Proof of Nuprl Lemma : es-interface-equality-prior-recursion

Step * 1 1 1 of Lemma es-interface-equality-prior-recursion

1. Info : Type
2. T : Type
3. X : EClass(T)
4. Y : EClass(T)
5. ∀es:EO+(Info). ∀e:E.  ((((X)' es e) = ((Y)' es e) ∈ bag(T)) ⇒ ((X es e) = (Y es e) ∈ bag(T)))
6. es : EO+(Info)@i'
7. e : E@i
8. ∀e':E. ((e' < e) ⇒ ((X es e') = (Y es e') ∈ bag(T)))@i
9. ↑e ∈_b prior(X)
10. ↑e ∈_b prior(Y)
11. prior(X)(e) ∈ E
12. prior(Y)(e) ∈ E
⊢ {X(prior(X)(e))} = {Y(prior(Y)(e))} ∈ bag(T)
BY
{ (InstLemma `es-prior-interface-equal`[⌈Info⌉;⌈es⌉;⌈X⌉;⌈Y⌉;⌈e⌉]⋅
   THEN Auto
   THEN Try ((All (RepUR ``in-eclass can-apply``) THEN RWO "8 8<" (-1) THEN Auto)⋅)
   THEN EqCD
   THEN Auto) }

1
.....subterm..... T:t
1:n
1. Info : Type
2. T : Type
3. X : EClass(T)
4. Y : EClass(T)
5. ∀es:EO+(Info). ∀e:E.  ((((X)' es e) = ((Y)' es e) ∈ bag(T)) ⇒ ((X es e) = (Y es e) ∈ bag(T)))
6. es : EO+(Info)@i'
7. e : E@i
8. ∀e':E. ((e' < e) ⇒ ((X es e') = (Y es e') ∈ bag(T)))@i
9. ↑e ∈_b prior(X)
10. ↑e ∈_b prior(Y)
11. prior(X)(e) ∈ E
12. prior(Y)(e) ∈ E
13. prior(X)(e) = prior(Y)(e) ∈ E
⊢ X(prior(X)(e)) = Y(prior(Y)(e)) ∈ T

Latex:

Latex:
1. Info : Type 2. T : Type 3. X : EClass(T) 4. Y : EClass(T) 5. \mforall{}es:EO+(Info). \mforall{}e:E. ((((X)' es e) = ((Y)' es e)) {}\mRightarrow{} ((X es e) = (Y es e))) 6. es : EO+(Info)@i' 7. e : E@i 8. \mforall{}e':E. ((e' < e) {}\mRightarrow{} ((X es e') = (Y es e')))@i 9. \muparrow{}e \mmember{}\msubb{} prior(X) 10. \muparrow{}e \mmember{}\msubb{} prior(Y) 11. prior(X)(e) \mmember{} E 12. prior(Y)(e) \mmember{} E \mvdash{} \{X(prior(X)(e))\} = \{Y(prior(Y)(e))\} By Latex: (InstLemma `es-prior-interface-equal`[\mkleeneopen{}Info\mkleeneclose{};\mkleeneopen{}es\mkleeneclose{};\mkleeneopen{}X\mkleeneclose{};\mkleeneopen{}Y\mkleeneclose{};\mkleeneopen{}e\mkleeneclose{}]\mcdot{} THEN Auto THEN Try ((All (RepUR ``in-eclass can-apply``) THEN RWO "8 8<" (-1) THEN Auto)\mcdot{}) THEN EqCD THEN Auto) Home Index