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

Step * 1 1 2 1 1 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. (fix((λf,n. if 4 <z |r0 (n + 1)| then 1 else f (n + 1) fi )) 0) = 1 ∈ partial(ℤ)
3. j : ℕ
⊢ λf,n. if 4 <z |r0 (n + 1)| then 1 else f (n + 1) fi ^j ⊥ 0 ≤ ⊥
BY

{ (Assert ⌜∀t:ℕ. (λf,n. if 4 <z |r0 (n + 1)| then 1 else f (n + 1) fi ^j ⊥ t ≤ ⊥)⌝⋅ THENM (BHyp -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. (fix((λf,n. if 4 <z |r0 (n + 1)| then 1 else f (n + 1) fi )) 0) = 1 ∈ partial(ℤ)
3. j : ℕ
⊢ ∀t:ℕ. (λf,n. if 4 <z |r0 (n + 1)| then 1 else f (n + 1) fi ^j ⊥ t ≤ ⊥)

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. (fix((\mlambda{}f,n. if 4 <z |r0 (n + 1)| then 1 else f (n + 1) fi )) 0) = 1 3. j : \mBbbN{} \mvdash{} \mlambda{}f,n. if 4 <z |r0 (n + 1)| then 1 else f (n + 1) fi \^{}j \mbot{} 0 \mleq{} \mbot{} By Latex: (Assert \mkleeneopen{}\mforall{}t:\mBbbN{}. (\mlambda{}f,n. if 4 <z |r0 (n + 1)| then 1 else f (n + 1) fi \^{}j \mbot{} t \mleq{} \mbot{})\mkleeneclose{}\mcdot{} THENM (BHyp -1 THEN Auto) ) Home Index