Proof of Nuprl Lemma : rv-T-partially-implies-rv-T'

Step * 1 1 1 1 of Lemma rv-T-partially-implies-rv-T'

1. n : ℕ⁺
2. x : ℝ^n
3. y : ℝ^n
4. t1 : ℝ
5. r0 < t1
6. t1 < r1
7. x ≠ y
8. t2 : ℝ
9. r0 < t2
10. t2 < r1
11. x ≠ y
12. t : ℝ
13. r0 ≤ t
14. t ≤ r1
15. r0 < t
⊢ r0 < ((t * t1) + ((r1 - t) * t2))
BY
{ (nRMul ⌜t1⌝ (-1)⋅ THEN (Assert r0 ≤ (r1 - t) BY (nRAdd ⌜t⌝ 0⋅ THEN Auto))) }

1
1. n : ℕ⁺
2. x : ℝ^n
3. y : ℝ^n
4. t1 : ℝ
5. r0 < t1
6. t1 < r1
7. x ≠ y
8. t2 : ℝ
9. r0 < t2
10. t2 < r1
11. x ≠ y
12. t : ℝ
13. r0 ≤ t
14. t ≤ r1
15. r0 < (t * t1)
16. r0 ≤ (r1 - t)
⊢ r0 < ((t * t1) + ((r1 - t) * t2))

Latex:

Latex:
1. n : \mBbbN{}\msupplus{} 2. x : \mBbbR{}\^{}n 3. y : \mBbbR{}\^{}n 4. t1 : \mBbbR{} 5. r0 < t1 6. t1 < r1 7. x \mneq{} y 8. t2 : \mBbbR{} 9. r0 < t2 10. t2 < r1 11. x \mneq{} y 12. t : \mBbbR{} 13. r0 \mleq{} t 14. t \mleq{} r1 15. r0 < t \mvdash{} r0 < ((t * t1) + ((r1 - t) * t2)) By Latex: (nRMul \mkleeneopen{}t1\mkleeneclose{} (-1)\mcdot{} THEN (Assert r0 \mleq{} (r1 - t) BY (nRAdd \mkleeneopen{}t\mkleeneclose{} 0\mcdot{} THEN Auto))) Home Index