Proof of Nuprl Lemma : rational-IVT

Step * 1 2 1 2 2 6 1 1 of Lemma rational-IVT

1. a : ℝ
2. b : ℝ
3. f : (ℤ × ℕ⁺) ⟶ (ℤ × ℕ⁺)
4. g : {x:ℝ| x ∈ [a, b]}  ⟶ ℝ
5. (a < b)
∧ ((g[a] * g[b]) < r0)
∧ (∀x,y:{x:ℝ| x ∈ [a, b]} .  ((x = y) ⇒ (g[x] = g[y])))
∧ (∀r:ℤ × ℕ⁺. ((ratreal(r) ∈ [a, b]) ⇒ (g[ratreal(r)] = ratreal(f[r]))))
6. ra : ℤ × ℕ⁺
7. rb : ℤ × ℕ⁺
8. a ≤ ratreal(ra)
9. ratreal(ra) ≤ ratreal(rb)
10. ratreal(rb) ≤ b
11. ratreal(ratmul(f[ra];f[rb])) < r0
12. (ratreal(f[rb]) ≤ r0) ∧ (r0 ≤ ratreal(f[ra]))
13. rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb) ∈ ℝ
14. rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb) ∈ [ratreal(ra), ratreal(rb)]
15. -(g[rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb)]) = r0
16. g[rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb)] = r0
⊢ rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb) ∈ ∃c:{c:ℝ| c ∈ (a, b)}  [(g[c] = r0)]
BY
{ (MemTypeCD THEN Auto) }

1
1. a : ℝ
2. b : ℝ
3. f : (ℤ × ℕ⁺) ⟶ (ℤ × ℕ⁺)
4. g : {x:ℝ| x ∈ [a, b]}  ⟶ ℝ
5. a < b
6. (g[a] * g[b]) < r0
7. ∀x,y:{x:ℝ| x ∈ [a, b]} .  ((x = y) ⇒ (g[x] = g[y]))
8. ∀r:ℤ × ℕ⁺. ((ratreal(r) ∈ [a, b]) ⇒ (g[ratreal(r)] = ratreal(f[r])))
9. ra : ℤ × ℕ⁺
10. rb : ℤ × ℕ⁺
11. a ≤ ratreal(ra)
12. ratreal(ra) ≤ ratreal(rb)
13. ratreal(rb) ≤ b
14. ratreal(ratmul(f[ra];f[rb])) < r0
15. ratreal(f[rb]) ≤ r0
16. r0 ≤ ratreal(f[ra])
17. rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb) ∈ ℝ
18. rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb) ∈ [ratreal(ra), ratreal(rb)]
19. -(g[rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb)]) = r0
20. g[rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb)] = r0
⊢ rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb) ∈ {c:ℝ| (a < c) ∧ (c < b)}

2
1. a : ℝ
2. b : ℝ
3. f : (ℤ × ℕ⁺) ⟶ (ℤ × ℕ⁺)
4. g : {x:ℝ| x ∈ [a, b]}  ⟶ ℝ
5. a < b
6. (g[a] * g[b]) < r0
7. ∀x,y:{x:ℝ| x ∈ [a, b]} .  ((x = y) ⇒ (g[x] = g[y]))
8. ∀r:ℤ × ℕ⁺. ((ratreal(r) ∈ [a, b]) ⇒ (g[ratreal(r)] = ratreal(f[r])))
9. ra : ℤ × ℕ⁺
10. rb : ℤ × ℕ⁺
11. a ≤ ratreal(ra)
12. ratreal(ra) ≤ ratreal(rb)
13. ratreal(rb) ≤ b
14. ratreal(ratmul(f[ra];f[rb])) < r0
15. ratreal(f[rb]) ≤ r0
16. r0 ≤ ratreal(f[ra])
17. rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb) ∈ ℝ
18. rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb) ∈ [ratreal(ra), ratreal(rb)]
19. -(g[rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb)]) = r0
20. g[rational-fun-zero(λ₂x.int-rat-mul(-1;f[x]);ra;rb)] = r0
21. c : {c:ℝ| c ∈ (a, b)}
⊢ c ∈ {x:ℝ| (a ≤ x) ∧ (x ≤ b)}

Latex:

Latex:
1. a : \mBbbR{} 2. b : \mBbbR{} 3. f : (\mBbbZ{} \mtimes{} \mBbbN{}\msupplus{}) {}\mrightarrow{} (\mBbbZ{} \mtimes{} \mBbbN{}\msupplus{}) 4. g : \{x:\mBbbR{}| x \mmember{} [a, b]\} {}\mrightarrow{} \mBbbR{} 5. (a < b) \mwedge{} ((g[a] * g[b]) < r0) \mwedge{} (\mforall{}x,y:\{x:\mBbbR{}| x \mmember{} [a, b]\} . ((x = y) {}\mRightarrow{} (g[x] = g[y]))) \mwedge{} (\mforall{}r:\mBbbZ{} \mtimes{} \mBbbN{}\msupplus{}. ((ratreal(r) \mmember{} [a, b]) {}\mRightarrow{} (g[ratreal(r)] = ratreal(f[r])))) 6. ra : \mBbbZ{} \mtimes{} \mBbbN{}\msupplus{} 7. rb : \mBbbZ{} \mtimes{} \mBbbN{}\msupplus{} 8. a \mleq{} ratreal(ra) 9. ratreal(ra) \mleq{} ratreal(rb) 10. ratreal(rb) \mleq{} b 11. ratreal(ratmul(f[ra];f[rb])) < r0 12. (ratreal(f[rb]) \mleq{} r0) \mwedge{} (r0 \mleq{} ratreal(f[ra])) 13. rational-fun-zero(\mlambda{}\msubtwo{}x.int-rat-mul(-1;f[x]);ra;rb) \mmember{} \mBbbR{} 14. rational-fun-zero(\mlambda{}\msubtwo{}x.int-rat-mul(-1;f[x]);ra;rb) \mmember{} [ratreal(ra), ratreal(rb)] 15. -(g[rational-fun-zero(\mlambda{}\msubtwo{}x.int-rat-mul(-1;f[x]);ra;rb)]) = r0 16. g[rational-fun-zero(\mlambda{}\msubtwo{}x.int-rat-mul(-1;f[x]);ra;rb)] = r0 \mvdash{} rational-fun-zero(\mlambda{}\msubtwo{}x.int-rat-mul(-1;f[x]);ra;rb) \mmember{} \mexists{}c:\{c:\mBbbR{}| c \mmember{} (a, b)\} [(g[c] = r0)] By Latex: (MemTypeCD THEN Auto) Home Index