Proof of Nuprl Lemma : mul-polynom-val

Step * 2 1 2 2 1 1 1 1 of Lemma mul-polynom-val

1. k : ℕ
2. ∀k:ℕk
     ∀[n:ℕ]. ∀[p,q:polyform(n)].
       (((tree_size(p) + tree_size(q)) ≤ k) ⇒ (∀[l:{l:ℤ List| n ≤ ||l||} ]. (mul-polynom(p;q)@l = (p@l * q@l) ∈ ℤ)))
3. n : ℕ
4. p1 : ℤ
5. p1 ≠ 1
6. p1 ≠ 0
7. True
8. left : tree(ℤ)
9. q2 : tree(ℤ)
10. ((↑(ispolyform(left) (n - 1))) ∧ (↑(ispolyform(q2) n))) ∧ 0 < n
11. (0 + (1 + tree_size(left)) + tree_size(q2)) ≤ k
12. u : ℤ
13. v : ℤ List
14. n ≤ (||v|| + 1)
15. mul-polynom(tree_leaf(p1);left) ∈ polyform(n - 1)
16. mul-polynom(tree_leaf(p1);q2) ∈ polyform(n)
17. mul-polynom(tree_leaf(p1);left)@v = (tree_leaf(p1)@v * left@v) ∈ ℤ
18. mul-polynom(tree_leaf(p1);q2)@[u / v] = (tree_leaf(p1)@[u / v] * q2@[u / v]) ∈ ℤ
19. left ∈ polyform(n - 1)
20. q2 ∈ polyform(n)
⊢ if p1 * q2@[u / v]=0 then p1 * left@v else ((p1 * left@v) + (u * p1 * q2@[u / v]))
= (p1 * if q2@[u / v]=0 then left@v else (left@v + (u * q2@[u / v])))
∈ ℤ
BY
{ ((Decide ⌜q2@[u / v] = 0 ∈ ℤ⌝⋅ THENA Auto) THEN Reduce 0) }

1
1. k : ℕ
2. ∀k:ℕk
     ∀[n:ℕ]. ∀[p,q:polyform(n)].
       (((tree_size(p) + tree_size(q)) ≤ k) ⇒ (∀[l:{l:ℤ List| n ≤ ||l||} ]. (mul-polynom(p;q)@l = (p@l * q@l) ∈ ℤ)))
3. n : ℕ
4. p1 : ℤ
5. p1 ≠ 1
6. p1 ≠ 0
7. True
8. left : tree(ℤ)
9. q2 : tree(ℤ)
10. ((↑(ispolyform(left) (n - 1))) ∧ (↑(ispolyform(q2) n))) ∧ 0 < n
11. (0 + (1 + tree_size(left)) + tree_size(q2)) ≤ k
12. u : ℤ
13. v : ℤ List
14. n ≤ (||v|| + 1)
15. mul-polynom(tree_leaf(p1);left) ∈ polyform(n - 1)
16. mul-polynom(tree_leaf(p1);q2) ∈ polyform(n)
17. mul-polynom(tree_leaf(p1);left)@v = (tree_leaf(p1)@v * left@v) ∈ ℤ
18. mul-polynom(tree_leaf(p1);q2)@[u / v] = (tree_leaf(p1)@[u / v] * q2@[u / v]) ∈ ℤ
19. left ∈ polyform(n - 1)
20. q2 ∈ polyform(n)
21. q2@[u / v] = 0 ∈ ℤ

⊢ if p1 * q2@[u / v]=0 then p1 * left@v else ((p1 * left@v) + (u * p1 * q2@[u / v])) = (p1 * left@v) ∈ ℤ

2
1. k : ℕ
2. ∀k:ℕk
∀[n:ℕ]. ∀[p,q:polyform(n)].
(((tree_size(p) + tree_size(q)) ≤ k) ⇒ (∀[l:{l:ℤ List| n ≤ ||l||} ]. (mul-polynom(p;q)@l = (p@l * q@l) ∈ ℤ)))
3. n : ℕ
4. p1 : ℤ
5. p1 ≠ 1
6. p1 ≠ 0
7. True
8. left : tree(ℤ)
9. q2 : tree(ℤ)
10. ((↑(ispolyform(left) (n - 1))) ∧ (↑(ispolyform(q2) n))) ∧ 0 < n
11. (0 + (1 + tree_size(left)) + tree_size(q2)) ≤ k
12. u : ℤ
13. v : ℤ List
14. n ≤ (||v|| + 1)
15. mul-polynom(tree_leaf(p1);left) ∈ polyform(n - 1)
16. mul-polynom(tree_leaf(p1);q2) ∈ polyform(n)
17. mul-polynom(tree_leaf(p1);left)@v = (tree_leaf(p1)@v * left@v) ∈ ℤ
18. mul-polynom(tree_leaf(p1);q2)@[u / v] = (tree_leaf(p1)@[u / v] * q2@[u / v]) ∈ ℤ
19. left ∈ polyform(n - 1)
20. q2 ∈ polyform(n)
21. ¬(q2@[u / v] = 0 ∈ ℤ)
⊢ if p1 * q2@[u / v]=0 then p1 * left@v else ((p1 * left@v) + (u * p1 * q2@[u / v]))
= (p1 * (left@v + (u * q2@[u / v])))
∈ ℤ

Latex:

Latex:
1. k : \mBbbN{} 2. \mforall{}k:\mBbbN{}k \mforall{}[n:\mBbbN{}]. \mforall{}[p,q:polyform(n)]. (((tree\_size(p) + tree\_size(q)) \mleq{} k) {}\mRightarrow{} (\mforall{}[l:\{l:\mBbbZ{} List| n \mleq{} ||l||\} ]. (mul-polynom(p;q)@l = (p@l * q@l)))) 3. n : \mBbbN{} 4. p1 : \mBbbZ{} 5. p1 \mneq{} 1 6. p1 \mneq{} 0 7. True 8. left : tree(\mBbbZ{}) 9. q2 : tree(\mBbbZ{}) 10. ((\muparrow{}(ispolyform(left) (n - 1))) \mwedge{} (\muparrow{}(ispolyform(q2) n))) \mwedge{} 0 < n 11. (0 + (1 + tree\_size(left)) + tree\_size(q2)) \mleq{} k 12. u : \mBbbZ{} 13. v : \mBbbZ{} List 14. n \mleq{} (||v|| + 1) 15. mul-polynom(tree\_leaf(p1);left) \mmember{} polyform(n - 1) 16. mul-polynom(tree\_leaf(p1);q2) \mmember{} polyform(n) 17. mul-polynom(tree\_leaf(p1);left)@v = (tree\_leaf(p1)@v * left@v) 18. mul-polynom(tree\_leaf(p1);q2)@[u / v] = (tree\_leaf(p1)@[u / v] * q2@[u / v]) 19. left \mmember{} polyform(n - 1) 20. q2 \mmember{} polyform(n) \mvdash{} if p1 * q2@[u / v]=0 then p1 * left@v else ((p1 * left@v) + (u * p1 * q2@[u / v])) = (p1 * if q2@[u / v]=0 then left@v else (left@v + (u * q2@[u / v]))) By Latex: ((Decide \mkleeneopen{}q2@[u / v] = 0\mkleeneclose{}\mcdot{} THENA Auto) THEN Reduce 0) Home Index