Proof of Nuprl Lemma : hyptrans

Step * 1 of Lemma hyptrans_lemma

1. rv : InnerProductSpace
2. e : Point
3. h : Point
4. e^2 = r1
5. h ⋅ e = r0
6. tau : ℝ
7. t : ℝ
8. e ⋅ h = r0
9. h + sinh(tau) * rsqrt(r1 + h^2)*e^2 = (h^2 + (sinh(tau)^2 * (r1 + h^2)))
⊢ h + sinh(tau) * rsqrt(r1 + h^2)*e + (h + sinh(tau) * rsqrt(r1 + h^2)*e ⋅ e * (cosh(t) - r1))

+ (rsqrt(r1 + h + sinh(tau) * rsqrt(r1 + h^2)*e^2) * sinh(t))*e ≡ h + sinh(tau + t) * rsqrt(r1 + h^2)*e

BY
{ (Assert (r1 + h^2 + (sinh(tau)^2 * (r1 + h^2))) = (cosh(tau)^2 * (r1 + h^2)) BY

         (InstLemma `cosh2-sinh2` [⌜tau⌝]⋅ THEN Auto THEN nRAdd ⌜sinh(tau)^2⌝ (-1)⋅ THEN RWO "-1" 0 THEN Auto)) }

1
1. rv : InnerProductSpace
2. e : Point
3. h : Point
4. e^2 = r1
5. h ⋅ e = r0
6. tau : ℝ
7. t : ℝ
8. e ⋅ h = r0
9. h + sinh(tau) * rsqrt(r1 + h^2)*e^2 = (h^2 + (sinh(tau)^2 * (r1 + h^2)))
10. (r1 + h^2 + (sinh(tau)^2 * (r1 + h^2))) = (cosh(tau)^2 * (r1 + h^2))
⊢ h + sinh(tau) * rsqrt(r1 + h^2)*e + (h + sinh(tau) * rsqrt(r1 + h^2)*e ⋅ e * (cosh(t) - r1))

+ (rsqrt(r1 + h + sinh(tau) * rsqrt(r1 + h^2)*e^2) * sinh(t))*e ≡ h + sinh(tau + t) * rsqrt(r1 + h^2)*e

Latex:

Latex:
1. rv : InnerProductSpace 2. e : Point 3. h : Point 4. e\^{}2 = r1 5. h \mcdot{} e = r0 6. tau : \mBbbR{} 7. t : \mBbbR{} 8. e \mcdot{} h = r0 9. h + sinh(tau) * rsqrt(r1 + h\^{}2)*e\^{}2 = (h\^{}2 + (sinh(tau)\^{}2 * (r1 + h\^{}2))) \mvdash{} h + sinh(tau) * rsqrt(r1 + h\^{}2)*e + (h + sinh(tau) * rsqrt(r1 + h\^{}2)*e \mcdot{} e * (cosh(t) - r1)) + (rsqrt(r1 + h + sinh(tau) * rsqrt(r1 + h\^{}2)*e\^{}2) * sinh(t))*e \mequiv{} h + sinh(tau + t) * rsqrt(r1 + h\^{}2)*e By Latex: (Assert (r1 + h\^{}2 + (sinh(tau)\^{}2 * (r1 + h\^{}2))) = (cosh(tau)\^{}2 * (r1 + h\^{}2)) BY (InstLemma `cosh2-sinh2` [\mkleeneopen{}tau\mkleeneclose{}]\mcdot{} THEN Auto THEN nRAdd \mkleeneopen{}sinh(tau)\^{}2\mkleeneclose{} (-1)\mcdot{} THEN RWO "-1" 0 THEN Auto)) Home Index