Proof of Nuprl Lemma : es-interface-predecessors-iseg

Step * 1 2 2 1 of Lemma es-interface-predecessors-iseg

1. [Info] : Type
2. es : EO+(Info)@i'
3. X : EClass(Top)@i'
4. e : E(X)@i
5. ∀e1:E(X). ((e1 < e) ⇒ (∀e':E(X). (≤(X)(e') ≤ ≤(X)(e1) ⇐⇒ e' ≤loc e1 )))
6. e' : E(X)@i
7. ¬(e' = e ∈ E(X))
8. e' ≤loc e  ⇐⇒ (↑e ∈_b prior(X)) ∧ e' ≤loc prior(X)(e)
⊢ ≤(X)(e') ≤ ≤(X)(e) ⇐⇒ (↑e ∈_b prior(X)) ∧ e' ≤loc prior(X)(e)
BY
{ ((RW (AddrC [1;3] (LemmaC `es-interface-predecessors-step`)) 0 THENA Auto)
   THEN (SplitOnConclITE THENA Auto)
   THEN Reduce 0)⋅ }

1
1. [Info] : Type
2. es : EO+(Info)@i'
3. X : EClass(Top)@i'
4. e : E(X)@i
5. ∀e1:E(X). ((e1 < e) ⇒ (∀e':E(X). (≤(X)(e') ≤ ≤(X)(e1) ⇐⇒ e' ≤loc e1 )))
6. e' : E(X)@i
7. ¬(e' = e ∈ E(X))
8. e' ≤loc e  ⇐⇒ (↑e ∈_b prior(X)) ∧ e' ≤loc prior(X)(e)
9. ↑e ∈_b prior(X)
⊢ ≤(X)(e') ≤ ≤(X)(prior(X)(e)) @ [e] ⇐⇒ True ∧ e' ≤loc prior(X)(e)

2
1. [Info] : Type
2. es : EO+(Info)@i'
3. X : EClass(Top)@i'
4. e : E(X)@i
5. ∀e1:E(X). ((e1 < e) ⇒ (∀e':E(X). (≤(X)(e') ≤ ≤(X)(e1) ⇐⇒ e' ≤loc e1 )))
6. e' : E(X)@i
7. ¬(e' = e ∈ E(X))
8. e' ≤loc e  ⇐⇒ (↑e ∈_b prior(X)) ∧ e' ≤loc prior(X)(e)
9. ¬↑e ∈_b prior(X)
⊢ ≤(X)(e') ≤ [e] ⇐⇒ False ∧ e' ≤loc prior(X)(e)

Latex:

Latex:
1. [Info] : Type 2. es : EO+(Info)@i' 3. X : EClass(Top)@i' 4. e : E(X)@i 5. \mforall{}e1:E(X). ((e1 < e) {}\mRightarrow{} (\mforall{}e':E(X). (\mleq{}(X)(e') \mleq{} \mleq{}(X)(e1) \mLeftarrow{}{}\mRightarrow{} e' \mleq{}loc e1 ))) 6. e' : E(X)@i 7. \mneg{}(e' = e) 8. e' \mleq{}loc e \mLeftarrow{}{}\mRightarrow{} (\muparrow{}e \mmember{}\msubb{} prior(X)) \mwedge{} e' \mleq{}loc prior(X)(e) \mvdash{} \mleq{}(X)(e') \mleq{} \mleq{}(X)(e) \mLeftarrow{}{}\mRightarrow{} (\muparrow{}e \mmember{}\msubb{} prior(X)) \mwedge{} e' \mleq{}loc prior(X)(e) By Latex: ((RW (AddrC [1;3] (LemmaC `es-interface-predecessors-step`)) 0 THENA Auto) THEN (SplitOnConclITE THENA Auto) THEN Reduce 0)\mcdot{} Home Index