Proof of Nuprl Lemma : odd-lsum-of-odd

Step * 2 2 of Lemma odd-lsum-of-odd

1. T : Type
2. n : ℕ
3. u : T
4. u1 : T
5. v : T List
6. ∀L1:T List
(||L1|| < ||[u; [u1 / v]]||
⇒

 ∀[f:{x:T| (x ∈ L1)}  ⟶ ℤ]. ↑isOdd(Σ(f[x] | x ∈ L1)) supposing (∀x∈L1.↑isOdd(f[x])) supposing ↑isOdd(||L1||))

7. ↑isOdd(||[u; [u1 / v]]||)
8. f : {x:T| (x ∈ [u; [u1 / v]])}  ⟶ ℤ
9. (∀x∈[u; [u1 / v]].↑isOdd(f[x]))
⊢ ↑isOdd(Σ(f[x] | x ∈ [u; [u1 / v]]))
BY
{ DVar `v' }

1
1. T : Type
2. n : ℕ
3. u : T
4. u1 : T
5. ∀L1:T List
     (||L1|| < ||[u; u1]||
     ⇒

 ∀[f:{x:T| (x ∈ L1)}  ⟶ ℤ]. ↑isOdd(Σ(f[x] | x ∈ L1)) supposing (∀x∈L1.↑isOdd(f[x])) supposing ↑isOdd(||L1||))

6. ↑isOdd(||[u; u1]||)
7. f : {x:T| (x ∈ [u; u1])}  ⟶ ℤ
8. (∀x∈[u; u1].↑isOdd(f[x]))
⊢ ↑isOdd(Σ(f[x] | x ∈ [u; u1]))

2
1. T : Type
2. n : ℕ
3. u : T
4. u1 : T
5. u2 : T
6. v : T List
7. ∀L1:T List
     (||L1|| < ||[u; u1; [u2 / v]]||
     ⇒

 ∀[f:{x:T| (x ∈ L1)}  ⟶ ℤ]. ↑isOdd(Σ(f[x] | x ∈ L1)) supposing (∀x∈L1.↑isOdd(f[x])) supposing ↑isOdd(||L1||))

8. ↑isOdd(||[u; u1; [u2 / v]]||)
9. f : {x:T| (x ∈ [u; u1; [u2 / v]])} ⟶ ℤ
10. (∀x∈[u; u1; [u2 / v]].↑isOdd(f[x]))
⊢ ↑isOdd(Σ(f[x] | x ∈ [u; u1; [u2 / v]]))

Latex:

Latex:
1. T : Type 2. n : \mBbbN{} 3. u : T 4. u1 : T 5. v : T List 6. \mforall{}L1:T List (||L1|| < ||[u; [u1 / v]]|| {}\mRightarrow{} \mforall{}[f:\{x:T| (x \mmember{} L1)\} {}\mrightarrow{} \mBbbZ{}]. \muparrow{}isOdd(\mSigma{}(f[x] | x \mmember{} L1)) supposing (\mforall{}x\mmember{}L1.\muparrow{}isOdd(f[x])) supposing \muparrow{}isOdd(||L1||)) 7. \muparrow{}isOdd(||[u; [u1 / v]]||) 8. f : \{x:T| (x \mmember{} [u; [u1 / v]])\} {}\mrightarrow{} \mBbbZ{} 9. (\mforall{}x\mmember{}[u; [u1 / v]].\muparrow{}isOdd(f[x])) \mvdash{} \muparrow{}isOdd(\mSigma{}(f[x] | x \mmember{} [u; [u1 / v]])) By Latex: DVar `v' Home Index