Proof of Nuprl Lemma : rv-orthogonal-iff

Step * 2 1 of Lemma rv-orthogonal-iff

1. rv : InnerProductSpace
2. f : Point(rv) ⟶ Point(rv)
3. f 0 ≡ 0
4. Isometry(f)
5. ∀x,y:Point(rv).  (x ≡ y ⇒ f x ≡ f y)
6. x : Point(rv)
7. y : Point(rv)
⊢ f x + y ≡ f x + f y
BY
{ Assert ⌜∀a,b:Point(rv).  f (r1/r(2))*a + b ≡ (r1/r(2))*f a + f b⌝⋅ }

1
.....assertion.....
1. rv : InnerProductSpace
2. f : Point(rv) ⟶ Point(rv)
3. f 0 ≡ 0
4. Isometry(f)
5. ∀x,y:Point(rv).  (x ≡ y ⇒ f x ≡ f y)
6. x : Point(rv)
7. y : Point(rv)
⊢ ∀a,b:Point(rv).  f (r1/r(2))*a + b ≡ (r1/r(2))*f a + f b

2
1. rv : InnerProductSpace
2. f : Point(rv) ⟶ Point(rv)
3. f 0 ≡ 0
4. Isometry(f)
5. ∀x,y:Point(rv).  (x ≡ y ⇒ f x ≡ f y)
6. x : Point(rv)
7. y : Point(rv)
8. ∀a,b:Point(rv).  f (r1/r(2))*a + b ≡ (r1/r(2))*f a + f b
⊢ f x + y ≡ f x + f y

Latex:

Latex:
1. rv : InnerProductSpace 2. f : Point(rv) {}\mrightarrow{} Point(rv) 3. f 0 \mequiv{} 0 4. Isometry(f) 5. \mforall{}x,y:Point(rv). (x \mequiv{} y {}\mRightarrow{} f x \mequiv{} f y) 6. x : Point(rv) 7. y : Point(rv) \mvdash{} f x + y \mequiv{} f x + f y By Latex: Assert \mkleeneopen{}\mforall{}a,b:Point(rv). f (r1/r(2))*a + b \mequiv{} (r1/r(2))*f a + f b\mkleeneclose{}\mcdot{} Home Index