Proof of Nuprl Lemma : rnexp-req

Step * 2 1 1 1 1 of Lemma rnexp-req

1. k : {2...}
2. x : ℝ
3. B : ℕ
4. (canon-bnd(x)^(k - 1 - 1) ÷ 2^(k - 1 - 1)) = B ∈ ℕ
5. BB : ℕ⁺
6. (((k - 1) * (B + 1)) + 1) = BB ∈ ℕ⁺
7. A : ℕ
8. (canon-bnd(x)^(k - 1) ÷ 2^(k - 1)) = A ∈ ℕ
9. AA : ℕ⁺
10. ((k * (A + 1)) + 1) = AA ∈ ℕ⁺
11. v : {f:ℕ⁺ ⟶ ℤ| AA-regular-seq(f)}
12. reg-seq-nexp(x;k) = v ∈ {f:ℕ⁺ ⟶ ℤ| AA-regular-seq(f)}
13. v@0 : {f:ℕ⁺ ⟶ ℤ| BB-regular-seq(f)}
14. reg-seq-nexp(x;k - 1) = v@0 ∈ {f:ℕ⁺ ⟶ ℤ| BB-regular-seq(f)}
⊢ bdd-diff(accelerate(AA;v);reg-seq-mul(x;accelerate(BB;v@0)))
BY
{ (RW (AddrC [1] (LemmaC `accelerate-bdd-diff`)) 0 THENA Try (Complete (Auto)))⋅ }

1
1. k : {2...}
2. x : ℝ
3. B : ℕ
4. (canon-bnd(x)^(k - 1 - 1) ÷ 2^(k - 1 - 1)) = B ∈ ℕ
5. BB : ℕ⁺
6. (((k - 1) * (B + 1)) + 1) = BB ∈ ℕ⁺
7. A : ℕ
8. (canon-bnd(x)^(k - 1) ÷ 2^(k - 1)) = A ∈ ℕ
9. AA : ℕ⁺
10. ((k * (A + 1)) + 1) = AA ∈ ℕ⁺
11. v : {f:ℕ⁺ ⟶ ℤ| AA-regular-seq(f)}
12. reg-seq-nexp(x;k) = v ∈ {f:ℕ⁺ ⟶ ℤ| AA-regular-seq(f)}
13. v@0 : {f:ℕ⁺ ⟶ ℤ| BB-regular-seq(f)}
14. reg-seq-nexp(x;k - 1) = v@0 ∈ {f:ℕ⁺ ⟶ ℤ| BB-regular-seq(f)}
⊢ bdd-diff(v;reg-seq-mul(x;accelerate(BB;v@0)))

Latex:

Latex:
1. k : \{2...\} 2. x : \mBbbR{} 3. B : \mBbbN{} 4. (canon-bnd(x)\^{}(k - 1 - 1) \mdiv{} 2\^{}(k - 1 - 1)) = B 5. BB : \mBbbN{}\msupplus{} 6. (((k - 1) * (B + 1)) + 1) = BB 7. A : \mBbbN{} 8. (canon-bnd(x)\^{}(k - 1) \mdiv{} 2\^{}(k - 1)) = A 9. AA : \mBbbN{}\msupplus{} 10. ((k * (A + 1)) + 1) = AA 11. v : \{f:\mBbbN{}\msupplus{} {}\mrightarrow{} \mBbbZ{}| AA-regular-seq(f)\} 12. reg-seq-nexp(x;k) = v 13. v@0 : \{f:\mBbbN{}\msupplus{} {}\mrightarrow{} \mBbbZ{}| BB-regular-seq(f)\} 14. reg-seq-nexp(x;k - 1) = v@0 \mvdash{} bdd-diff(accelerate(AA;v);reg-seq-mul(x;accelerate(BB;v@0))) By Latex: (RW (AddrC [1] (LemmaC `accelerate-bdd-diff`)) 0 THENA Try (Complete (Auto)))\mcdot{} Home Index