Proof of Nuprl Lemma : det-kI+J

Step * 1 2 1 1 2 2 of Lemma det-kI+J

.....subterm..... T:t
3:n
1. r : CRng
2. n : ℤ
3. 0 < n
4. a : |r|
5. ¬(n = 1 ∈ ℤ)
6. |matrix(if x=n - 1
           then 1 +r if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y]
           else if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])|
= (|matrix(if x=n - 1 then 1 else if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])|
   +r
   |matrix(if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])|)
∈ |r|

⊢ (a ↑r (n - 1)) = |matrix(if x=n - 1 then 1 else if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])| ∈ |r|

BY
{ Thin (-1) }

1
1. r : CRng
2. n : ℤ
3. 0 < n
4. a : |r|
5. ¬(n = 1 ∈ ℤ)

⊢ (a ↑r (n - 1)) = |matrix(if x=n - 1 then 1 else if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])| ∈ |r|

Latex:

Latex:
.....subterm..... T:t 3:n 1. r : CRng 2. n : \mBbbZ{} 3. 0 < n 4. a : |r| 5. \mneg{}(n = 1) 6. |matrix(if x=n - 1 then 1 +r if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y] else if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])| = (|matrix(if x=n - 1 then 1 else if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])| +r |matrix(if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])|) \mvdash{} (a \muparrow{}r (n - 1)) = |matrix(if x=n - 1 then 1 else if x=n - 1 then if y=n - 1 then a else 0 else a*I + J[x,y])| By Latex: Thin (-1) Home Index