Proof of Nuprl Lemma : trans-kernel-equation

Step * 1 2 1 of Lemma trans-kernel-equation

1. rv : InnerProductSpace
2. e : Point
3. e^2 = r1
4. T : ℝ ⟶ Point ⟶ Point
5. ∀s,t:ℝ. ∀x,y:Point.  (T_s(x) # T_t(y) ⇒ (x # y ∨ s ≠ t))
6. ∀t,s:ℝ. ∀x:Point.  T_t + s(x) ≡ T_t(T_s(x))
7. ∀x:Point. ∀r:ℝ.  ∃t:ℝ. (T_t(x) ≡ x + r*e ∧ (∀y:ℝ. (y ≠ t ⇒ T_y(x) # x + r*e)))
8. ∀x:Point. ∀t:{t:ℝ| r0 ≤ t} .  ∃r:{t:ℝ| r0 ≤ t} . T_t(x) ≡ x + r*e
9. t : ℝ
10. h : Point
11. h ⋅ e = r0
12. t ≤ r0
⊢ T_t(h) ≡ h + ρ(h;t)*e
BY
{ ((InstHyp [⌜T_t(h)⌝;⌜-(t)⌝] (-5)⋅ THENA Auto) THEN (RWO "6<" (-1) THENA Auto)) }

1
1. rv : InnerProductSpace
2. e : Point
3. e^2 = r1
4. T : ℝ ⟶ Point ⟶ Point
5. ∀s,t:ℝ. ∀x,y:Point.  (T_s(x) # T_t(y) ⇒ (x # y ∨ s ≠ t))
6. ∀t,s:ℝ. ∀x:Point.  T_t + s(x) ≡ T_t(T_s(x))
7. ∀x:Point. ∀r:ℝ.  ∃t:ℝ. (T_t(x) ≡ x + r*e ∧ (∀y:ℝ. (y ≠ t ⇒ T_y(x) # x + r*e)))
8. ∀x:Point. ∀t:{t:ℝ| r0 ≤ t} .  ∃r:{t:ℝ| r0 ≤ t} . T_t(x) ≡ x + r*e
9. t : ℝ
10. h : Point
11. h ⋅ e = r0
12. t ≤ r0
13. ∃r:{t:ℝ| r0 ≤ t} . T_-(t) + t(h) ≡ T_t(h) + r*e
⊢ T_t(h) ≡ h + ρ(h;t)*e

Latex:

Latex:
1. rv : InnerProductSpace 2. e : Point 3. e\^{}2 = r1 4. T : \mBbbR{} {}\mrightarrow{} Point {}\mrightarrow{} Point 5. \mforall{}s,t:\mBbbR{}. \mforall{}x,y:Point. (T\_s(x) \# T\_t(y) {}\mRightarrow{} (x \# y \mvee{} s \mneq{} t)) 6. \mforall{}t,s:\mBbbR{}. \mforall{}x:Point. T\_t + s(x) \mequiv{} T\_t(T\_s(x)) 7. \mforall{}x:Point. \mforall{}r:\mBbbR{}. \mexists{}t:\mBbbR{}. (T\_t(x) \mequiv{} x + r*e \mwedge{} (\mforall{}y:\mBbbR{}. (y \mneq{} t {}\mRightarrow{} T\_y(x) \# x + r*e))) 8. \mforall{}x:Point. \mforall{}t:\{t:\mBbbR{}| r0 \mleq{} t\} . \mexists{}r:\{t:\mBbbR{}| r0 \mleq{} t\} . T\_t(x) \mequiv{} x + r*e 9. t : \mBbbR{} 10. h : Point 11. h \mcdot{} e = r0 12. t \mleq{} r0 \mvdash{} T\_t(h) \mequiv{} h + \mrho{}(h;t)*e By Latex: ((InstHyp [\mkleeneopen{}T\_t(h)\mkleeneclose{};\mkleeneopen{}-(t)\mkleeneclose{}] (-5)\mcdot{} THENA Auto) THEN (RWO "6<" (-1) THENA Auto)) Home Index