Proof of Nuprl Lemma : fset-closure-exists

Step * 1 1 2 2 2 1 of Lemma fset-closure-exists

1. T : Type
2. eq : EqDecider(T)
3. r : T ⟶ ℕ
4. fs : (T ⟶ T) List
5. (∀f∈fs.∀x:T. ((¬((f x) = x ∈ T)) ⇒ r (f x) < r x))
6. ∀x,y:T. Dec(x = y ∈ T)
7. n : ℤ
8. 0 < n
9. ∀s:fset(T). ((∀x:T. (x ∈ s ⇒ ((r x) ≤ (n - 1)))) ⇒ (∃c:fset(T). (c = fs closure of s)))
10. s : fset(T)
11. ∀x:T. (x ∈ s ⇒ ((r x) ≤ n))
12. x : T

13. ∃s1:fset(T). ((s1 ∈ map(λf.f"({x ∈ s | (r x =_z n) ∧_b (¬_b(eq (f x) x))});fs)) ∧ x ∈ s1)

⊢ (r x) ≤ (n - 1)
BY
{ (D (-1) THEN (RWO "member_map" (-1) THENA Auto)) }

1
1. T : Type
2. eq : EqDecider(T)
3. r : T ⟶ ℕ
4. fs : (T ⟶ T) List
5. (∀f∈fs.∀x:T. ((¬((f x) = x ∈ T)) ⇒ r (f x) < r x))
6. ∀x,y:T. Dec(x = y ∈ T)
7. n : ℤ
8. 0 < n
9. ∀s:fset(T). ((∀x:T. (x ∈ s ⇒ ((r x) ≤ (n - 1)))) ⇒ (∃c:fset(T). (c = fs closure of s)))
10. s : fset(T)
11. ∀x:T. (x ∈ s ⇒ ((r x) ≤ n))
12. x : T
13. s1 : fset(T)

14. (∃y:T ⟶ T. ((y ∈ fs) ∧ (s1 = ((λf.f"({x ∈ s | (r x =_z n) ∧_b (¬_b(eq (f x) x))})) y) ∈ fset(T)))) ∧ x ∈ s1

⊢ (r x) ≤ (n - 1)

Latex:

Latex:
1. T : Type 2. eq : EqDecider(T) 3. r : T {}\mrightarrow{} \mBbbN{} 4. fs : (T {}\mrightarrow{} T) List 5. (\mforall{}f\mmember{}fs.\mforall{}x:T. ((\mneg{}((f x) = x)) {}\mRightarrow{} r (f x) < r x)) 6. \mforall{}x,y:T. Dec(x = y) 7. n : \mBbbZ{} 8. 0 < n 9. \mforall{}s:fset(T). ((\mforall{}x:T. (x \mmember{} s {}\mRightarrow{} ((r x) \mleq{} (n - 1)))) {}\mRightarrow{} (\mexists{}c:fset(T). (c = fs closure of s))) 10. s : fset(T) 11. \mforall{}x:T. (x \mmember{} s {}\mRightarrow{} ((r x) \mleq{} n)) 12. x : T 13. \mexists{}s1:fset(T). ((s1 \mmember{} map(\mlambda{}f.f"(\{x \mmember{} s | (r x =\msubz{} n) \mwedge{}\msubb{} (\mneg{}\msubb{}(eq (f x) x))\});fs)) \mwedge{} x \mmember{} s1) \mvdash{} (r x) \mleq{} (n - 1) By Latex: (D (-1) THEN (RWO "member\_map" (-1) THENA Auto)) Home Index