Proof of Nuprl Lemma : extend-half-cube-face

Step * 1 1 1 1 1 1 1 3 of Lemma extend-half-cube-face

1. k : ℕ
2. a : ℚCube(k)
3. b : ℚCube(k)
4. c : ℚCube(k)
5. ∀i:ℕk. (↑Inhabited(a i))
6. 0 < dim(b)
7. ∀i:ℕk. a i ≤ b i
8. ∀i:ℕk. (↑is-half-interval(b i;c i))
9. dim(a) = (dim(b) - 1) ∈ ℤ
10. i : ℕk
11. dim(c i) = 1 ∈ ℤ
12. ∀j:ℕk. ((¬(j = i ∈ ℤ)) ⇒ ((a j) = (b j) ∈ ℚInterval))
13. (a i) = [fst((b i))] ∈ ℚInterval
14. (fst((b i))) = (fst((c i))) ∈ ℚ
15. (snd((b i))) = qavg(fst((c i));snd((c i))) ∈ ℚ
16. λj.if (j =_z i) then [fst((c i))] else c j fi ∈ ℚCube(k)
17. ↑is-half-cube(k;a;λj.if (j =_z i) then [fst((c i))] else c j fi )
18. ∀i@0:ℕk. if (i@0 =_z i) then [fst((c i))] else c i@0 fi ≤ c i@0
19. y : ℚCube(k)
20. ↑is-half-cube(k;a;y)
21. ∀i:ℕk. y i ≤ c i
⊢ y = (λj.if (j =_z i) then [fst((c i))] else c j fi ) ∈ ℚCube(k)
BY

{ (Unfold `rational-cube` 0 THEN (FunExt THENA Auto) THEN Reduce 0 THEN AutoSplit THEN Try (HypSubst' (-1) 0)) }

1
1. k : ℕ
2. a : ℚCube(k)
3. b : ℚCube(k)
4. c : ℚCube(k)
5. ∀i:ℕk. (↑Inhabited(a i))
6. 0 < dim(b)
7. ∀i:ℕk. a i ≤ b i
8. ∀i:ℕk. (↑is-half-interval(b i;c i))
9. dim(a) = (dim(b) - 1) ∈ ℤ
10. i : ℕk
11. dim(c i) = 1 ∈ ℤ
12. ∀j:ℕk. ((¬(j = i ∈ ℤ)) ⇒ ((a j) = (b j) ∈ ℚInterval))
13. (a i) = [fst((b i))] ∈ ℚInterval
14. (fst((b i))) = (fst((c i))) ∈ ℚ
15. (snd((b i))) = qavg(fst((c i));snd((c i))) ∈ ℚ
16. λj.if (j =_z i) then [fst((c i))] else c j fi  ∈ ℚCube(k)
17. ↑is-half-cube(k;a;λj.if (j =_z i) then [fst((c i))] else c j fi )
18. ∀i@0:ℕk. if (i@0 =_z i) then [fst((c i))] else c i@0 fi  ≤ c i@0
19. y : ℚCube(k)
20. ↑is-half-cube(k;a;y)
21. ∀i:ℕk. y i ≤ c i
22. x : ℕk
23. x = i ∈ ℤ
⊢ (y i) = [fst((c i))] ∈ ℚInterval

2
1. k : ℕ
2. a : ℚCube(k)
3. b : ℚCube(k)
4. c : ℚCube(k)
5. ∀i:ℕk. (↑Inhabited(a i))
6. 0 < dim(b)
7. ∀i:ℕk. a i ≤ b i
8. ∀i:ℕk. (↑is-half-interval(b i;c i))
9. dim(a) = (dim(b) - 1) ∈ ℤ
10. i : ℕk
11. dim(c i) = 1 ∈ ℤ
12. ∀j:ℕk. ((¬(j = i ∈ ℤ)) ⇒ ((a j) = (b j) ∈ ℚInterval))
13. (a i) = [fst((b i))] ∈ ℚInterval
14. (fst((b i))) = (fst((c i))) ∈ ℚ
15. (snd((b i))) = qavg(fst((c i));snd((c i))) ∈ ℚ
16. λj.if (j =_z i) then [fst((c i))] else c j fi  ∈ ℚCube(k)
17. ↑is-half-cube(k;a;λj.if (j =_z i) then [fst((c i))] else c j fi )
18. ∀i@0:ℕk. if (i@0 =_z i) then [fst((c i))] else c i@0 fi  ≤ c i@0
19. y : ℚCube(k)
20. ↑is-half-cube(k;a;y)
21. ∀i:ℕk. y i ≤ c i
22. x : ℕk
23. x ≠ i
⊢ (y x) = (c x) ∈ ℚInterval

Latex:

Latex:
1. k : \mBbbN{} 2. a : \mBbbQ{}Cube(k) 3. b : \mBbbQ{}Cube(k) 4. c : \mBbbQ{}Cube(k) 5. \mforall{}i:\mBbbN{}k. (\muparrow{}Inhabited(a i)) 6. 0 < dim(b) 7. \mforall{}i:\mBbbN{}k. a i \mleq{} b i 8. \mforall{}i:\mBbbN{}k. (\muparrow{}is-half-interval(b i;c i)) 9. dim(a) = (dim(b) - 1) 10. i : \mBbbN{}k 11. dim(c i) = 1 12. \mforall{}j:\mBbbN{}k. ((\mneg{}(j = i)) {}\mRightarrow{} ((a j) = (b j))) 13. (a i) = [fst((b i))] 14. (fst((b i))) = (fst((c i))) 15. (snd((b i))) = qavg(fst((c i));snd((c i))) 16. \mlambda{}j.if (j =\msubz{} i) then [fst((c i))] else c j fi \mmember{} \mBbbQ{}Cube(k) 17. \muparrow{}is-half-cube(k;a;\mlambda{}j.if (j =\msubz{} i) then [fst((c i))] else c j fi ) 18. \mforall{}i@0:\mBbbN{}k. if (i@0 =\msubz{} i) then [fst((c i))] else c i@0 fi \mleq{} c i@0 19. y : \mBbbQ{}Cube(k) 20. \muparrow{}is-half-cube(k;a;y) 21. \mforall{}i:\mBbbN{}k. y i \mleq{} c i \mvdash{} y = (\mlambda{}j.if (j =\msubz{} i) then [fst((c i))] else c j fi ) By Latex: (Unfold `rational-cube` 0 THEN (FunExt THENA Auto) THEN Reduce 0 THEN AutoSplit THEN Try (HypSubst' (-1) 0)) Home Index