Proof of Nuprl Lemma : fun-path-append

Step * 2 1 1 1 1 of Lemma fun-path-append

.....equality.....
1. T : Type
2. f : T ⟶ T
3. u : T
4. v : T List

5. ∀[L2:T List]. ∀[x,y,z:T].  uiff(z=f*(x) via v @ [y / L2];{y=f*(x) via [y / L2] ∧ z=f*(y) via v @ [y]})

6. L2 : T List
7. ∀[x,y,z:T]. uiff(z=f*(x) via v @ [y / L2];{y=f*(x) via [y / L2] ∧ z=f*(y) via v @ [y]})
8. x : T
9. ∀[y,z:T]. uiff(z=f*(x) via v @ [y / L2];{y=f*(x) via [y / L2] ∧ z=f*(y) via v @ [y]})
10. y : T
11. z : T
12. {(z = u ∈ T)

∧ ((u = (f hd(v @ [y / L2])) ∈ T) ∧ (¬(u = hd(v @ [y / L2]) ∈ T))) ∧ hd(v @ [y / L2])=f*(x) via v @ [y / L2]

supposing 0 < ||v @ [y / L2]||
∧ x = u ∈ T supposing ¬0 < ||v @ [y / L2]||}
⊢ hd(v @ [y / L2]) ~ hd(v @ [y])
BY
{ ((DVar `v' THEN Reduce 0) THEN Auto) }

Latex:

Latex:
.....equality..... 1. T : Type 2. f : T {}\mrightarrow{} T 3. u : T 4. v : T List 5. \mforall{}[L2:T List]. \mforall{}[x,y,z:T]. uiff(z=f*(x) via v @ [y / L2];\{y=f*(x) via [y / L2] \mwedge{} z=f*(y) via v @ [y]\}) 6. L2 : T List 7. \mforall{}[x,y,z:T]. uiff(z=f*(x) via v @ [y / L2];\{y=f*(x) via [y / L2] \mwedge{} z=f*(y) via v @ [y]\}) 8. x : T 9. \mforall{}[y,z:T]. uiff(z=f*(x) via v @ [y / L2];\{y=f*(x) via [y / L2] \mwedge{} z=f*(y) via v @ [y]\}) 10. y : T 11. z : T 12. \{(z = u) \mwedge{} ((u = (f hd(v @ [y / L2]))) \mwedge{} (\mneg{}(u = hd(v @ [y / L2])))) \mwedge{} hd(v @ [y / L2])=f*(x) via v @ [y / L2] supposing 0 < ||v @ [y / L2]|| \mwedge{} x = u supposing \mneg{}0 < ||v @ [y / L2]||\} \mvdash{} hd(v @ [y / L2]) \msim{} hd(v @ [y]) By Latex: ((DVar `v' THEN Reduce 0) THEN Auto) Home Index