Proof of Nuprl Lemma : pa-inv

Step * 2 1 1 1 of Lemma pa-inv_wf

.....set predicate.....
1. p : {p:{2...}| prime(p)}
2. n : ℕ
3. x1 : if (n =_z 0) then p-adics(p) else p-units(p) fi
4. ¬(n = 0 ∈ ℤ)
5. u : p-units(p)
6. x1 = u ∈ p-units(p)
7. v : p-adics(p)
8. u * v = 1(p) ∈ p-adics(p)
⊢ pa-mul(p;<n, u>;<0, p^n(p) * v>) = 1(p) ∈ padic(p)
BY

{ ((Assert ⌜pa-mul(p;<n, u>;<0, p^n(p) * v>) = bpa-norm(p;1(p)) ∈ padic(p)⌝⋅ THENM (NthHypEqTrans (-1) THEN Auto))

THEN Unfold `pa-mul` 0
THEN (BLemma `bpa-equiv-iff-norm2` THENA Auto)) }

1
1. p : {p:{2...}| prime(p)}
2. n : ℕ
3. x1 : if (n =_z 0) then p-adics(p) else p-units(p) fi
4. ¬(n = 0 ∈ ℤ)
5. u : p-units(p)
6. x1 = u ∈ p-units(p)
7. v : p-adics(p)
8. u * v = 1(p) ∈ p-adics(p)
⊢ bpa-equiv(p;bpa-mul(p;<n, u>;<0, p^n(p) * v>);1(p))

Latex:

Latex:
.....set predicate..... 1. p : \{p:\{2...\}| prime(p)\} 2. n : \mBbbN{} 3. x1 : if (n =\msubz{} 0) then p-adics(p) else p-units(p) fi 4. \mneg{}(n = 0) 5. u : p-units(p) 6. x1 = u 7. v : p-adics(p) 8. u * v = 1(p) \mvdash{} pa-mul(p;<n, u>ɘ, p\^{}n(p) * v>) = 1(p) By Latex: ((Assert \mkleeneopen{}pa-mul(p;<n, u>ɘ, p\^{}n(p) * v>) = bpa-norm(p;1(p))\mkleeneclose{}\mcdot{} THENM (NthHypEqTrans (-1) THEN Auto)\000C) THEN Unfold `pa-mul` 0 THEN (BLemma `bpa-equiv-iff-norm2` THENA Auto)) Home Index