Proof of Nuprl Lemma : arcsine-contraction-Taylor

Step * 1 2 of Lemma arcsine-contraction-Taylor

1. a : ℝ
2. r(-1) < a
3. a < r1
4. x : ℝ
5. c : ℝ
6. r0 ≤ a
7. a ≤ c
8. rsqrt(r1 - a * a) ≤ c
9. r0 ≤ (r1 - a * a)
10. e : {e:ℝ| r0 < e}
11. (-(π/2), π/2) ⊆ (-∞, ∞)
12. d(rcos(x))/dx = λx.-(rsin(x)) on (-∞, ∞)
13. d(rsin(x))/dx = λx.rcos(x) on (-∞, ∞)
14. d(-(rsin(x)))/dx = λx.-(rcos(x)) on (-∞, ∞)
15. d(-(rcos(x)))/dx = λx.rsin(x) on (-∞, ∞)
⊢ finite-deriv-seq((-∞, ∞);3;i,x.if (i =_z 0) then arcsine-contraction(a;x)
if (i =_z 1) then r1 + ((a * -(rsin(x))) - rsqrt(r1 - a * a) * rcos(x))
if (i =_z 2) then r0 + ((a * -(rcos(x))) - rsqrt(r1 - a * a) * -(rsin(x)))
else r0 + ((a * -(-(rsin(x)))) - rsqrt(r1 - a * a) * -(rcos(x)))
fi )
BY
{ ((D 0 THENA Auto)
   THEN IntSegCases (-1)
   THEN Reduce 0
   THEN Auto
   THEN Try (Unfold `arcsine-contraction` 0)
   THEN ProveDerivative
   THEN Auto) }

Latex:

Latex:
1. a : \mBbbR{} 2. r(-1) < a 3. a < r1 4. x : \mBbbR{} 5. c : \mBbbR{} 6. r0 \mleq{} a 7. a \mleq{} c 8. rsqrt(r1 - a * a) \mleq{} c 9. r0 \mleq{} (r1 - a * a) 10. e : \{e:\mBbbR{}| r0 < e\} 11. (-(\mpi{}/2), \mpi{}/2) \msubseteq{} (-\minfty{}, \minfty{}) 12. d(rcos(x))/dx = \mlambda{}x.-(rsin(x)) on (-\minfty{}, \minfty{}) 13. d(rsin(x))/dx = \mlambda{}x.rcos(x) on (-\minfty{}, \minfty{}) 14. d(-(rsin(x)))/dx = \mlambda{}x.-(rcos(x)) on (-\minfty{}, \minfty{}) 15. d(-(rcos(x)))/dx = \mlambda{}x.rsin(x) on (-\minfty{}, \minfty{}) \mvdash{} finite-deriv-seq((-\minfty{}, \minfty{});3;i,x.if (i =\msubz{} 0) then arcsine-contraction(a;x) if (i =\msubz{} 1) then r1 + ((a * -(rsin(x))) - rsqrt(r1 - a * a) * rcos(x)) if (i =\msubz{} 2) then r0 + ((a * -(rcos(x))) - rsqrt(r1 - a * a) * -(rsin(x))) else r0 + ((a * -(-(rsin(x)))) - rsqrt(r1 - a * a) * -(rcos(x))) fi ) By Latex: ((D 0 THENA Auto) THEN IntSegCases (-1) THEN Reduce 0 THEN Auto THEN Try (Unfold `arcsine-contraction` 0) THEN ProveDerivative THEN Auto) Home Index