Proof of Nuprl Lemma : satisfiable-pcs-to-integer-problem

Step * 1 2 1 1 2 of Lemma satisfiable-pcs-to-integer-problem

1. X1 : iPolynomial() List
2. X2 : iPolynomial() List
3. f : ℤ ⟶ ℤ
4. (∀p∈X1.int_term_value(f;ipolynomial-term(p)) = 0 ∈ ℤ)
5. (∀p∈X2.0 ≤ int_term_value(f;ipolynomial-term(p)))
6. v : ℤ List List
7. rev(pcs-mon-vars(<X1, X2>)) = v ∈ (ℤ List List)
8. 0 < ||v||
9. hd(v) = [] ∈ (ℤ List)
10. ∀[p:iPolynomial()]
      (((p ∈ X1) ∨ (p ∈ X2))
      ⇒ (int_term_value(f;ipolynomial-term(p))
         = linearization(p;v) ⋅ map(λvs.accumulate (with value x and list item v):
                                         x * (f v)
                                        over list:
                                          vs
                                        with starting value:
                                         1);v)
         ∈ ℤ))
11. i : ℕ||map(λp.linearization(p;v);X1)||
12. ||map(λvs.accumulate (with value x and list item v):
               x * (f v)
              over list:
                vs
              with starting value:
               1);v)||
= ||linearization(X1[i];v)||
∈ ℤ
13. 0 < ||map(λvs.accumulate (with value x and list item v):
                   x * (f v)
                  over list:
                    vs
                  with starting value:
                   1);v)||

14. hd(map(λvs.accumulate (with value x and list item v): x * (f v)over list:  vswith starting value: 1);v)) = 1 ∈ ℤ

⊢ linearization(X1[i];v) ⋅ map(λvs.accumulate (with value x and list item v):
                                    x * (f v)
                                   over list:
                                     vs
                                   with starting value:
                                    1);v)
= 0
∈ ℤ
BY
{ ((RWO "length-map" (-4) THENA Auto) THEN RWO  "10<" 0 THEN Auto) }

Latex:

Latex:
1. X1 : iPolynomial() List 2. X2 : iPolynomial() List 3. f : \mBbbZ{} {}\mrightarrow{} \mBbbZ{} 4. (\mforall{}p\mmember{}X1.int\_term\_value(f;ipolynomial-term(p)) = 0) 5. (\mforall{}p\mmember{}X2.0 \mleq{} int\_term\_value(f;ipolynomial-term(p))) 6. v : \mBbbZ{} List List 7. rev(pcs-mon-vars(<X1, X2>)) = v 8. 0 < ||v|| 9. hd(v) = [] 10. \mforall{}[p:iPolynomial()] (((p \mmember{} X1) \mvee{} (p \mmember{} X2)) {}\mRightarrow{} (int\_term\_value(f;ipolynomial-term(p)) = linearization(p;v) \mcdot{} map(\mlambda{}vs.accumulate (with value x and list item v): x * (f v) over list: vs with starting value: 1);v))) 11. i : \mBbbN{}||map(\mlambda{}p.linearization(p;v);X1)|| 12. ||map(\mlambda{}vs.accumulate (with value x and list item v): x * (f v) over list: vs with starting value: 1);v)|| = ||linearization(X1[i];v)|| 13. 0 < ||map(\mlambda{}vs.accumulate (with value x and list item v): x * (f v) over list: vs with starting value: 1);v)|| 14. hd(map(\mlambda{}vs.accumulate (with value x and list item v): x * (f v) over list: vs with starting value: 1);v)) = 1 \mvdash{} linearization(X1[i];v) \mcdot{} map(\mlambda{}vs.accumulate (with value x and list item v): x * (f v) over list: vs with starting value: 1);v) = 0 By Latex: ((RWO "length-map" (-4) THENA Auto) THEN RWO "10<" 0 THEN Auto) Home Index