Proof of Nuprl Lemma : satisfiable-exact-reduce-constraints

Step * 1 1 4 1 1 1 1 of Lemma satisfiable-exact-reduce-constraints

1. eqs : ℤ List List
2. i : ℕ||eqs||
3. j : ℕ⁺||eqs[i]||
4. exact-eq-constraint(eqs;i;j)
5. ineqs : ℤ List List
6. xs : ℤ List
7. satisfies-integer-problem(eqs;ineqs;xs)
8. (∀e∈eqs.||e|| = ||xs|| ∈ ℤ)
9. (∀e∈ineqs.||e|| = ||xs|| ∈ ℤ)
10. ||eqs[i]|| ~ ||xs||
11. eqs ∈ {l:ℤ List| ||l|| = ||eqs[i]|| ∈ ℤ} List
12. ineqs ∈ {l:ℤ List| ||l|| = ||eqs[i]|| ∈ ℤ} List
13. 1 ≤ j
14. j < ||xs||
15. 0 < ||xs\j||
16. hd(xs\j) = hd(xs) ∈ ℤ
17. (∀as∈eqs.xs ⋅ as =0)
18. ∀i:ℕ||ineqs||. xs ⋅ ineqs[i] ≥0
19. i@0 : ℕ||ineqs||
20. ||xs|| = ||ineqs[i@0]|| ∈ ℤ
21. 0 < ||xs||
22. hd(xs) = 1 ∈ ℤ
23. ineqs[i@0] ⋅ xs ≥ 0
24. 0 < ||xs\j||
25. hd(xs\j) = 1 ∈ ℤ
26. ||xs|| = ||ineqs[i@0]|| ∈ ℤ
27. 0 < ||xs||
28. hd(xs) = 1 ∈ ℤ
29. ineqs[i@0] ⋅ xs ≥ 0
⊢ (||eqs[i]|| - 1) = (||ineqs[i@0]|| - 1) ∈ ℤ
BY
{ TACTIC:(RWO "10 20<" 0 THEN Auto) }

Latex:

Latex:
1. eqs : \mBbbZ{} List List 2. i : \mBbbN{}||eqs|| 3. j : \mBbbN{}\msupplus{}||eqs[i]|| 4. exact-eq-constraint(eqs;i;j) 5. ineqs : \mBbbZ{} List List 6. xs : \mBbbZ{} List 7. satisfies-integer-problem(eqs;ineqs;xs) 8. (\mforall{}e\mmember{}eqs.||e|| = ||xs||) 9. (\mforall{}e\mmember{}ineqs.||e|| = ||xs||) 10. ||eqs[i]|| \msim{} ||xs|| 11. eqs \mmember{} \{l:\mBbbZ{} List| ||l|| = ||eqs[i]||\} List 12. ineqs \mmember{} \{l:\mBbbZ{} List| ||l|| = ||eqs[i]||\} List 13. 1 \mleq{} j 14. j < ||xs|| 15. 0 < ||xs\mbackslash{}j|| 16. hd(xs\mbackslash{}j) = hd(xs) 17. (\mforall{}as\mmember{}eqs.xs \mcdot{} as =0) 18. \mforall{}i:\mBbbN{}||ineqs||. xs \mcdot{} ineqs[i] \mgeq{}0 19. i@0 : \mBbbN{}||ineqs|| 20. ||xs|| = ||ineqs[i@0]|| 21. 0 < ||xs|| 22. hd(xs) = 1 23. ineqs[i@0] \mcdot{} xs \mgeq{} 0 24. 0 < ||xs\mbackslash{}j|| 25. hd(xs\mbackslash{}j) = 1 26. ||xs|| = ||ineqs[i@0]|| 27. 0 < ||xs|| 28. hd(xs) = 1 29. ineqs[i@0] \mcdot{} xs \mgeq{} 0 \mvdash{} (||eqs[i]|| - 1) = (||ineqs[i@0]|| - 1) By Latex: TACTIC:(RWO "10 20<" 0 THEN Auto) Home Index