Proof of Nuprl Lemma : trans-from-kernel-is-trans

Step * 1 1 2 of Lemma trans-from-kernel-is-trans

1. rv : InnerProductSpace
2. e : {e:Point(rv)| e^2 = r1}
3. f : {h:Point(rv)| h ⋅ e = r0}  ⟶ ℝ ⟶ ℝ
4. g : {h:Point(rv)| h ⋅ e = r0}  ⟶ ℝ ⟶ ℝ
5. e^2 = r1
6. ∀h1,h2:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  (f h1 t1 ≠ f h2 t2 ⇒ (h1 # h2 ∨ t1 ≠ t2))
7. ∀h:{h:Point(rv)| h ⋅ e = r0} . ((f h r0) = r0)
8. ∀h:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  ((t1 < t2) ⇒ ((f h t1) < (f h t2)))
9. ∀h:{h:Point(rv)| h ⋅ e = r0} . ∀r:ℝ.  ∃t:ℝ. ((f h t) = r)
10. ∀h:{h:Point(rv)| h ⋅ e = r0} . ∀r:ℝ.  ((f h (g h r)) = r)
11. ∀h1,h2:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  (h1 ≡ h2 ⇒ (t1 = t2) ⇒ ((f h1 t1) = (f h2 t2)))
12. ∀h1,h2:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  (g h1 t1 ≠ g h2 t2 ⇒ (h1 # h2 ∨ t1 ≠ t2))
13. ∀h1,h2:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  (h1 ≡ h2 ⇒ (t1 = t2) ⇒ ((g h1 t1) = (g h2 t2)))
14. ∀y:Point(rv). (y - y ⋅ e*e ∈ {h:Point(rv)| h ⋅ e = r0} )

15. ∀h:{h:Point(rv)| h ⋅ e = r0} . ∀tau,t:ℝ.  trans-from-kernel(rv;e;f;g;t;h + f h tau*e) ≡ h + f h (tau + t)*e

⊢ translation-group-fun(rv;e;λt,x. trans-from-kernel(rv;e;f;g;t;x))
BY
{ (Assert ∀x:Point(rv). ∃h:{h:Point(rv)| h ⋅ e = r0} . ∃tau:ℝ. x ≡ h + f h tau*e BY
((D 0 THENA Auto)

          THEN InstConcl [⌜fst(rv-decomp(rv;x;e))⌝;⌜g (fst(rv-decomp(rv;x;e))) (snd(rv-decomp(rv;x;e)))⌝]⋅

          THEN Auto
          THEN (GenConclTerm ⌜rv-decomp(rv;x;e)⌝⋅ THENA Auto)
          THEN RepeatFor 2 (DVar `v')
          THEN All Reduce
          THEN (Unhide THENA Auto)
          THEN RWO "10" 0
          THEN Auto)) }

1
1. rv : InnerProductSpace
2. e : {e:Point(rv)| e^2 = r1}
3. f : {h:Point(rv)| h ⋅ e = r0}  ⟶ ℝ ⟶ ℝ
4. g : {h:Point(rv)| h ⋅ e = r0}  ⟶ ℝ ⟶ ℝ
5. e^2 = r1
6. ∀h1,h2:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  (f h1 t1 ≠ f h2 t2 ⇒ (h1 # h2 ∨ t1 ≠ t2))
7. ∀h:{h:Point(rv)| h ⋅ e = r0} . ((f h r0) = r0)
8. ∀h:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  ((t1 < t2) ⇒ ((f h t1) < (f h t2)))
9. ∀h:{h:Point(rv)| h ⋅ e = r0} . ∀r:ℝ.  ∃t:ℝ. ((f h t) = r)
10. ∀h:{h:Point(rv)| h ⋅ e = r0} . ∀r:ℝ.  ((f h (g h r)) = r)
11. ∀h1,h2:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  (h1 ≡ h2 ⇒ (t1 = t2) ⇒ ((f h1 t1) = (f h2 t2)))
12. ∀h1,h2:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  (g h1 t1 ≠ g h2 t2 ⇒ (h1 # h2 ∨ t1 ≠ t2))
13. ∀h1,h2:{h:Point(rv)| h ⋅ e = r0} . ∀t1,t2:ℝ.  (h1 ≡ h2 ⇒ (t1 = t2) ⇒ ((g h1 t1) = (g h2 t2)))
14. ∀y:Point(rv). (y - y ⋅ e*e ∈ {h:Point(rv)| h ⋅ e = r0} )

15. ∀h:{h:Point(rv)| h ⋅ e = r0} . ∀tau,t:ℝ.  trans-from-kernel(rv;e;f;g;t;h + f h tau*e) ≡ h + f h (tau + t)*e

16. ∀x:Point(rv). ∃h:{h:Point(rv)| h ⋅ e = r0} . ∃tau:ℝ. x ≡ h + f h tau*e
⊢ translation-group-fun(rv;e;λt,x. trans-from-kernel(rv;e;f;g;t;x))

Latex:

Latex:
1. rv : InnerProductSpace 2. e : \{e:Point(rv)| e\^{}2 = r1\} 3. f : \{h:Point(rv)| h \mcdot{} e = r0\} {}\mrightarrow{} \mBbbR{} {}\mrightarrow{} \mBbbR{} 4. g : \{h:Point(rv)| h \mcdot{} e = r0\} {}\mrightarrow{} \mBbbR{} {}\mrightarrow{} \mBbbR{} 5. e\^{}2 = r1 6. \mforall{}h1,h2:\{h:Point(rv)| h \mcdot{} e = r0\} . \mforall{}t1,t2:\mBbbR{}. (f h1 t1 \mneq{} f h2 t2 {}\mRightarrow{} (h1 \# h2 \mvee{} t1 \mneq{} t2)) 7. \mforall{}h:\{h:Point(rv)| h \mcdot{} e = r0\} . ((f h r0) = r0) 8. \mforall{}h:\{h:Point(rv)| h \mcdot{} e = r0\} . \mforall{}t1,t2:\mBbbR{}. ((t1 < t2) {}\mRightarrow{} ((f h t1) < (f h t2))) 9. \mforall{}h:\{h:Point(rv)| h \mcdot{} e = r0\} . \mforall{}r:\mBbbR{}. \mexists{}t:\mBbbR{}. ((f h t) = r) 10. \mforall{}h:\{h:Point(rv)| h \mcdot{} e = r0\} . \mforall{}r:\mBbbR{}. ((f h (g h r)) = r) 11. \mforall{}h1,h2:\{h:Point(rv)| h \mcdot{} e = r0\} . \mforall{}t1,t2:\mBbbR{}. (h1 \mequiv{} h2 {}\mRightarrow{} (t1 = t2) {}\mRightarrow{} ((f h1 t1) = (f h2 t2))) 12. \mforall{}h1,h2:\{h:Point(rv)| h \mcdot{} e = r0\} . \mforall{}t1,t2:\mBbbR{}. (g h1 t1 \mneq{} g h2 t2 {}\mRightarrow{} (h1 \# h2 \mvee{} t1 \mneq{} t2)) 13. \mforall{}h1,h2:\{h:Point(rv)| h \mcdot{} e = r0\} . \mforall{}t1,t2:\mBbbR{}. (h1 \mequiv{} h2 {}\mRightarrow{} (t1 = t2) {}\mRightarrow{} ((g h1 t1) = (g h2 t2))) 14. \mforall{}y:Point(rv). (y - y \mcdot{} e*e \mmember{} \{h:Point(rv)| h \mcdot{} e = r0\} ) 15. \mforall{}h:\{h:Point(rv)| h \mcdot{} e = r0\} . \mforall{}tau,t:\mBbbR{}. trans-from-kernel(rv;e;f;g;t;h + f h tau*e) \mequiv{} h + f h (tau + t)*e \mvdash{} translation-group-fun(rv;e;\mlambda{}t,x. trans-from-kernel(rv;e;f;g;t;x)) By Latex: (Assert \mforall{}x:Point(rv). \mexists{}h:\{h:Point(rv)| h \mcdot{} e = r0\} . \mexists{}tau:\mBbbR{}. x \mequiv{} h + f h tau*e BY ((D 0 THENA Auto) THEN InstConcl [\mkleeneopen{}fst(rv-decomp(rv;x;e))\mkleeneclose{};\mkleeneopen{}g (fst(rv-decomp(rv;x;e))) (snd(rv-decomp(rv;x;e)))\mkleeneclose{}]\mcdot{} THEN Auto THEN (GenConclTerm \mkleeneopen{}rv-decomp(rv;x;e)\mkleeneclose{}\mcdot{} THENA Auto) THEN RepeatFor 2 (DVar `v') THEN All Reduce THEN (Unhide THENA Auto) THEN RWO "10" 0 THEN Auto)) Home Index