Proof of Nuprl Lemma : generated-subspace-is-subspace

Step * 2 1 of Lemma generated-subspace-is-subspace

1. K : Rng
2. vs : VectorSpace(K)
3. [P] : Point(vs) ⟶ ℙ
4. w : Point(vs)
5. y : Point(vs)
6. t : l_tree(x:Point(vs) × P[x];|K|)
7. w = vs-tree-val(vs;t) ∈ Point(vs)
8. y = 0 ∈ Point(vs)
9. k : |K|
⊢ ∃t:l_tree(x:Point(vs) × P[x];|K|). (k * w + y = vs-tree-val(vs;t) ∈ Point(vs))
BY
{ ((D 0 With ⌜l_tree_node(k;t;l_tree_node(0;t;t))⌝  THEN Auto)
   THEN Unfold `vs-tree-val` 0
   THEN Reduce 0
   THEN Fold `vs-tree-val` 0) }

1
1. K : Rng
2. vs : VectorSpace(K)
3. P : Point(vs) ⟶ ℙ
4. w : Point(vs)
5. y : Point(vs)
6. t : l_tree(x:Point(vs) × P[x];|K|)
7. w = vs-tree-val(vs;t) ∈ Point(vs)
8. y = 0 ∈ Point(vs)
9. k : |K|
⊢ k * w + y = k * vs-tree-val(vs;t) + 0 * vs-tree-val(vs;t) + vs-tree-val(vs;t) ∈ Point(vs)

Latex:

Latex:
1. K : Rng 2. vs : VectorSpace(K) 3. [P] : Point(vs) {}\mrightarrow{} \mBbbP{} 4. w : Point(vs) 5. y : Point(vs) 6. t : l\_tree(x:Point(vs) \mtimes{} P[x];|K|) 7. w = vs-tree-val(vs;t) 8. y = 0 9. k : |K| \mvdash{} \mexists{}t:l\_tree(x:Point(vs) \mtimes{} P[x];|K|). (k * w + y = vs-tree-val(vs;t)) By Latex: ((D 0 With \mkleeneopen{}l\_tree\_node(k;t;l\_tree\_node(0;t;t))\mkleeneclose{} THEN Auto) THEN Unfold `vs-tree-val` 0 THEN Reduce 0 THEN Fold `vs-tree-val` 0) Home Index