Proof of Nuprl Lemma : bpa-equiv-equiv

Step * 1 1 1 1 1 1 1 of Lemma bpa-equiv-equiv

1. p : {2...}
2. ℤ(p) ∈ RngSig
3. ∀[x,y,z:p-adics(p)]. (x + y + z = x + y + z ∈ p-adics(p))
4. ∀[x:p-adics(p)]. ((x + 0(p) = x ∈ p-adics(p)) ∧ (0(p) + x = x ∈ p-adics(p)))
5. ∀[x:p-adics(p)]. ((x + -(x) = 0(p) ∈ p-adics(p)) ∧ (-(x) + x = 0(p) ∈ p-adics(p)))
6. ∀[x,y,z:p-adics(p)]. (x * y * z = x * y * z ∈ p-adics(p))
7. ∀[x:p-adics(p)]. ((x * 1(p) = x ∈ p-adics(p)) ∧ (1(p) * x = x ∈ p-adics(p)))

8. ∀[a,x,y:p-adics(p)].  ((a * x + y = a * x + a * y ∈ p-adics(p)) ∧ (x + y * a = x * a + y * a ∈ p-adics(p)))

9. ∀[x,y:p-adics(p)].  (x * y = y * x ∈ p-adics(p))
10. Sym(basic-padic(p);x,y.let n,a = x
                           in let m,b = y
                              in p^m(p) * a = p^n(p) * b ∈ p-adics(p))
11. a1 : ℕ
12. a2 : p-adics(p)
13. b1 : ℕ
14. c1 : ℕ
15. c2 : p-adics(p)
16. v : p-adics(p)
17. p^c1(p) * a2 = v ∈ p-adics(p)
18. v1 : p-adics(p)
19. p^a1(p) * c2 = v1 ∈ p-adics(p)
20. p^b1(p) * v = p^b1(p) * v1 ∈ p-adics(p)
⊢ v = v1 ∈ p-adics(p)
BY
{ (FLemma `p-mul-int-cancelation-1` [-1] THEN Auto) }

Latex:

Latex:
1. p : \{2...\} 2. \mBbbZ{}(p) \mmember{} RngSig 3. \mforall{}[x,y,z:p-adics(p)]. (x + y + z = x + y + z) 4. \mforall{}[x:p-adics(p)]. ((x + 0(p) = x) \mwedge{} (0(p) + x = x)) 5. \mforall{}[x:p-adics(p)]. ((x + -(x) = 0(p)) \mwedge{} (-(x) + x = 0(p))) 6. \mforall{}[x,y,z:p-adics(p)]. (x * y * z = x * y * z) 7. \mforall{}[x:p-adics(p)]. ((x * 1(p) = x) \mwedge{} (1(p) * x = x)) 8. \mforall{}[a,x,y:p-adics(p)]. ((a * x + y = a * x + a * y) \mwedge{} (x + y * a = x * a + y * a)) 9. \mforall{}[x,y:p-adics(p)]. (x * y = y * x) 10. Sym(basic-padic(p);x,y.let n,a = x in let m,b = y in p\^{}m(p) * a = p\^{}n(p) * b) 11. a1 : \mBbbN{} 12. a2 : p-adics(p) 13. b1 : \mBbbN{} 14. c1 : \mBbbN{} 15. c2 : p-adics(p) 16. v : p-adics(p) 17. p\^{}c1(p) * a2 = v 18. v1 : p-adics(p) 19. p\^{}a1(p) * c2 = v1 20. p\^{}b1(p) * v = p\^{}b1(p) * v1 \mvdash{} v = v1 By Latex: (FLemma `p-mul-int-cancelation-1` [-1] THEN Auto) Home Index