Proof of Nuprl Lemma : binary-search

Step * 2 of Lemma binary-search_wf

1. d : ℤ
2. 0 < d
3. ∀a:ℤ. ∀b:{a + 1...}.
     (((b - a) ≤ (d - 1))
     ⇒ (∀f:{a..b + 1^-} ⟶ 𝔹
           binary-search(f;a;b) ∈ {x:{a..b^-}| (¬↑(f x)) ∧ (↑(f (x + 1)))}

           supposing ↓∃x:{a..b^-}. ((∀y:{a..x + 1^-}. (¬↑(f y))) ∧ (∀z:{x + 1..b + 1^-}. (↑(f z))))))

4. a : ℤ
5. b : {a + 1...}
6. (b - a) ≤ d
7. f : {a..b + 1^-} ⟶ 𝔹
8. ↓∃x:{a..b^-}. ((∀y:{a..x + 1^-}. (¬↑(f y))) ∧ (∀z:{x + 1..b + 1^-}. (↑(f z))))
9. ¬(b = (a + 1) ∈ ℤ)
⊢ eval c = a + ((b - a) ÷ 2) in

  if f c then binary-search(f;a;c) else binary-search(f;c;b) fi  ∈ {x:{a..b^-}| (¬↑(f x)) ∧ (↑(f (x + 1)))}

BY
{ Assert ⌜0 < (b - a) ÷ 2 ∧ (b - a) ÷ 2 < b - a⌝⋅ }

1
.....assertion.....
1. d : ℤ
2. 0 < d
3. ∀a:ℤ. ∀b:{a + 1...}.
     (((b - a) ≤ (d - 1))
     ⇒ (∀f:{a..b + 1^-} ⟶ 𝔹
           binary-search(f;a;b) ∈ {x:{a..b^-}| (¬↑(f x)) ∧ (↑(f (x + 1)))}

           supposing ↓∃x:{a..b^-}. ((∀y:{a..x + 1^-}. (¬↑(f y))) ∧ (∀z:{x + 1..b + 1^-}. (↑(f z))))))

4. a : ℤ
5. b : {a + 1...}
6. (b - a) ≤ d
7. f : {a..b + 1^-} ⟶ 𝔹
8. ↓∃x:{a..b^-}. ((∀y:{a..x + 1^-}. (¬↑(f y))) ∧ (∀z:{x + 1..b + 1^-}. (↑(f z))))
9. ¬(b = (a + 1) ∈ ℤ)
⊢ 0 < (b - a) ÷ 2 ∧ (b - a) ÷ 2 < b - a

2
1. d : ℤ
2. 0 < d
3. ∀a:ℤ. ∀b:{a + 1...}.
     (((b - a) ≤ (d - 1))
     ⇒ (∀f:{a..b + 1^-} ⟶ 𝔹
           binary-search(f;a;b) ∈ {x:{a..b^-}| (¬↑(f x)) ∧ (↑(f (x + 1)))}

           supposing ↓∃x:{a..b^-}. ((∀y:{a..x + 1^-}. (¬↑(f y))) ∧ (∀z:{x + 1..b + 1^-}. (↑(f z))))))

4. a : ℤ
5. b : {a + 1...}
6. (b - a) ≤ d
7. f : {a..b + 1^-} ⟶ 𝔹
8. ↓∃x:{a..b^-}. ((∀y:{a..x + 1^-}. (¬↑(f y))) ∧ (∀z:{x + 1..b + 1^-}. (↑(f z))))
9. ¬(b = (a + 1) ∈ ℤ)
10. 0 < (b - a) ÷ 2 ∧ (b - a) ÷ 2 < b - a
⊢ eval c = a + ((b - a) ÷ 2) in

  if f c then binary-search(f;a;c) else binary-search(f;c;b) fi  ∈ {x:{a..b^-}| (¬↑(f x)) ∧ (↑(f (x + 1)))}

Latex:

Latex:
1. d : \mBbbZ{} 2. 0 < d 3. \mforall{}a:\mBbbZ{}. \mforall{}b:\{a + 1...\}. (((b - a) \mleq{} (d - 1)) {}\mRightarrow{} (\mforall{}f:\{a..b + 1\msupminus{}\} {}\mrightarrow{} \mBbbB{} binary-search(f;a;b) \mmember{} \{x:\{a..b\msupminus{}\}| (\mneg{}\muparrow{}(f x)) \mwedge{} (\muparrow{}(f (x + 1)))\} supposing \mdownarrow{}\mexists{}x:\{a..b\msupminus{}\}. ((\mforall{}y:\{a..x + 1\msupminus{}\}. (\mneg{}\muparrow{}(f y))) \mwedge{} (\mforall{}z:\{x + 1..b + 1\msupminus{}\}. (\muparrow{}(f z)))))) 4. a : \mBbbZ{} 5. b : \{a + 1...\} 6. (b - a) \mleq{} d 7. f : \{a..b + 1\msupminus{}\} {}\mrightarrow{} \mBbbB{} 8. \mdownarrow{}\mexists{}x:\{a..b\msupminus{}\}. ((\mforall{}y:\{a..x + 1\msupminus{}\}. (\mneg{}\muparrow{}(f y))) \mwedge{} (\mforall{}z:\{x + 1..b + 1\msupminus{}\}. (\muparrow{}(f z)))) 9. \mneg{}(b = (a + 1)) \mvdash{} eval c = a + ((b - a) \mdiv{} 2) in if f c then binary-search(f;a;c) else binary-search(f;c;b) fi \mmember{} \{x:\{a..b\msupminus{}\}| (\mneg{}\muparrow{}(f x)) \mwedge{} (\muparrow{}(f (x + 1)))\} By Latex: Assert \mkleeneopen{}0 < (b - a) \mdiv{} 2 \mwedge{} (b - a) \mdiv{} 2 < b - a\mkleeneclose{}\mcdot{} Home Index