Nuprl Lemma : l_tree-definition

∀[L,T,A:Type]. ∀[R:A ─→ l_tree(L;T) ─→ ℙ].
  ((∀val:L. {x:A| R[x;l_tree_leaf(val)]} )
  ⇒ (∀val:T. ∀left_subtree,right_subtree:l_tree(L;T).
        ({x:A| R[x;left_subtree]}
        ⇒ {x:A| R[x;right_subtree]}
        ⇒ {x:A| R[x;l_tree_node(val;left_subtree;right_subtree)]} ))
  ⇒ {∀v:l_tree(L;T). {x:A| R[x;v]} })

Proof

Definitions occuring in Statement : l_tree_node: l_tree_node(val;left_subtree;right_subtree), l_tree_leaf: l_tree_leaf(val), l_tree: l_tree(L;T), uall: ∀[x:A]. B[x], prop: ℙ, guard: {T}, so_apply: x[s1;s2], all: ∀x:A. B[x], implies: P ⇒ Q, set: {x:A| B[x]} , function: x:A ─→ B[x], universe: Type
Lemmas : l_tree-induction, set_wf, l_tree_wf, all_wf, l_tree_node_wf, l_tree_leaf_wf
\mforall{}[L,T,A:Type]. \mforall{}[R:A {}\mrightarrow{} l\_tree(L;T) {}\mrightarrow{} \mBbbP{}]. ((\mforall{}val:L. \{x:A| R[x;l\_tree\_leaf(val)]\} ) {}\mRightarrow{} (\mforall{}val:T. \mforall{}left$_{subtree}$,right$_{subtree}$:l\_tree(L;T\000C). (\{x:A| R[x;left$_{subtree}$]\} {}\mRightarrow{} \{x:A| R[x;right$_{subtree}$]\} {}\mRightarrow{} \{x:A| R[x;l\_tree\_node(val;left$_{subtree}$;right$_{subtre\000Ce}$)]\} )) {}\mRightarrow{} \{\mforall{}v:l\_tree(L;T). \{x:A| R[x;v]\} \}) Date html generated: 2015_07_17-AM-07_41_40 Last ObjectModification: 2015_01_27-AM-09_31_14 Home Index