Proof of Nuprl Lemma : bag-summation-linear1

Step * 1 of Lemma bag-summation-linear1

1. T : Type
2. R : Type
3. add : R ⟶ R ⟶ R
4. mul : R ⟶ R ⟶ R
5. zero : R
6. b : bag(T)
7. f : T ⟶ R
8. ∀[g:T ⟶ R]

     ∀a:R. (Σ(x∈b). a mul (f[x] add g[x]) = (a mul (Σ(x∈b). f[x] add Σ(x∈b). g[x])) ∈ R)

supposing (∃minus:R ⟶ R. IsGroup(R;add;zero;minus)) ∧ Comm(R;add) ∧ BiLinear(R;add;mul)
9. minus : R ⟶ R
10. IsGroup(R;add;zero;minus)
11. Comm(R;add)
12. BiLinear(R;add;mul)
13. a : R
14. Σ(x∈b). a mul (f[x] add zero) = (a mul (Σ(x∈b). f[x] add Σ(x∈b). zero)) ∈ R
15. x : T
⊢ (a mul f[x]) = (a mul (f[x] add zero)) ∈ R
BY
{ (EqCD THEN Auto) }

1
.....subterm..... T:t
3:n
1. T : Type
2. R : Type
3. add : R ⟶ R ⟶ R
4. mul : R ⟶ R ⟶ R
5. zero : R
6. b : bag(T)
7. f : T ⟶ R
8. ∀[g:T ⟶ R]

     ∀a:R. (Σ(x∈b). a mul (f[x] add g[x]) = (a mul (Σ(x∈b). f[x] add Σ(x∈b). g[x])) ∈ R)

Latex:

Latex:
1. T : Type 2. R : Type 3. add : R {}\mrightarrow{} R {}\mrightarrow{} R 4. mul : R {}\mrightarrow{} R {}\mrightarrow{} R 5. zero : R 6. b : bag(T) 7. f : T {}\mrightarrow{} R 8. \mforall{}[g:T {}\mrightarrow{} R] \mforall{}a:R. (\mSigma{}(x\mmember{}b). a mul (f[x] add g[x]) = (a mul (\mSigma{}(x\mmember{}b). f[x] add \mSigma{}(x\mmember{}b). g[x]))) supposing (\mexists{}minus:R {}\mrightarrow{} R. IsGroup(R;add;zero;minus)) \mwedge{} Comm(R;add) \mwedge{} BiLinear(R;add;mul) 9. minus : R {}\mrightarrow{} R 10. IsGroup(R;add;zero;minus) 11. Comm(R;add) 12. BiLinear(R;add;mul) 13. a : R 14. \mSigma{}(x\mmember{}b). a mul (f[x] add zero) = (a mul (\mSigma{}(x\mmember{}b). f[x] add \mSigma{}(x\mmember{}b). zero)) 15. x : T \mvdash{} (a mul f[x]) = (a mul (f[x] add zero)) By Latex: (EqCD THEN Auto) Home Index