Proof of Nuprl Lemma : fps-compose-mul

Step * 1 2 1 1 3 2 1 1 of Lemma fps-compose-mul

1. X : Type
2. valueall-type(X)
3. eq : EqDecider(X)
4. r : CRng
5. x : X
6. g : PowerSeries(X;r)
7. f : PowerSeries(X;r)
8. h : PowerSeries(X;r)
9. ∀L:bag(X) List⁺. (||L|| ≥ 1 )
10. Assoc(|r|;+r)
11. IsMonoid(|r|;+r;0)
12. Comm(|r|;+r)
13. Comm(|r|;*)
14. Assoc(|r|;*)
15. ∀L:bag(X) List⁺. (Πa ∈ tl(L). f a ∈ |r|)
16. b : bag(X)
17. x@0 : bag(X) List⁺ × bag(X) × bag(X)
18. x@0 ↓∈ ⋃L∈bag-parts'(eq;b;x).bag-map(λp.<L, p>;bag-partitions(eq;hd(L) + bag-rep(||tl(L)||;x)))
⊢ ((* (g (fst(snd(x@0)))) (h (snd(snd(x@0))))) * Πa ∈ tl(fst(x@0)). f a)
= (((g
     (hd(fst(let L,b1,b2 = x@0 in
     <[(b1|¬x) / firstn(#((b1|x));tl(L))], [(b2|¬x) / nth_tl(#((b1|x));tl(L))]>))
     + bag-rep(||tl(fst(let L,b1,b2 = x@0 in
       <[(b1|¬x) / firstn(#((b1|x));tl(L))], [(b2|¬x) / nth_tl(#((b1|x));tl(L))]>))||;x)))
    *
    Πa ∈ tl(fst(let L,b1,b2 = x@0 in
    <[(b1|¬x) / firstn(#((b1|x));tl(L))], [(b2|¬x) / nth_tl(#((b1|x));tl(L))]>)). f a)
   *
   ((h
     (hd(snd(let L,b1,b2 = x@0 in
     <[(b1|¬x) / firstn(#((b1|x));tl(L))], [(b2|¬x) / nth_tl(#((b1|x));tl(L))]>))
     + bag-rep(||tl(snd(let L,b1,b2 = x@0 in
       <[(b1|¬x) / firstn(#((b1|x));tl(L))], [(b2|¬x) / nth_tl(#((b1|x));tl(L))]>))||;x)))
    *
    Πa ∈ tl(snd(let L,b1,b2 = x@0 in
    <[(b1|¬x) / firstn(#((b1|x));tl(L))], [(b2|¬x) / nth_tl(#((b1|x));tl(L))]>)). f a))
∈ |r|
BY

{ TACTIC:(D (-2) THEN RenameVar `L' (-3)⋅ THEN D -2 THEN RenameVar `as' (-3) THEN RenameVar `bs' (-2) THEN Reduce 0) }

1
1. X : Type
2. valueall-type(X)
3. eq : EqDecider(X)
4. r : CRng
5. x : X
6. g : PowerSeries(X;r)
7. f : PowerSeries(X;r)
8. h : PowerSeries(X;r)
9. ∀L:bag(X) List⁺. (||L|| ≥ 1 )
10. Assoc(|r|;+r)
11. IsMonoid(|r|;+r;0)
12. Comm(|r|;+r)
13. Comm(|r|;*)
14. Assoc(|r|;*)
15. ∀L:bag(X) List⁺. (Πa ∈ tl(L). f a ∈ |r|)
16. b : bag(X)
17. L : bag(X) List⁺
18. as : bag(X)
19. bs : bag(X)

20. <L, as, bs> ↓∈ ⋃L∈bag-parts'(eq;b;x).bag-map(λp.<L, p>;bag-partitions(eq;hd(L) + bag-rep(||tl(L)||;x)))

⊢ ((* (g as) (h bs)) * Πa ∈ tl(L). f a)
= (((g ((as|¬x) + bag-rep(||firstn(#((as|x));tl(L))||;x))) * Πa ∈ firstn(#((as|x));tl(L)). f a)
*
((h ((bs|¬x) + bag-rep(||nth_tl(#((as|x));tl(L))||;x))) * Πa ∈ nth_tl(#((as|x));tl(L)). f a))
∈ |r|

Latex:

Latex:
1. X : Type 2. valueall-type(X) 3. eq : EqDecider(X) 4. r : CRng 5. x : X 6. g : PowerSeries(X;r) 7. f : PowerSeries(X;r) 8. h : PowerSeries(X;r) 9. \mforall{}L:bag(X) List\msupplus{}. (||L|| \mgeq{} 1 ) 10. Assoc(|r|;+r) 11. IsMonoid(|r|;+r;0) 12. Comm(|r|;+r) 13. Comm(|r|;*) 14. Assoc(|r|;*) 15. \mforall{}L:bag(X) List\msupplus{}. (\mPi{}a \mmember{} tl(L). f a \mmember{} |r|) 16. b : bag(X) 17. x@0 : bag(X) List\msupplus{} \mtimes{} bag(X) \mtimes{} bag(X) 18. x@0 \mdownarrow{}\mmember{} \mcup{}L\mmember{}bag-parts'(eq;b;x).bag-map(\mlambda{}p.<L, p>bag-partitions(eq;hd(L) + bag-rep(||tl(L)||;x))) \mvdash{} ((* (g (fst(snd(x@0)))) (h (snd(snd(x@0))))) * \mPi{}a \mmember{} tl(fst(x@0)). f a) = (((g (hd(fst(let L,b1,b2 = x@0 in <[(b1|\mneg{}x) / firstn(\#((b1|x));tl(L))], [(b2|\mneg{}x) / nth\_tl(\#((b1|x));tl(L))]>)) + bag-rep(||tl(fst(let L,b1,b2 = x@0 in <[(b1|\mneg{}x) / firstn(\#((b1|x));tl(L))], [(b2|\mneg{}x) / nth\_tl(\#((b1|x));tl(L))]>))||;x))) * \mPi{}a \mmember{} tl(fst(let L,b1,b2 = x@0 in <[(b1|\mneg{}x) / firstn(\#((b1|x));tl(L))], [(b2|\mneg{}x) / nth\_tl(\#((b1|x));tl(L))]>)). f a) * ((h (hd(snd(let L,b1,b2 = x@0 in <[(b1|\mneg{}x) / firstn(\#((b1|x));tl(L))], [(b2|\mneg{}x) / nth\_tl(\#((b1|x));tl(L))]>)) + bag-rep(||tl(snd(let L,b1,b2 = x@0 in <[(b1|\mneg{}x) / firstn(\#((b1|x));tl(L))], [(b2|\mneg{}x) / nth\_tl(\#((b1|x));tl(L))]>))||;x))) * \mPi{}a \mmember{} tl(snd(let L,b1,b2 = x@0 in <[(b1|\mneg{}x) / firstn(\#((b1|x));tl(L))], [(b2|\mneg{}x) / nth\_tl(\#((b1|x));tl(L))]>)). f a)) By Latex: TACTIC:(D (-2) THEN RenameVar `L' (-3)\mcdot{} THEN D -2 THEN RenameVar `as' (-3) THEN RenameVar `bs' (-2) THEN Reduce 0) Home Index