Proof of Nuprl Lemma : es-cut-induction-ordered

Step * 1 1 1 2 of Lemma es-cut-induction-ordered

1. [Info] : Type
2. es : EO+(Info)@i'
3. X : EClass(Top)@i'
4. f : sys-antecedent(es;X)@i
5. [P] : Cut(X;f) ─→ ℙ
6. ∃R:E(X) ─→ E(X) ─→ ℙ. (Linorder(E(X);x,y.R[x;y]) ∧ (∀x,y:E(X). Dec(R[x;y])))@i'
7. P[{}]@i
8. ∀c:Cut(X;f). ∀e:E(X).
(P[c] ⇒

 (P[c+e]) supposing (prior(X)(e) ∈ c supposing ↑e ∈_b prior(X) and f e ∈ c supposing ¬((f e) = e ∈ E(X))))@i

9. es-eq(es) ∈ EqDecider(E(X))
10. n : ℕ
11. ∀n:ℕn. ∀c:Cut(X;f).  ((||c|| ≤ n) ⇒ P[c])@i
12. c : Cut(X;f)@i
13. ||c|| ≤ n@i
14. ¬(c = {} ∈ fset(E(X)))
⊢ P[c]
BY
{ Assert ⌈∀e:E(X)
            (e ∈ c
            ⇒ (∀e':E(X). (e' ∈ c ⇒ (e = (X-pred e') ∈ E(X)) ⇒ (e' = e ∈ E(X))))
            ⇒ (∀e':E(X). (e' ∈ c ⇒ (e = (f e') ∈ E(X)) ⇒ (e' = e ∈ E(X))))
            ⇒ P[c])⌉⋅ }

1
.....assertion.....
1. [Info] : Type
2. es : EO+(Info)@i'
3. X : EClass(Top)@i'
4. f : sys-antecedent(es;X)@i
5. [P] : Cut(X;f) ─→ ℙ
6. ∃R:E(X) ─→ E(X) ─→ ℙ. (Linorder(E(X);x,y.R[x;y]) ∧ (∀x,y:E(X).  Dec(R[x;y])))@i'
7. P[{}]@i
8. ∀c:Cut(X;f). ∀e:E(X).
     (P[c] ⇒

 (P[c+e]) supposing (prior(X)(e) ∈ c supposing ↑e ∈_b prior(X) and f e ∈ c supposing ¬((f e) = e ∈ E(X))))@i

9. es-eq(es) ∈ EqDecider(E(X))
10. n : ℕ
11. ∀n:ℕn. ∀c:Cut(X;f).  ((||c|| ≤ n) ⇒ P[c])@i
12. c : Cut(X;f)@i
13. ||c|| ≤ n@i
14. ¬(c = {} ∈ fset(E(X)))
⊢ ∀e:E(X)
    (e ∈ c
    ⇒ (∀e':E(X). (e' ∈ c ⇒ (e = (X-pred e') ∈ E(X)) ⇒ (e' = e ∈ E(X))))
    ⇒ (∀e':E(X). (e' ∈ c ⇒ (e = (f e') ∈ E(X)) ⇒ (e' = e ∈ E(X))))
    ⇒ P[c])

2
1. [Info] : Type
2. es : EO+(Info)@i'
3. X : EClass(Top)@i'
4. f : sys-antecedent(es;X)@i
5. [P] : Cut(X;f) ─→ ℙ
6. ∃R:E(X) ─→ E(X) ─→ ℙ. (Linorder(E(X);x,y.R[x;y]) ∧ (∀x,y:E(X).  Dec(R[x;y])))@i'
7. P[{}]@i
8. ∀c:Cut(X;f). ∀e:E(X).
     (P[c] ⇒

 (P[c+e]) supposing (prior(X)(e) ∈ c supposing ↑e ∈_b prior(X) and f e ∈ c supposing ¬((f e) = e ∈ E(X))))@i

9. es-eq(es) ∈ EqDecider(E(X))
10. n : ℕ
11. ∀n:ℕn. ∀c:Cut(X;f).  ((||c|| ≤ n) ⇒ P[c])@i
12. c : Cut(X;f)@i
13. ||c|| ≤ n@i
14. ¬(c = {} ∈ fset(E(X)))
15. ∀e:E(X)
      (e ∈ c
      ⇒ (∀e':E(X). (e' ∈ c ⇒ (e = (X-pred e') ∈ E(X)) ⇒ (e' = e ∈ E(X))))
      ⇒ (∀e':E(X). (e' ∈ c ⇒ (e = (f e') ∈ E(X)) ⇒ (e' = e ∈ E(X))))
      ⇒ P[c])
⊢ P[c]

Latex:

Latex:
1. [Info] : Type 2. es : EO+(Info)@i' 3. X : EClass(Top)@i' 4. f : sys-antecedent(es;X)@i 5. [P] : Cut(X;f) {}\mrightarrow{} \mBbbP{} 6. \mexists{}R:E(X) {}\mrightarrow{} E(X) {}\mrightarrow{} \mBbbP{}. (Linorder(E(X);x,y.R[x;y]) \mwedge{} (\mforall{}x,y:E(X). Dec(R[x;y])))@i' 7. P[\{\}]@i 8. \mforall{}c:Cut(X;f). \mforall{}e:E(X). (P[c] {}\mRightarrow{} (P[c+e]) supposing (prior(X)(e) \mmember{} c supposing \muparrow{}e \mmember{}\msubb{} prior(X) and f e \mmember{} c supposing \mneg{}((f e) = e)))@i 9. es-eq(es) \mmember{} EqDecider(E(X)) 10. n : \mBbbN{} 11. \mforall{}n:\mBbbN{}n. \mforall{}c:Cut(X;f). ((||c|| \mleq{} n) {}\mRightarrow{} P[c])@i 12. c : Cut(X;f)@i 13. ||c|| \mleq{} n@i 14. \mneg{}(c = \{\}) \mvdash{} P[c] By Latex: Assert \mkleeneopen{}\mforall{}e:E(X) (e \mmember{} c {}\mRightarrow{} (\mforall{}e':E(X). (e' \mmember{} c {}\mRightarrow{} (e = (X-pred e')) {}\mRightarrow{} (e' = e))) {}\mRightarrow{} (\mforall{}e':E(X). (e' \mmember{} c {}\mRightarrow{} (e = (f e')) {}\mRightarrow{} (e' = e))) {}\mRightarrow{} P[c])\mkleeneclose{}\mcdot{} Home Index