Proof of Nuprl Lemma : arcsine-rsin

Step * 1 1 2 1 2 of Lemma arcsine-rsin

.....antecedent.....
1. ∀x:{x:ℝ| x ∈ (-(π/2), π/2)} . (rsin(x) ∈ (r(-1), r1))
2. ∀x:{x:ℝ| (-(π/2) < x) ∧ (x < π/2)} . ((r(-1) < rsin(x)) ∧ (rsin(x) < r1))
3. x : {t:ℝ| t ∈ (-(π/2), π/2)}
4. y : {t:ℝ| t ∈ (-(π/2), π/2)}
5. x ≤ y
⊢ d(rsin(x))/dx = λx.rcos(x) on [-(π/2), π/2]
BY

{ ((InstLemma `derivative_functionality_wrt_subinterval` [⌜(-∞, ∞)⌝]⋅ THENA Auto) THEN BHyp -1  THEN Auto) }

Latex:

Latex:
.....antecedent..... 1. \mforall{}x:\{x:\mBbbR{}| x \mmember{} (-(\mpi{}/2), \mpi{}/2)\} . (rsin(x) \mmember{} (r(-1), r1)) 2. \mforall{}x:\{x:\mBbbR{}| (-(\mpi{}/2) < x) \mwedge{} (x < \mpi{}/2)\} . ((r(-1) < rsin(x)) \mwedge{} (rsin(x) < r1)) 3. x : \{t:\mBbbR{}| t \mmember{} (-(\mpi{}/2), \mpi{}/2)\} 4. y : \{t:\mBbbR{}| t \mmember{} (-(\mpi{}/2), \mpi{}/2)\} 5. x \mleq{} y \mvdash{} d(rsin(x))/dx = \mlambda{}x.rcos(x) on [-(\mpi{}/2), \mpi{}/2] By Latex: ((InstLemma `derivative\_functionality\_wrt\_subinterval` [\mkleeneopen{}(-\minfty{}, \minfty{})\mkleeneclose{}]\mcdot{} THENA Auto) THEN BHyp -1 THEN Auto) Home Index