Proof of Nuprl Lemma : rmax-rnexp

Step * 2 2 1 1 1 2 of Lemma rmax-rnexp

1. x : ℝ
2. y : ℝ
3. r0 ≤ x
4. r0 ≤ y
5. n : ℤ
6. n ≠ 1
7. n ≠ 0
8. 0 < n
9. rmax(x;y)^n - 1 ≤ rmax(x^n - 1;y^n - 1)
10. (rmax(x;y) * x^n - 1) ≤ rmax(x * x^n - 1;y * y^n - 1)
⊢ ¬(((x^n - 1 * x) < (y^n - 1 * x)) ∧ ((y^n - 1 * y) < (y^n - 1 * x)))
BY
{ (D 0 THEN Auto)⋅ }

1
1. x : ℝ
2. y : ℝ
3. r0 ≤ x
4. r0 ≤ y
5. n : ℤ
6. n ≠ 1
7. n ≠ 0
8. 0 < n
9. rmax(x;y)^n - 1 ≤ rmax(x^n - 1;y^n - 1)
10. (rmax(x;y) * x^n - 1) ≤ rmax(x * x^n - 1;y * y^n - 1)
11. (x^n - 1 * x) < (y^n - 1 * x)
12. (y^n - 1 * y) < (y^n - 1 * x)
⊢ False

Latex:

Latex:
1. x : \mBbbR{} 2. y : \mBbbR{} 3. r0 \mleq{} x 4. r0 \mleq{} y 5. n : \mBbbZ{} 6. n \mneq{} 1 7. n \mneq{} 0 8. 0 < n 9. rmax(x;y)\^{}n - 1 \mleq{} rmax(x\^{}n - 1;y\^{}n - 1) 10. (rmax(x;y) * x\^{}n - 1) \mleq{} rmax(x * x\^{}n - 1;y * y\^{}n - 1) \mvdash{} \mneg{}(((x\^{}n - 1 * x) < (y\^{}n - 1 * x)) \mwedge{} ((y\^{}n - 1 * y) < (y\^{}n - 1 * x))) By Latex: (D 0 THEN Auto)\mcdot{} Home Index