" and "∀i∈Field r. (i, j) ∈ r"
then show False
by (metis Card_order_trans c i infinite_Card_order_limit)
qed
qed
lemma insert_Chain:
assumes "Refl r" "C ∈ Chains r" and "i ∈ Field r" and "⋀j. j ∈ C ⟹ (j,i) ∈ r ∨ (i,j) ∈ r"
shows "insert i C ∈ Chains r"
using assms unfolding Chains_def by (auto dest: refl_onD)
lemma Collect_insert: "{R j |j. j ∈ insert j1 J} = insert (R j1) {R j |j. j ∈ J}"
by auto
lemma Field_init_seg_of[simp]:
"Field init_seg_of = UNIV"
unfolding Field_def init_seg_of_def by auto
lemma refl_init_seg_of[intro, simp]: "refl init_seg_of"
unfolding refl_on_def Field_def by auto
lemma regularCard_all_ex:
assumes r: "Card_order r" "regularCard r"
and As: "⋀ i j b. b ∈ B ⟹ (i,j) ∈ r ⟹ P i b ⟹ P j b"
and Bsub: "∀ b ∈ B. ∃ i ∈ Field r. P i b"
and cardB: "|B| <o r"
shows "∃ i ∈ Field r. ∀ b ∈ B. P i b"
proof-
let ?As = "λi. {b ∈ B. P i b}"
have "∃i ∈ Field r. B ≤ ?As i"
apply(rule regularCard_UNION) using assms unfolding relChain_def by auto
thus ?thesis by auto
qed
lemma relChain_stabilize:
assumes rc: "relChain r As" and AsB: "(⋃i ∈ Field r. As i) ⊆ B" and Br: "|