Proof of Nuprl Lemma : sinh-inv-sinh

Step * 1 1 1 1 of Lemma sinh-inv-sinh

1. x : ℝ
2. (r0 ≤ ((x * x) + r1)) ∧ (r0 < (x + rsqrt((x * x) + r1)))
3. v : ℝ
4. v = rlog(x + rsqrt((x * x) + r1))
5. ln(x + rsqrt((x * x) + r1)) = v ∈ {x1:ℝ| x1 = rlog(x + rsqrt((x * x) + r1))}
6. v1 : ℝ
7. v1 = e^v
8. expr(v) = v1 ∈ {y:ℝ| y = e^v}
9. v2 : ℝ
10. v2 = e^-(v)
11. expr(-(v)) = v2 ∈ {y:ℝ| y = e^-(v)}
12. v1 = (x + rsqrt((x * x) + r1))
13. v2 = (r1/x + rsqrt((x * x) + r1))
⊢ (v1 + -(v2)) = (r(2) * x)
BY
{ ((RWO "-2<" (-1) THENA Auto) THEN (RWO "-1" 0 THENA Auto)) }

1
1. x : ℝ
2. (r0 ≤ ((x * x) + r1)) ∧ (r0 < (x + rsqrt((x * x) + r1)))
3. v : ℝ
4. v = rlog(x + rsqrt((x * x) + r1))
5. ln(x + rsqrt((x * x) + r1)) = v ∈ {x1:ℝ| x1 = rlog(x + rsqrt((x * x) + r1))}
6. v1 : ℝ
7. v1 = e^v
8. expr(v) = v1 ∈ {y:ℝ| y = e^v}
9. v2 : ℝ
10. v2 = e^-(v)
11. expr(-(v)) = v2 ∈ {y:ℝ| y = e^-(v)}
12. v1 = (x + rsqrt((x * x) + r1))
13. v2 = (r1/v1)
⊢ (v1 + -((r1/v1))) = (r(2) * x)

Latex:

Latex:
1. x : \mBbbR{} 2. (r0 \mleq{} ((x * x) + r1)) \mwedge{} (r0 < (x + rsqrt((x * x) + r1))) 3. v : \mBbbR{} 4. v = rlog(x + rsqrt((x * x) + r1)) 5. ln(x + rsqrt((x * x) + r1)) = v 6. v1 : \mBbbR{} 7. v1 = e\^{}v 8. expr(v) = v1 9. v2 : \mBbbR{} 10. v2 = e\^{}-(v) 11. expr(-(v)) = v2 12. v1 = (x + rsqrt((x * x) + r1)) 13. v2 = (r1/x + rsqrt((x * x) + r1)) \mvdash{} (v1 + -(v2)) = (r(2) * x) By Latex: ((RWO "-2<" (-1) THENA Auto) THEN (RWO "-1" 0 THENA Auto)) Home Index