Proof of Nuprl Lemma : fps-geometric-slice

Step * 1 1 1 of Lemma fps-geometric-slice_lemma

.....assertion.....
1. X : Type
2. valueall-type(X)
3. eq : EqDecider(X)
4. r : CRng
5. m : ℕ
6. n : ℕ⁺m + 1
7. g : PowerSeries(X;r)
8. g = [g]_n ∈ PowerSeries(X;r)
9. IsRing(PowerSeries(X;r);λf,g. (f+g);0;λf.-(f);λf,g. (f*g);1)
10. 0 = fps-summation(r;upto(m + 1);k.([(1-g)]_k*[(1÷(1-g))]_m - k)) ∈ PowerSeries(X;r)
⊢ fps-summation(r;upto(m + 1);k.([(1-g)]_k*[(1÷(1-g))]_m - k))
= fps-summation(r;[k∈upto(m + 1)|(k =_z 0) ∨_b(k =_z n)];k.([(1-g)]_k*[(1÷(1-g))]_m - k))
∈ PowerSeries(X;r)
BY
{ xxx((NthHypEq (-1) THEN EqCD THEN Auto) THEN Thin (-1))xxx }

1
1. X : Type
2. valueall-type(X)
3. eq : EqDecider(X)
4. r : CRng
5. m : ℕ
6. n : ℕ⁺m + 1
7. g : PowerSeries(X;r)
8. g = [g]_n ∈ PowerSeries(X;r)
9. IsRing(PowerSeries(X;r);λf,g. (f+g);0;λf.-(f);λf,g. (f*g);1)
⊢ fps-summation(r;[k∈upto(m + 1)|(k =_z 0) ∨_b(k =_z n)];k.([(1-g)]_k*[(1÷(1-g))]_m - k))
= fps-summation(r;upto(m + 1);k.([(1-g)]_k*[(1÷(1-g))]_m - k))
∈ PowerSeries(X;r)

Latex:

Latex:
.....assertion..... 1. X : Type 2. valueall-type(X) 3. eq : EqDecider(X) 4. r : CRng 5. m : \mBbbN{} 6. n : \mBbbN{}\msupplus{}m + 1 7. g : PowerSeries(X;r) 8. g = [g]\_n 9. IsRing(PowerSeries(X;r);\mlambda{}f,g. (f+g);0;\mlambda{}f.-(f);\mlambda{}f,g. (f*g);1) 10. 0 = fps-summation(r;upto(m + 1);k.([(1-g)]\_k*[(1\mdiv{}(1-g))]\_m - k)) \mvdash{} fps-summation(r;upto(m + 1);k.([(1-g)]\_k*[(1\mdiv{}(1-g))]\_m - k)) = fps-summation(r;[k\mmember{}upto(m + 1)|(k =\msubz{} 0) \mvee{}\msubb{}(k =\msubz{} n)];k.([(1-g)]\_k*[(1\mdiv{}(1-g))]\_m - k)) By Latex: xxx((NthHypEq (-1) THEN EqCD THEN Auto) THEN Thin (-1))xxx Home Index