Step
*
2
of Lemma
simple-comb2-classrel
1. Info : Type
2. A : Type
3. B : Type
4. C : Type
5. f : A ─→ B ─→ C
6. X : EClass(A)
7. Y : EClass(B)
8. es : EO+(Info)
9. e : E
10. v : C
11. ∀[es:EO+(Info)]. ∀[e:E]. ∀[v:C].
uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ ((λn.[A; B][n]) k)
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = ((λw.(f (w 0) (w 1))) vs) ∈ C)))
⊢ uiff(v ∈ λa,b.lifting2(f;a;b)|X;Y|(e);↓∃a:A. ∃b:B. ((a ∈ X(e) ∧ b ∈ Y(e)) ∧ (v = (f a b) ∈ C)))
BY
{ (RepUR ``simple-comb2`` 0 THEN Reduce (-1) THEN (InstHyp [⌈es⌉; ⌈e⌉; ⌈v⌉] (-1)⋅ THENA Auto) THEN D 0 THEN UnivCD) }
1
1. Info : Type
2. A : Type
3. B : Type
4. C : Type
5. f : A ─→ B ─→ C
6. X : EClass(A)
7. Y : EClass(B)
8. es : EO+(Info)
9. e : E
10. v : C
11. ∀[es:EO+(Info)]. ∀[e:E]. ∀[v:C].
uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ [A; B][k]
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = (f (vs 0) (vs 1)) ∈ C)))
12. uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ [A; B][k]
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = (f (vs 0) (vs 1)) ∈ C)))
13. v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λz.[X; Y][z])(e)
⊢ ↓∃a:A. ∃b:B. ((a ∈ X(e) ∧ b ∈ Y(e)) ∧ (v = (f a b) ∈ C))
2
.....wf.....
1. Info : Type
2. A : Type
3. B : Type
4. C : Type
5. f : A ─→ B ─→ C
6. X : EClass(A)
7. Y : EClass(B)
8. es : EO+(Info)
9. e : E
10. v : C
11. ∀[es:EO+(Info)]. ∀[e:E]. ∀[v:C].
uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ [A; B][k]
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = (f (vs 0) (vs 1)) ∈ C)))
12. uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ [A; B][k]
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = (f (vs 0) (vs 1)) ∈ C)))
⊢ v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λz.[X; Y][z])(e) ∈ ℙ
3
1. Info : Type
2. A : Type
3. B : Type
4. C : Type
5. f : A ─→ B ─→ C
6. X : EClass(A)
7. Y : EClass(B)
8. es : EO+(Info)
9. e : E
10. v : C
11. ∀[es:EO+(Info)]. ∀[e:E]. ∀[v:C].
uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ [A; B][k]
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = (f (vs 0) (vs 1)) ∈ C)))
12. uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ [A; B][k]
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = (f (vs 0) (vs 1)) ∈ C)))
13. ↓∃a:A. ∃b:B. ((a ∈ X(e) ∧ b ∈ Y(e)) ∧ (v = (f a b) ∈ C))
⊢ v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λz.[X; Y][z])(e)
4
.....wf.....
1. Info : Type
2. A : Type
3. B : Type
4. C : Type
5. f : A ─→ B ─→ C
6. X : EClass(A)
7. Y : EClass(B)
8. es : EO+(Info)
9. e : E
10. v : C
11. ∀[es:EO+(Info)]. ∀[e:E]. ∀[v:C].
uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ [A; B][k]
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = (f (vs 0) (vs 1)) ∈ C)))
12. uiff(v ∈ simple-comb(λw.lifting2(f;w 0;w 1);λn.[X; Y][n])(e);↓∃vs:k:ℕ2 ─→ [A; B][k]
((∀k:ℕ2. vs[k] ∈ λn.[X; Y][n][k](e))
∧ (v = (f (vs 0) (vs 1)) ∈ C)))
⊢ ↓∃a:A. ∃b:B. ((a ∈ X(e) ∧ b ∈ Y(e)) ∧ (v = (f a b) ∈ C)) ∈ ℙ
Latex:
Latex:
1. Info : Type
2. A : Type
3. B : Type
4. C : Type
5. f : A {}\mrightarrow{} B {}\mrightarrow{} C
6. X : EClass(A)
7. Y : EClass(B)
8. es : EO+(Info)
9. e : E
10. v : C
11. \mforall{}[es:EO+(Info)]. \mforall{}[e:E]. \mforall{}[v:C].
uiff(v \mmember{} simple-comb(\mlambda{}w.lifting2(f;w 0;w 1);\mlambda{}n.[X; Y][n])(e);\mdownarrow{}\mexists{}vs:k:\mBbbN{}2 {}\mrightarrow{} ((\mlambda{}n.[A; B][n]) k)
((\mforall{}k:\mBbbN{}2
vs[k] \mmember{} \mlambda{}n.[X; Y][n][k](e))
\mwedge{} (v
= ((\mlambda{}w.(f (w 0) (w 1)))
vs))))
\mvdash{} uiff(v \mmember{} \mlambda{}a,b.lifting2(f;a;b)|X;Y|(e);\mdownarrow{}\mexists{}a:A. \mexists{}b:B. ((a \mmember{} X(e) \mwedge{} b \mmember{} Y(e)) \mwedge{} (v = (f a b))))
By
Latex:
(RepUR ``simple-comb2`` 0
THEN Reduce (-1)
THEN (InstHyp [\mkleeneopen{}es\mkleeneclose{}; \mkleeneopen{}e\mkleeneclose{}; \mkleeneopen{}v\mkleeneclose{}] (-1)\mcdot{} THENA Auto)
THEN D 0
THEN UnivCD)
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