Proof of Nuprl Lemma : map-as-map-upto

Step * 1 1 2 of Lemma map-as-map-upto

1. F : Top
2. u : Top
3. v : Top List
4. map(λx.F[x];v) ~ map(λi.F[v[i]];upto(||v||))
5. upto(||v|| + 1) ~ upto(1) @ map(λx.(x + 1);upto((||v|| + 1) - 1))
⊢ [0] @ map(λx.(x + 1);upto((||v|| + 1) - 1)) ~ [0 / map(λi.(i + 1);upto(||v||))]
BY
{ (Reduce 0 THEN EqCD) }

1
1. F : Top
2. u : Top
3. v : Top List
4. map(λx.F[x];v) ~ map(λi.F[v[i]];upto(||v||))
5. upto(||v|| + 1) ~ upto(1) @ map(λx.(x + 1);upto((||v|| + 1) - 1))
⊢ 0 ~ 0

2
1. F : Top
2. u : Top
3. v : Top List
4. map(λx.F[x];v) ~ map(λi.F[v[i]];upto(||v||))
5. upto(||v|| + 1) ~ upto(1) @ map(λx.(x + 1);upto((||v|| + 1) - 1))
⊢ map(λx.(x + 1);upto((||v|| + 1) - 1)) ~ map(λi.(i + 1);upto(||v||))

Latex:

Latex:
1. F : Top 2. u : Top 3. v : Top List 4. map(\mlambda{}x.F[x];v) \msim{} map(\mlambda{}i.F[v[i]];upto(||v||)) 5. upto(||v|| + 1) \msim{} upto(1) @ map(\mlambda{}x.(x + 1);upto((||v|| + 1) - 1)) \mvdash{} [0] @ map(\mlambda{}x.(x + 1);upto((||v|| + 1) - 1)) \msim{} [0 / map(\mlambda{}i.(i + 1);upto(||v||))] By Latex: (Reduce 0 THEN EqCD) Home Index