Proof of Nuprl Lemma : partial-int-not-discrete

Step * 1 1 1 1 2 1 1 of Lemma partial-int-not-discrete

1. ∀k:ℕ. (λx.(fix((λf,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) k) ∈ ℝ ⟶ partial(ℤ))

2. λx.(fix((λf,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) 0) ∈ ℝ ⟶ partial(ℤ)
3. x : ℝ
4. y : ℝ
5. x = y
6. ∀x:ℝ. ((r0 < |x|) ⇒ ((λx.(fix((λf,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) 0)) x ~ 1))
7. x1 : ℝ
8. ((λx.(fix((λf,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) 0)) x1)↓
⊢ r0 < |x1|
BY
{ (Reduce -1

   THEN (Assert λf,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi  ∈ (ℕ ⟶ partial(ℤ)) ⟶ ℕ ⟶ partial(ℤ) BY

Auto)

   THEN (Assert ∀j,k:ℕ.  (λf,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi ^j ⊥ k ∈ partial(ℤ)) BY

Auto)

   THEN (Assert ⌜∀k:ℕ. ((fix((λf,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi )) k)↓

⇒ (r0 < |x1|))⌝⋅
THENM (InstHyp [⌜0⌝] (-1)⋅ THEN Auto)
)) }

1
.....assertion.....

1. ∀k:ℕ. (λx.(fix((λf,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) k) ∈ ℝ ⟶ partial(ℤ))

2. λx.(fix((λf,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) 0) ∈ ℝ ⟶ partial(ℤ)
3. x : ℝ
4. y : ℝ
5. x = y
6. ∀x:ℝ. ((r0 < |x|) ⇒ ((λx.(fix((λf,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) 0)) x ~ 1))
7. x1 : ℝ
8. (fix((λf,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi )) 0)↓

9. λf,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi  ∈ (ℕ ⟶ partial(ℤ)) ⟶ ℕ ⟶ partial(ℤ)

10. ∀j,k:ℕ. (λf,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi ^j ⊥ k ∈ partial(ℤ))
⊢ ∀k:ℕ. ((fix((λf,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi )) k)↓ ⇒ (r0 < |x1|))

Latex:

Latex:
1. \mforall{}k:\mBbbN{}. (\mlambda{}x.(fix((\mlambda{}f,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) k) \mmember{} \mBbbR{} {}\mrightarrow{} partial(\mBbbZ{})) 2. \mlambda{}x.(fix((\mlambda{}f,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) 0) \mmember{} \mBbbR{} {}\mrightarrow{} partial(\mBbbZ{}) 3. x : \mBbbR{} 4. y : \mBbbR{} 5. x = y 6. \mforall{}x:\mBbbR{}. ((r0 < |x|) {}\mRightarrow{} ((\mlambda{}x.(fix((\mlambda{}f,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) 0)) x \msim{} 1)) 7. x1 : \mBbbR{} 8. ((\mlambda{}x.(fix((\mlambda{}f,n. if 4 <z |x (n + 1)| then 1 else f (n + 1) fi )) 0)) x1)\mdownarrow{} \mvdash{} r0 < |x1| By Latex: (Reduce -1 THEN (Assert \mlambda{}f,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi \mmember{} (\mBbbN{} {}\mrightarrow{} partial(\mBbbZ{})) {}\mrightarrow{} \mBbbN{} {}\mrightarrow{} partial(\mBbbZ{}) BY Auto) THEN (Assert \mforall{}j,k:\mBbbN{}. (\mlambda{}f,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi \^{}j \mbot{} k \mmember{} partial(\mBbbZ{})) BY Auto) THEN (Assert \mkleeneopen{}\mforall{}k:\mBbbN{}. ((fix((\mlambda{}f,n. if 4 <z |x1 (n + 1)| then 1 else f (n + 1) fi )) k)\mdownarrow{} {}\mRightarrow{} (r0 < |x1|\000C))\mkleeneclose{}\mcdot{} THENM (InstHyp [\mkleeneopen{}0\mkleeneclose{}] (-1)\mcdot{} THEN Auto) )) Home Index