Proof of Nuprl Lemma : flip-conjugate-rotate

Step * 1 1 2 2 of Lemma flip-conjugate-rotate

1. n : ℕ
2. i : ℕn - 1
3. i ∈ ℕn
4. i + 1 ∈ ℕn
5. x : ℕn
6. x ≠ i + 1
7. rot(n)^i = (λx.if x + i <z n then x + i else (x + i) - n fi ) ∈ (ℕn ⟶ ℕn)

8. rot(n)^n - i = (λx.if x + (n - i) <z n then x + (n - i) else (x + (n - i)) - n fi ) ∈ (ℕn ⟶ ℕn)

9. ¬(x = i ∈ ℤ)
10. x + (n - i) < n
⊢ x = (rot(n)^i (x + (n - i))) ∈ ℕn
BY
{ ApFunToHypEquands `Z' ⌜Z (x + (n - i))⌝ ⌜ℕn⌝ 7⋅ }

1
.....fun wf.....
1. n : ℕ
2. i : ℕn - 1
3. i ∈ ℕn
4. i + 1 ∈ ℕn
5. x : ℕn
6. x ≠ i + 1
7. rot(n)^i = (λx.if x + i <z n then x + i else (x + i) - n fi ) ∈ (ℕn ⟶ ℕn)

8. rot(n)^n - i = (λx.if x + (n - i) <z n then x + (n - i) else (x + (n - i)) - n fi ) ∈ (ℕn ⟶ ℕn)

9. ¬(x = i ∈ ℤ)
10. x + (n - i) < n
11. Z : ℕn ⟶ ℕn
⊢ (Z (x + (n - i))) = (Z (x + (n - i))) ∈ ℕn

2
1. n : ℕ
2. i : ℕn - 1
3. i ∈ ℕn
4. i + 1 ∈ ℕn
5. x : ℕn
6. x ≠ i + 1
7. rot(n)^i = (λx.if x + i <z n then x + i else (x + i) - n fi ) ∈ (ℕn ⟶ ℕn)

8. rot(n)^n - i = (λx.if x + (n - i) <z n then x + (n - i) else (x + (n - i)) - n fi ) ∈ (ℕn ⟶ ℕn)

9. ¬(x = i ∈ ℤ)
10. x + (n - i) < n

11. (rot(n)^i (x + (n - i))) = ((λx.if x + i <z n then x + i else (x + i) - n fi ) (x + (n - i))) ∈ ℕn

⊢ x = (rot(n)^i (x + (n - i))) ∈ ℕn

Latex:

Latex:
1. n : \mBbbN{} 2. i : \mBbbN{}n - 1 3. i \mmember{} \mBbbN{}n 4. i + 1 \mmember{} \mBbbN{}n 5. x : \mBbbN{}n 6. x \mneq{} i + 1 7. rot(n)\^{}i = (\mlambda{}x.if x + i <z n then x + i else (x + i) - n fi ) 8. rot(n)\^{}n - i = (\mlambda{}x.if x + (n - i) <z n then x + (n - i) else (x + (n - i)) - n fi ) 9. \mneg{}(x = i) 10. x + (n - i) < n \mvdash{} x = (rot(n)\^{}i (x + (n - i))) By Latex: ApFunToHypEquands `Z' \mkleeneopen{}Z (x + (n - i))\mkleeneclose{} \mkleeneopen{}\mBbbN{}n\mkleeneclose{} 7\mcdot{} Home Index