Proof of Nuprl Lemma : rat_term

Step * 4 of Lemma rat_term_polynomial

1. left : rat_term()
2. right : rat_term()
3. v4 : iPolynomial()
4. v5 : iPolynomial()
5. rat_term_to_ipolys(left) = <v4, v5> ∈ (iPolynomial() × iPolynomial())
6. v2 : iPolynomial()
7. v3 : iPolynomial()
8. rat_term_to_ipolys(right) = <v2, v3> ∈ (iPolynomial() × iPolynomial())
9. f : ℤ ⟶ ℝ
10. P1 : ℙ
11. v8 : ℝ supposing P1
12. rat_term_to_real(f;right) = <P1, v8> ∈ (P:ℙ × ℝ supposing P)
13. P : ℙ
14. v7 : ⋂:P. ℝ
15. rat_term_to_real(f;left) = <P, v7> ∈ (P:ℙ × ℝ supposing P)
16. P
17. P1
18. real_term_value(f;ipolynomial-term(v3)) ≠ r0
19. v8 = (real_term_value(f;ipolynomial-term(v2))/real_term_value(f;ipolynomial-term(v3)))
20. real_term_value(f;ipolynomial-term(v5)) ≠ r0
21. v7 = (real_term_value(f;ipolynomial-term(v4))/real_term_value(f;ipolynomial-term(v5)))
22. ℝ
⊢ real_term_value(f;ipolynomial-term(mul_ipoly(v5;v3))) ≠ r0
∧ ((v7 - v8)
  = (real_term_value(f;ipolynomial-term(add_ipoly(mul_ipoly(v4;v3);mul_ipoly(minus-poly(v2);v5))))/...))
BY
{ (Thin (-1)
   THEN (RWW "mul_poly-sq" 0 THENA Auto)
   THEN (RWO "add_ipoly-sq" 0 THENA Auto)
   THEN (InstLemma `minus-poly-req` [⌜v2⌝]⋅ THENA Auto)
   THEN (D -1 With ⌜f⌝  THENA Auto)) }

1
1. left : rat_term()
2. right : rat_term()
3. v4 : iPolynomial()
4. v5 : iPolynomial()
5. rat_term_to_ipolys(left) = <v4, v5> ∈ (iPolynomial() × iPolynomial())
6. v2 : iPolynomial()
7. v3 : iPolynomial()
8. rat_term_to_ipolys(right) = <v2, v3> ∈ (iPolynomial() × iPolynomial())
9. f : ℤ ⟶ ℝ
10. P1 : ℙ
11. v8 : ℝ supposing P1
12. rat_term_to_real(f;right) = <P1, v8> ∈ (P:ℙ × ℝ supposing P)
13. P : ℙ
14. v7 : ⋂:P. ℝ
15. rat_term_to_real(f;left) = <P, v7> ∈ (P:ℙ × ℝ supposing P)
16. P
17. P1
18. real_term_value(f;ipolynomial-term(v3)) ≠ r0
19. v8 = (real_term_value(f;ipolynomial-term(v2))/real_term_value(f;ipolynomial-term(v3)))
20. real_term_value(f;ipolynomial-term(v5)) ≠ r0
21. v7 = (real_term_value(f;ipolynomial-term(v4))/real_term_value(f;ipolynomial-term(v5)))
22. real_term_value(f;ipolynomial-term(minus-poly(v2))) = real_term_value(f;"-"ipolynomial-term(v2))
⊢ real_term_value(f;ipolynomial-term(mul-ipoly(v5;v3))) ≠ r0
∧ ((v7 - v8)
  = (real_term_value(f;ipolynomial-term(add-ipoly(mul-ipoly(v4;v3);mul-ipoly(minus-poly(v2);v5))))/...))

Latex:

Latex:
1. left : rat\_term() 2. right : rat\_term() 3. v4 : iPolynomial() 4. v5 : iPolynomial() 5. rat\_term\_to\_ipolys(left) = <v4, v5> 6. v2 : iPolynomial() 7. v3 : iPolynomial() 8. rat\_term\_to\_ipolys(right) = <v2, v3> 9. f : \mBbbZ{} {}\mrightarrow{} \mBbbR{} 10. P1 : \mBbbP{} 11. v8 : \mBbbR{} supposing P1 12. rat\_term\_to\_real(f;right) = <P1, v8> 13. P : \mBbbP{} 14. v7 : \mcap{}:P. \mBbbR{} 15. rat\_term\_to\_real(f;left) = <P, v7> 16. P 17. P1 18. real\_term\_value(f;ipolynomial-term(v3)) \mneq{} r0 19. v8 = (real\_term\_value(f;ipolynomial-term(v2))/real\_term\_value(f;ipolynomial-term(v3))) 20. real\_term\_value(f;ipolynomial-term(v5)) \mneq{} r0 21. v7 = (real\_term\_value(f;ipolynomial-term(v4))/real\_term\_value(f;ipolynomial-term(v5))) 22. \mBbbR{} \mvdash{} real\_term\_value(f;ipolynomial-term(mul\_ipoly(v5;v3))) \mneq{} r0 \mwedge{} ((v7 - v8) = (real\_term\_value(f;ipolynomial-term(add\_ipoly(mul\_ipoly(v4;v3);mul\_ipoly(...;v5))))/...)) By Latex: (Thin (-1) THEN (RWW "mul\_poly-sq" 0 THENA Auto) THEN (RWO "add\_ipoly-sq" 0 THENA Auto) THEN (InstLemma `minus-poly-req` [\mkleeneopen{}v2\mkleeneclose{}]\mcdot{} THENA Auto) THEN (D -1 With \mkleeneopen{}f\mkleeneclose{} THENA Auto)) Home Index