Mercurial > hg > Members > kono > Proof > ZF-in-agda
annotate HOD.agda @ 121:453ef0d4ee8a
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| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Thu, 27 Jun 2019 19:26:45 +0900 |
| parents | ac214eab1c3c |
| children | 4d2434513228 |
| rev | line source |
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| 16 | 1 open import Level |
| 112 | 2 module HOD where |
| 3 | 3 |
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4 open import zf |
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5 open import ordinal |
| 23 | 6 open import Data.Nat renaming ( zero to Zero ; suc to Suc ; ℕ to Nat ; _⊔_ to _n⊔_ ) |
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7 open import Relation.Binary.PropositionalEquality |
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8 open import Data.Nat.Properties |
| 6 | 9 open import Data.Empty |
| 10 open import Relation.Nullary | |
| 11 open import Relation.Binary | |
| 12 open import Relation.Binary.Core | |
| 13 | |
| 27 | 14 -- Ordinal Definable Set |
| 11 | 15 |
| 112 | 16 record HOD {n : Level} : Set (suc n) where |
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17 field |
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18 def : (x : Ordinal {n} ) → Set n |
| 114 | 19 otrans : {x : Ordinal {n} } → def x → { y : Ordinal {n} } → y o< x → def y |
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20 |
| 112 | 21 open HOD |
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22 open import Data.Unit |
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23 |
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24 open Ordinal |
| 120 | 25 open _∧_ |
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26 |
| 112 | 27 record _==_ {n : Level} ( a b : HOD {n} ) : Set n where |
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28 field |
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29 eq→ : ∀ { x : Ordinal {n} } → def a x → def b x |
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30 eq← : ∀ { x : Ordinal {n} } → def b x → def a x |
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31 |
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32 id : {n : Level} {A : Set n} → A → A |
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33 id x = x |
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34 |
| 112 | 35 eq-refl : {n : Level} { x : HOD {n} } → x == x |
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36 eq-refl {n} {x} = record { eq→ = id ; eq← = id } |
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37 |
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38 open _==_ |
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39 |
| 112 | 40 eq-sym : {n : Level} { x y : HOD {n} } → x == y → y == x |
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41 eq-sym eq = record { eq→ = eq← eq ; eq← = eq→ eq } |
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42 |
| 112 | 43 eq-trans : {n : Level} { x y z : HOD {n} } → x == y → y == z → x == z |
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44 eq-trans x=y y=z = record { eq→ = λ t → eq→ y=z ( eq→ x=y t) ; eq← = λ t → eq← x=y ( eq← y=z t) } |
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45 |
| 120 | 46 ⇔→== : {n : Level} { x y : HOD {suc n} } → ( {z : Ordinal {suc n}} → def x z ⇔ def y z) → x == y |
| 47 eq→ ( ⇔→== {n} {x} {y} eq ) {z} m = proj1 eq m | |
| 48 eq← ( ⇔→== {n} {x} {y} eq ) {z} m = proj2 eq m | |
| 49 | |
| 112 | 50 -- Ordinal in HOD ( and ZFSet ) |
| 51 Ord : { n : Level } → ( a : Ordinal {n} ) → HOD {n} | |
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52 Ord {n} a = record { def = λ y → y o< a ; otrans = lemma } where |
| 114 | 53 lemma : {x : Ordinal} → x o< a → {y : Ordinal} → y o< x → y o< a |
| 54 lemma {x} x<a {y} y<x = ordtrans {n} {y} {x} {a} y<x x<a | |
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55 |
| 112 | 56 od∅ : {n : Level} → HOD {n} |
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57 od∅ {n} = Ord o∅ |
| 40 | 58 |
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59 postulate |
| 112 | 60 -- HOD can be iso to a subset of Ordinal ( by means of Godel Set ) |
| 61 od→ord : {n : Level} → HOD {n} → Ordinal {n} | |
| 113 | 62 ord→od : {n : Level} → Ordinal {n} → HOD {n} |
| 63 oiso : {n : Level} {x : HOD {n}} → ord→od ( od→ord x ) ≡ x | |
| 64 diso : {n : Level} {x : Ordinal {n}} → od→ord ( ord→od x ) ≡ x | |
| 112 | 65 c<→o< : {n : Level} {x y : HOD {n} } → def y ( od→ord x ) → od→ord x o< od→ord y |
| 116 | 66 ord-Ord :{n : Level} {x : Ordinal {n}} → x ≡ od→ord (Ord x) |
| 120 | 67 ==→o≡ : {n : Level} → { x y : HOD {suc n} } → (x == y) → x ≡ y |
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68 -- next assumption causes ∀ x ∋ ∅ . It menas only an ordinal becomes a set |
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69 -- o<→c< : {n : Level} {x y : Ordinal {n} } → x o< y → def (ord→od y) x |
| 100 | 70 -- supermum as Replacement Axiom |
| 95 | 71 sup-o : {n : Level } → ( Ordinal {n} → Ordinal {n}) → Ordinal {n} |
| 98 | 72 sup-o< : {n : Level } → { ψ : Ordinal {n} → Ordinal {n}} → ∀ {x : Ordinal {n}} → ψ x o< sup-o ψ |
| 111 | 73 -- contra-position of mimimulity of supermum required in Power Set Axiom |
| 98 | 74 sup-x : {n : Level } → ( Ordinal {n} → Ordinal {n}) → Ordinal {n} |
| 75 sup-lb : {n : Level } → { ψ : Ordinal {n} → Ordinal {n}} → {z : Ordinal {n}} → z o< sup-o ψ → z o< osuc (ψ (sup-x ψ)) | |
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76 -- sup-lb : {n : Level } → ( ψ : Ordinal {n} → Ordinal {n}) → ( ∀ {x : Ordinal {n}} → ψx o< z ) → z o< osuc ( sup-o ψ ) |
| 117 | 77 minimul : {n : Level } → (x : HOD {suc n} ) → ¬ (x == od∅ )→ HOD {suc n} |
| 78 -- this should be ¬ (x == od∅ )→ ∃ ox → x ∋ Ord ox ( minimum of x ) | |
| 79 x∋minimul : {n : Level } → (x : HOD {suc n} ) → ( ne : ¬ (x == od∅ ) ) → def x ( od→ord ( minimul x ne ) ) | |
| 80 minimul-1 : {n : Level } → (x : HOD {suc n} ) → ( ne : ¬ (x == od∅ ) ) → (y : HOD {suc n}) → ¬ ( def (minimul x ne) (od→ord y)) ∧ (def x (od→ord y) ) | |
| 95 | 81 |
| 112 | 82 _∋_ : { n : Level } → ( a x : HOD {n} ) → Set n |
| 95 | 83 _∋_ {n} a x = def a ( od→ord x ) |
| 84 | |
| 112 | 85 _c<_ : { n : Level } → ( x a : HOD {n} ) → Set n |
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86 x c< a = a ∋ x |
| 103 | 87 |
| 112 | 88 _c≤_ : {n : Level} → HOD {n} → HOD {n} → Set (suc n) |
| 95 | 89 a c≤ b = (a ≡ b) ∨ ( b ∋ a ) |
| 90 | |
| 113 | 91 cseq : {n : Level} → HOD {n} → HOD {n} |
| 118 | 92 cseq x = record { def = λ y → def x (osuc y) ; otrans = lemma } where |
| 93 lemma : {ox : Ordinal} → def x (osuc ox) → { oy : Ordinal}→ oy o< ox → def x (osuc oy) | |
| 94 lemma {ox} oox<Ox {oy} oy<ox = otrans x oox<Ox (osucc oy<ox ) | |
| 113 | 95 |
| 112 | 96 def-subst : {n : Level } {Z : HOD {n}} {X : Ordinal {n} }{z : HOD {n}} {x : Ordinal {n} }→ def Z X → Z ≡ z → X ≡ x → def z x |
| 95 | 97 def-subst df refl refl = df |
| 98 | |
| 113 | 99 o<→c< : {n : Level} {x y : Ordinal {n} } → x o< y → Ord y ∋ Ord x |
| 100 o<→c< {n} {x} {y} lt = subst ( λ k → k o< y ) ord-Ord lt | |
| 101 | |
| 112 | 102 sup-od : {n : Level } → ( HOD {n} → HOD {n}) → HOD {n} |
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103 sup-od ψ = Ord ( sup-o ( λ x → od→ord (ψ (ord→od x ))) ) |
| 95 | 104 |
| 112 | 105 sup-c< : {n : Level } → ( ψ : HOD {n} → HOD {n}) → ∀ {x : HOD {n}} → def ( sup-od ψ ) (od→ord ( ψ x )) |
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106 sup-c< {n} ψ {x} = def-subst {n} {_} {_} {Ord ( sup-o ( λ x → od→ord (ψ (ord→od x ))) )} {od→ord ( ψ x )} |
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107 lemma refl (cong ( λ k → od→ord (ψ k) ) oiso) where |
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108 lemma : od→ord (ψ (ord→od (od→ord x))) o< sup-o (λ x → od→ord (ψ (ord→od x))) |
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109 lemma = subst₂ (λ j k → j o< k ) refl diso (o<-subst sup-o< refl (sym diso) ) |
| 28 | 110 |
| 37 | 111 ∅3 : {n : Level} → { x : Ordinal {n}} → ( ∀(y : Ordinal {n}) → ¬ (y o< x ) ) → x ≡ o∅ {n} |
| 81 | 112 ∅3 {n} {x} = TransFinite {n} c2 c3 x where |
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113 c0 : Nat → Ordinal {n} → Set n |
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114 c0 lx x = (∀(y : Ordinal {n}) → ¬ (y o< x)) → x ≡ o∅ {n} |
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115 c2 : (lx : Nat) → c0 lx (record { lv = lx ; ord = Φ lx } ) |
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116 c2 Zero not = refl |
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117 c2 (Suc lx) not with not ( record { lv = lx ; ord = Φ lx } ) |
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118 ... | t with t (case1 ≤-refl ) |
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119 c2 (Suc lx) not | t | () |
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120 c3 : (lx : Nat) (x₁ : OrdinalD lx) → c0 lx (record { lv = lx ; ord = x₁ }) → c0 lx (record { lv = lx ; ord = OSuc lx x₁ }) |
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121 c3 lx (Φ .lx) d not with not ( record { lv = lx ; ord = Φ lx } ) |
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122 ... | t with t (case2 Φ< ) |
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123 c3 lx (Φ .lx) d not | t | () |
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124 c3 lx (OSuc .lx x₁) d not with not ( record { lv = lx ; ord = OSuc lx x₁ } ) |
| 34 | 125 ... | t with t (case2 (s< s<refl ) ) |
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126 c3 lx (OSuc .lx x₁) d not | t | () |
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127 |
| 112 | 128 transitive : {n : Level } { z y x : HOD {suc n} } → z ∋ y → y ∋ x → z ∋ x |
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129 transitive {n} {z} {y} {x} z∋y x∋y with ordtrans ( c<→o< {suc n} {x} {y} x∋y ) ( c<→o< {suc n} {y} {z} z∋y ) |
| 111 | 130 ... | t = otrans z z∋y (c<→o< {suc n} {x} {y} x∋y ) |
| 36 | 131 |
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132 record Minimumo {n : Level } (x : Ordinal {n}) : Set (suc n) where |
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133 field |
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134 mino : Ordinal {n} |
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135 min<x : mino o< x |
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136 |
| 57 | 137 ∅5 : {n : Level} → { x : Ordinal {n} } → ¬ ( x ≡ o∅ {n} ) → o∅ {n} o< x |
| 138 ∅5 {n} {record { lv = Zero ; ord = (Φ .0) }} not = ⊥-elim (not refl) | |
| 139 ∅5 {n} {record { lv = Zero ; ord = (OSuc .0 ord) }} not = case2 Φ< | |
| 140 ∅5 {n} {record { lv = (Suc lv) ; ord = ord }} not = case1 (s≤s z≤n) | |
| 37 | 141 |
| 46 | 142 ord-iso : {n : Level} {y : Ordinal {n} } → record { lv = lv (od→ord (ord→od y)) ; ord = ord (od→ord (ord→od y)) } ≡ record { lv = lv y ; ord = ord y } |
| 143 ord-iso = cong ( λ k → record { lv = lv k ; ord = ord k } ) diso | |
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144 |
| 51 | 145 -- avoiding lv != Zero error |
| 112 | 146 orefl : {n : Level} → { x : HOD {n} } → { y : Ordinal {n} } → od→ord x ≡ y → od→ord x ≡ y |
| 51 | 147 orefl refl = refl |
| 148 | |
| 112 | 149 ==-iso : {n : Level} → { x y : HOD {n} } → ord→od (od→ord x) == ord→od (od→ord y) → x == y |
| 51 | 150 ==-iso {n} {x} {y} eq = record { |
| 151 eq→ = λ d → lemma ( eq→ eq (def-subst d (sym oiso) refl )) ; | |
| 152 eq← = λ d → lemma ( eq← eq (def-subst d (sym oiso) refl )) } | |
| 153 where | |
| 112 | 154 lemma : {x : HOD {n} } {z : Ordinal {n}} → def (ord→od (od→ord x)) z → def x z |
| 51 | 155 lemma {x} {z} d = def-subst d oiso refl |
| 156 | |
| 112 | 157 =-iso : {n : Level } {x y : HOD {suc n} } → (x == y) ≡ (ord→od (od→ord x) == y) |
| 57 | 158 =-iso {_} {_} {y} = cong ( λ k → k == y ) (sym oiso) |
| 159 | |
| 112 | 160 ord→== : {n : Level} → { x y : HOD {n} } → od→ord x ≡ od→ord y → x == y |
| 51 | 161 ord→== {n} {x} {y} eq = ==-iso (lemma (od→ord x) (od→ord y) (orefl eq)) where |
| 162 lemma : ( ox oy : Ordinal {n} ) → ox ≡ oy → (ord→od ox) == (ord→od oy) | |
| 163 lemma ox ox refl = eq-refl | |
| 164 | |
| 165 o≡→== : {n : Level} → { x y : Ordinal {n} } → x ≡ y → ord→od x == ord→od y | |
| 166 o≡→== {n} {x} {.x} refl = eq-refl | |
| 167 | |
| 168 >→¬< : {x y : Nat } → (x < y ) → ¬ ( y < x ) | |
| 169 >→¬< (s≤s x<y) (s≤s y<x) = >→¬< x<y y<x | |
| 170 | |
| 112 | 171 c≤-refl : {n : Level} → ( x : HOD {n} ) → x c≤ x |
| 51 | 172 c≤-refl x = case1 refl |
| 173 | |
| 112 | 174 ∋→o< : {n : Level} → { a x : HOD {suc n} } → a ∋ x → od→ord x o< od→ord a |
| 91 | 175 ∋→o< {n} {a} {x} lt = t where |
| 176 t : (od→ord x) o< (od→ord a) | |
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177 t = c<→o< {suc n} {x} {a} lt |
| 91 | 178 |
| 80 | 179 o∅≡od∅ : {n : Level} → ord→od (o∅ {suc n}) ≡ od∅ {suc n} |
| 180 o∅≡od∅ {n} with trio< {n} (o∅ {suc n}) (od→ord (od∅ {suc n} )) | |
| 181 o∅≡od∅ {n} | tri< a ¬b ¬c = ⊥-elim (lemma a) where | |
| 182 lemma : o∅ {suc n } o< (od→ord (od∅ {suc n} )) → ⊥ | |
| 113 | 183 lemma lt with o<→c< lt |
| 184 lemma lt | t = o<¬≡ refl t | |
| 80 | 185 o∅≡od∅ {n} | tri≈ ¬a b ¬c = trans (cong (λ k → ord→od k ) b ) oiso |
| 186 o∅≡od∅ {n} | tri> ¬a ¬b c = ⊥-elim (¬x<0 c) | |
| 187 | |
| 112 | 188 o<→¬c> : {n : Level} → { x y : HOD {n} } → (od→ord x ) o< ( od→ord y) → ¬ (y c< x ) |
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189 o<→¬c> {n} {x} {y} olt clt = o<> olt (c<→o< clt ) where |
| 51 | 190 |
| 112 | 191 o≡→¬c< : {n : Level} → { x y : HOD {n} } → (od→ord x ) ≡ ( od→ord y) → ¬ x c< y |
| 111 | 192 o≡→¬c< {n} {x} {y} oeq lt = o<¬≡ (orefl oeq ) (c<→o< lt) |
| 54 | 193 |
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194 ∅0 : {n : Level} → record { def = λ x → Lift n ⊥ ; otrans = λ () } == od∅ {n} |
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195 eq→ ∅0 {w} (lift ()) |
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196 eq← ∅0 {w} (case1 ()) |
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197 eq← ∅0 {w} (case2 ()) |
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198 |
| 112 | 199 ∅< : {n : Level} → { x y : HOD {n} } → def x (od→ord y ) → ¬ ( x == od∅ {n} ) |
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200 ∅< {n} {x} {y} d eq with eq→ (eq-trans eq (eq-sym ∅0) ) d |
| 60 | 201 ∅< {n} {x} {y} d eq | lift () |
| 57 | 202 |
| 120 | 203 ∅6 : {n : Level} → { x : HOD {suc n} } → ¬ ( x ∋ x ) -- no Russel paradox |
| 204 ∅6 {n} {x} x∋x = o<¬≡ refl ( c<→o< {suc n} {x} {x} x∋x ) | |
| 51 | 205 |
| 112 | 206 def-iso : {n : Level} {A B : HOD {n}} {x y : Ordinal {n}} → x ≡ y → (def A y → def B y) → def A x → def B x |
| 76 | 207 def-iso refl t = t |
| 208 | |
| 57 | 209 is-o∅ : {n : Level} → ( x : Ordinal {suc n} ) → Dec ( x ≡ o∅ {suc n} ) |
| 210 is-o∅ {n} record { lv = Zero ; ord = (Φ .0) } = yes refl | |
| 211 is-o∅ {n} record { lv = Zero ; ord = (OSuc .0 ord₁) } = no ( λ () ) | |
| 212 is-o∅ {n} record { lv = (Suc lv₁) ; ord = ord } = no (λ()) | |
| 213 | |
| 119 | 214 |
| 79 | 215 -- open import Relation.Binary.HeterogeneousEquality as HE using (_≅_ ) |
| 94 | 216 -- postulate f-extensionality : { n : Level} → Relation.Binary.PropositionalEquality.Extensionality (suc n) (suc (suc n)) |
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217 |
| 112 | 218 csuc : {n : Level} → HOD {suc n} → HOD {suc n} |
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219 csuc x = ord→od ( osuc ( od→ord x )) |
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220 |
| 96 | 221 -- Power Set of X ( or constructible by λ y → def X (od→ord y ) |
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222 |
| 112 | 223 ZFSubset : {n : Level} → (A x : HOD {suc n} ) → HOD {suc n} |
| 121 | 224 ZFSubset A x = record { def = λ y → def A y ∧ def x y ; otrans = lemma } where |
| 225 lemma : {z : Ordinal} → def A z ∧ def x z → {y : Ordinal} → y o< z → def A y ∧ def x y | |
| 226 lemma {z} d {y} y<z = record { proj1 = otrans A (proj1 d) y<z ; proj2 = otrans x (proj2 d) y<z } | |
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227 |
| 112 | 228 Def : {n : Level} → (A : HOD {suc n}) → HOD {suc n} |
| 121 | 229 Def {n} A = Ord ( sup-o ( λ x → od→ord ( ZFSubset A (ord→od x )) ) ) |
| 96 | 230 |
| 231 -- Constructible Set on α | |
| 112 | 232 L : {n : Level} → (α : Ordinal {suc n}) → HOD {suc n} |
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233 L {n} record { lv = Zero ; ord = (Φ .0) } = od∅ |
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234 L {n} record { lv = lx ; ord = (OSuc lv ox) } = Def ( L {n} ( record { lv = lx ; ord = ox } ) ) |
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235 L {n} record { lv = (Suc lx) ; ord = (Φ (Suc lx)) } = -- Union ( L α ) |
| 121 | 236 cseq ( Ord (od→ord (L {n} (record { lv = lx ; ord = Φ lx })))) |
| 89 | 237 |
| 111 | 238 omega : { n : Level } → Ordinal {n} |
| 239 omega = record { lv = Suc Zero ; ord = Φ 1 } | |
| 240 | |
| 112 | 241 HOD→ZF : {n : Level} → ZF {suc (suc n)} {suc n} |
| 242 HOD→ZF {n} = record { | |
| 243 ZFSet = HOD {suc n} | |
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244 ; _∋_ = _∋_ |
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245 ; _≈_ = _==_ |
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246 ; ∅ = od∅ |
| 28 | 247 ; _,_ = _,_ |
| 248 ; Union = Union | |
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249 ; Power = Power |
| 28 | 250 ; Select = Select |
| 251 ; Replace = Replace | |
| 111 | 252 ; infinite = Ord omega |
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253 ; isZF = isZF |
| 28 | 254 } where |
| 112 | 255 Replace : HOD {suc n} → (HOD {suc n} → HOD {suc n} ) → HOD {suc n} |
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256 Replace X ψ = sup-od ψ |
| 115 | 257 Select : (X : HOD {suc n} ) → ((x : HOD {suc n} ) → Set (suc n) ) → HOD {suc n} |
| 116 | 258 Select X ψ = record { def = λ x → ((y : Ordinal {suc n} ) → X ∋ ord→od y → ψ (ord→od y)) ∧ (X ∋ ord→od x ) ; otrans = lemma } where |
| 259 lemma : {x : Ordinal} → ((y : Ordinal) → X ∋ ord→od y → ψ (ord→od y)) ∧ (X ∋ ord→od x) → | |
| 260 {y : Ordinal} → y o< x → ((y₁ : Ordinal) → X ∋ ord→od y₁ → ψ (ord→od y₁)) ∧ (X ∋ ord→od y) | |
| 115 | 261 lemma {x} select {y} y<x = record { proj1 = proj1 select ; proj2 = y<X } where |
| 262 y<X : X ∋ ord→od y | |
| 263 y<X = otrans X (proj2 select) (o<-subst y<x (sym diso) (sym diso) ) | |
| 112 | 264 _,_ : HOD {suc n} → HOD {suc n} → HOD {suc n} |
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265 x , y = Ord (omax (od→ord x) (od→ord y)) |
| 112 | 266 Union : HOD {suc n} → HOD {suc n} |
| 113 | 267 Union U = cseq U |
| 77 | 268 -- power : ∀ X ∃ A ∀ t ( t ∈ A ↔ ( ∀ {x} → t ∋ x → X ∋ x ) |
| 112 | 269 Power : HOD {suc n} → HOD {suc n} |
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270 Power A = Def A |
| 112 | 271 ZFSet = HOD {suc n} |
| 54 | 272 _∈_ : ( A B : ZFSet ) → Set (suc n) |
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273 A ∈ B = B ∋ A |
| 54 | 274 _⊆_ : ( A B : ZFSet ) → ∀{ x : ZFSet } → Set (suc n) |
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275 _⊆_ A B {x} = A ∋ x → B ∋ x |
| 103 | 276 _∩_ : ( A B : ZFSet ) → ZFSet |
| 115 | 277 A ∩ B = Select (A , B) ( λ x → ( A ∋ x ) ∧ (B ∋ x) ) |
| 96 | 278 -- _∪_ : ( A B : ZFSet ) → ZFSet |
| 279 -- A ∪ B = Select (A , B) ( λ x → (A ∋ x) ∨ ( B ∋ x ) ) | |
| 103 | 280 {_} : ZFSet → ZFSet |
| 281 { x } = ( x , x ) | |
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282 |
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283 infixr 200 _∈_ |
| 96 | 284 -- infixr 230 _∩_ _∪_ |
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285 infixr 220 _⊆_ |
| 112 | 286 isZF : IsZF (HOD {suc n}) _∋_ _==_ od∅ _,_ Union Power Select Replace (Ord omega) |
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287 isZF = record { |
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288 isEquivalence = record { refl = eq-refl ; sym = eq-sym; trans = eq-trans } |
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289 ; pair = pair |
| 118 | 290 ; union-u = λ X z UX∋z → union-u {X} {z} UX∋z |
| 72 | 291 ; union→ = union→ |
| 292 ; union← = union← | |
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293 ; empty = empty |
| 76 | 294 ; power→ = power→ |
| 295 ; power← = power← | |
| 296 ; extensionality = extensionality | |
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297 ; minimul = minimul |
| 51 | 298 ; regularity = regularity |
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299 ; infinity∅ = infinity∅ |
| 93 | 300 ; infinity = λ _ → infinity |
| 116 | 301 ; selection = λ {X} {ψ} {y} → selection {X} {ψ} {y} |
| 93 | 302 ; replacement = replacement |
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303 } where |
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304 open _∧_ |
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305 open Minimumo |
| 112 | 306 pair : (A B : HOD {suc n} ) → ((A , B) ∋ A) ∧ ((A , B) ∋ B) |
| 87 | 307 proj1 (pair A B ) = omax-x {n} (od→ord A) (od→ord B) |
| 308 proj2 (pair A B ) = omax-y {n} (od→ord A) (od→ord B) | |
| 112 | 309 empty : (x : HOD {suc n} ) → ¬ (od∅ ∋ x) |
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310 empty x (case1 ()) |
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311 empty x (case2 ()) |
| 100 | 312 --- |
| 313 --- ZFSubset A x = record { def = λ y → def A y ∧ def x y } subset of A | |
| 314 --- Power X = ord→od ( sup-o ( λ x → od→ord ( ZFSubset A (ord→od x )) ) ) Power X is a sup of all subset of A | |
| 315 -- | |
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316 -- if Power A ∋ t, from a propertiy of minimum sup there is osuc ZFSubset A ∋ t |
| 100 | 317 -- then ZFSubset A ≡ t or ZFSubset A ∋ t. In the former case ZFSubset A ∋ x implies A ∋ x |
| 318 -- In case of later, ZFSubset A ∋ t and t ∋ x implies ZFSubset A ∋ x by transitivity | |
| 319 -- | |
| 112 | 320 power→ : (A t : HOD) → Power A ∋ t → {x : HOD} → t ∋ x → A ∋ x |
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321 power→ A t P∋t {x} t∋x = proj1 lemma-s where |
| 112 | 322 minsup : HOD |
| 121 | 323 minsup = ZFSubset A ( Ord ( sup-x (λ x → od→ord ( ZFSubset A (ord→od x))))) |
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324 lemma-t : csuc minsup ∋ t |
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325 lemma-t = {!!} -- o<→c< (o<-subst (sup-lb (o<-subst (c<→o< P∋t) refl diso )) refl refl ) |
| 121 | 326 lemma-s : ZFSubset A ( Ord ( sup-x (λ x → od→ord ( ZFSubset A (ord→od x))))) ∋ x |
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327 lemma-s with osuc-≡< ( o<-subst (c<→o< lemma-t ) refl diso ) |
| 121 | 328 lemma-s | case1 eq = {!!} |
| 329 lemma-s | case2 lt = transitive {n} {minsup} {t} {x} {!!} t∋x | |
| 100 | 330 -- |
| 331 -- we have t ∋ x → A ∋ x means t is a subset of A, that is ZFSubset A t == t | |
| 332 -- Power A is a sup of ZFSubset A t, so Power A ∋ t | |
| 333 -- | |
| 112 | 334 power← : (A t : HOD) → ({x : HOD} → (t ∋ x → A ∋ x)) → Power A ∋ t |
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335 power← A t t→A = def-subst {suc n} {_} {_} {Power A} {od→ord t} |
| 103 | 336 {!!} refl lemma1 where |
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337 lemma-eq : ZFSubset A t == t |
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338 eq→ lemma-eq {z} w = proj2 w |
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339 eq← lemma-eq {z} w = record { proj2 = w ; |
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340 proj1 = def-subst {suc n} {_} {_} {A} {z} ( t→A (def-subst {suc n} {_} {_} {t} {od→ord (ord→od z)} w refl (sym diso) )) refl diso } |
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341 lemma1 : od→ord (ZFSubset A (ord→od (od→ord t))) ≡ od→ord t |
| 111 | 342 lemma1 = subst (λ k → od→ord (ZFSubset A k) ≡ od→ord t ) (sym oiso) {!!} |
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343 lemma : od→ord (ZFSubset A (ord→od (od→ord t)) ) o< sup-o (λ x → od→ord (ZFSubset A (ord→od x))) |
| 98 | 344 lemma = sup-o< |
| 118 | 345 union-u : {X z : HOD {suc n}} → (U>z : Union X ∋ z ) → HOD {suc n} |
| 346 union-u {X} {z} U>z = Ord ( osuc ( od→ord z ) ) | |
| 112 | 347 union→ : (X z u : HOD) → (X ∋ u) ∧ (u ∋ z) → Union X ∋ z |
| 118 | 348 union→ X z u xx with trio< ( od→ord u ) ( osuc ( od→ord z )) |
| 349 union→ X z u xx | tri< a ¬b ¬c with osuc-< a (c<→o< (proj2 xx)) | |
| 350 union→ X z u xx | tri< a ¬b ¬c | () | |
| 351 union→ X z u xx | tri≈ ¬a b ¬c = def-subst {suc n} {_} {_} {X} {osuc (od→ord z)} (proj1 xx) refl b where | |
| 352 union→ X z u xx | tri> ¬a ¬b c = otrans X (proj1 xx) c | |
| 353 union← : (X z : HOD) (X∋z : Union X ∋ z) → (X ∋ union-u {X} {z} X∋z ) ∧ (union-u {X} {z} X∋z ∋ z ) | |
| 354 union← X z X∋z = record { proj1 = lemma ; proj2 = <-osuc } where | |
| 355 lemma : X ∋ union-u {X} {z} X∋z | |
| 356 lemma = def-subst {suc n} {_} {_} {X} {od→ord (Ord (osuc ( od→ord z )))} X∋z refl ord-Ord | |
| 112 | 357 ψiso : {ψ : HOD {suc n} → Set (suc n)} {x y : HOD {suc n}} → ψ x → x ≡ y → ψ y |
| 54 | 358 ψiso {ψ} t refl = t |
| 116 | 359 selection : {X : HOD } {ψ : (x : HOD ) → Set (suc n)} {y : HOD} → (((y₁ : HOD) → X ∋ y₁ → ψ y₁) ∧ (X ∋ y)) ⇔ (Select X ψ ∋ y) |
| 115 | 360 selection {X} {ψ} {y} = record { proj1 = λ s → record { |
| 116 | 361 proj1 = λ y1 y1<X → proj1 s (ord→od y1) y1<X ; proj2 = subst (λ k → def X k ) (sym diso) (proj2 s) } |
| 362 ; proj2 = λ s → record { proj1 = λ y1 dy1 → subst (λ k → ψ k ) oiso ((proj1 s) (od→ord y1) (def-subst {suc n} {_} {_} {X} {_} dy1 refl (sym diso ))) | |
| 363 ; proj2 = def-subst {suc n} {_} {_} {X} {od→ord y} (proj2 s ) refl diso } } where | |
| 112 | 364 replacement : {ψ : HOD → HOD} (X x : HOD) → Replace X ψ ∋ ψ x |
| 93 | 365 replacement {ψ} X x = sup-c< ψ {x} |
| 112 | 366 ∅-iso : {x : HOD} → ¬ (x == od∅) → ¬ ((ord→od (od→ord x)) == od∅) |
| 60 | 367 ∅-iso {x} neq = subst (λ k → ¬ k) (=-iso {n} ) neq |
| 112 | 368 regularity : (x : HOD) (not : ¬ (x == od∅)) → |
| 115 | 369 (x ∋ minimul x not) ∧ (Select (minimul x not) (λ x₁ → (minimul x not ∋ x₁) ∧ (x ∋ x₁)) == od∅) |
| 117 | 370 proj1 (regularity x not ) = x∋minimul x not |
| 371 proj2 (regularity x not ) = record { eq→ = lemma1 ; eq← = λ {y} d → lemma2 {y} d } where | |
| 372 lemma1 : {x₁ : Ordinal} → def (Select (minimul x not) (λ x₂ → (minimul x not ∋ x₂) ∧ (x ∋ x₂))) x₁ → def od∅ x₁ | |
| 373 lemma1 {x₁} s = ⊥-elim ( minimul-1 x not (ord→od x₁) lemma3 ) where | |
| 374 lemma3 : def (minimul x not) (od→ord (ord→od x₁)) ∧ def x (od→ord (ord→od x₁)) | |
| 375 lemma3 = proj1 s x₁ (proj2 s) | |
| 376 lemma2 : {x₁ : Ordinal} → def od∅ x₁ → def (Select (minimul x not) (λ x₂ → (minimul x not ∋ x₂) ∧ (x ∋ x₂))) x₁ | |
| 377 lemma2 {y} d = ⊥-elim (empty (ord→od y) (def-subst {suc n} {_} {_} {od∅} {od→ord (ord→od y)} d refl (sym diso) )) | |
| 112 | 378 extensionality : {A B : HOD {suc n}} → ((z : HOD) → (A ∋ z) ⇔ (B ∋ z)) → A == B |
| 76 | 379 eq→ (extensionality {A} {B} eq ) {x} d = def-iso {suc n} {A} {B} (sym diso) (proj1 (eq (ord→od x))) d |
| 380 eq← (extensionality {A} {B} eq ) {x} d = def-iso {suc n} {B} {A} (sym diso) (proj2 (eq (ord→od x))) d | |
| 119 | 381 open import Relation.Binary.PropositionalEquality |
| 382 uxxx-ord : {x : HOD {suc n}} → {y : Ordinal {suc n}} → def (Union (x , (x , x))) y ⇔ ( y o< osuc (od→ord x) ) | |
| 383 uxxx-ord {x} {y} = subst (λ k → k ⇔ ( y o< osuc (od→ord x) )) (sym lemma) ( osuc2 y (od→ord x)) where | |
| 384 lemma : {y : Ordinal {suc n}} → def (Union (x , (x , x))) y ≡ osuc y o< osuc (osuc (od→ord x)) | |
| 385 lemma {y} = let open ≡-Reasoning in begin | |
| 386 def (Union (x , (x , x))) y | |
| 387 ≡⟨⟩ | |
| 388 def ( Ord ( omax (od→ord x) (od→ord (Ord (omax (od→ord x) (od→ord x) )) ))) ( osuc y ) | |
| 389 ≡⟨⟩ | |
| 390 osuc y o< omax (od→ord x) (od→ord (Ord (omax (od→ord x) (od→ord x) )) ) | |
| 391 ≡⟨ cong (λ k → osuc y o< omax (od→ord x) k ) (sym ord-Ord) ⟩ | |
| 392 osuc y o< omax (od→ord x) (omax (od→ord x) (od→ord x) ) | |
| 393 ≡⟨ cong (λ k → osuc y o< k ) (omxxx (od→ord x) ) ⟩ | |
| 394 osuc y o< osuc (osuc (od→ord x)) | |
| 395 ∎ | |
| 112 | 396 infinite : HOD {suc n} |
| 111 | 397 infinite = Ord omega |
| 398 infinity∅ : Ord omega ∋ od∅ {suc n} | |
| 119 | 399 infinity∅ = o<-subst (case1 (s≤s z≤n) ) ord-Ord refl |
| 112 | 400 infinity : (x : HOD) → infinite ∋ x → infinite ∋ Union (x , (x , x )) |
| 120 | 401 infinity x lt = o<-subst ( lemma (od→ord x) lt ) eq refl where |
| 402 eq : osuc (od→ord x) ≡ od→ord (Union (x , (x , x))) | |
| 403 eq = let open ≡-Reasoning in begin | |
| 404 osuc (od→ord x) | |
| 405 ≡⟨ ord-Ord ⟩ | |
| 406 od→ord (Ord (osuc (od→ord x))) | |
| 407 ≡⟨ cong ( λ k → od→ord k ) ( sym (==→o≡ ( ⇔→== uxxx-ord ))) ⟩ | |
| 408 od→ord (Union (x , (x , x))) | |
| 409 ∎ | |
| 91 | 410 lemma : (ox : Ordinal {suc n} ) → ox o< omega → osuc ox o< omega |
| 411 lemma record { lv = Zero ; ord = (Φ .0) } (case1 (s≤s x)) = case1 (s≤s z≤n) | |
| 412 lemma record { lv = Zero ; ord = (OSuc .0 ord₁) } (case1 (s≤s x)) = case1 (s≤s z≤n) | |
| 413 lemma record { lv = (Suc lv₁) ; ord = (Φ .(Suc lv₁)) } (case1 (s≤s ())) | |
| 414 lemma record { lv = (Suc lv₁) ; ord = (OSuc .(Suc lv₁) ord₁) } (case1 (s≤s ())) | |
| 415 lemma record { lv = 1 ; ord = (Φ 1) } (case2 c2) with d<→lv c2 | |
| 416 lemma record { lv = (Suc Zero) ; ord = (Φ .1) } (case2 ()) | refl | |
| 103 | 417 -- ∀ X [ ∅ ∉ X → (∃ f : X → ⋃ X ) → ∀ A ∈ X ( f ( A ) ∈ A ) ] -- this form is no good since X is a transitive set |
| 418 -- ∀ z [ ∀ x ( x ∈ z → ¬ ( x ≈ ∅ ) ) ∧ ∀ x ∀ y ( x , y ∈ z ∧ ¬ ( x ≈ y ) → x ∩ y ≈ ∅ ) → ∃ u ∀ x ( x ∈ z → ∃ t ( u ∩ x) ≈ { t }) ] | |
| 112 | 419 record Choice (z : HOD {suc n}) : Set (suc (suc n)) where |
| 103 | 420 field |
| 112 | 421 u : {x : HOD {suc n}} ( x∈z : x ∈ z ) → HOD {suc n} |
| 422 t : {x : HOD {suc n}} ( x∈z : x ∈ z ) → (x : HOD {suc n} ) → HOD {suc n} | |
| 423 choice : { x : HOD {suc n} } → ( x∈z : x ∈ z ) → ( u x∈z ∩ x) == { t x∈z x } | |
| 424 -- choice : {x : HOD {suc n}} ( x ∈ z → ¬ ( x ≈ ∅ ) ) → | |
| 425 -- axiom-of-choice : { X : HOD } → ( ¬x∅ : ¬ ( X == od∅ ) ) → { A : HOD } → (A∈X : A ∈ X ) → choice ¬x∅ A∈X ∈ A | |
| 103 | 426 -- axiom-of-choice {X} nx {A} lt = ¬∅=→∅∈ {!!} |
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Shinji KONO <kono@ie.u-ryukyu.ac.jp>
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