Proof of Nuprl Lemma : real-approx

Step * 1 of Lemma real-approx

1. x : ℝ
2. n : ℕ⁺
3. r(2 * n) = |r(2 * n)|
⊢ |-(r(x n)) + (r(2 * n) * x)| ≤ r(2)
BY
{ (TACTIC:Unfold `rleq` 0
   THEN (BLemma `rnonneg-iff` THENA Auto)
   THEN Unfold `rsub` 0
   THEN (RWO "radd-bdd-diff" 0 THENA Auto)
   THEN Fold `reg-seq-add` 0

   THEN (RWO "radd-bdd-diff" 0 THENA (Try (Complete (Auto)) THEN RepUR ``rminus rabs rmax`` 0 THEN Auto))

THEN Try (Fold `reg-seq-add` 0)
THEN (RWO "rmul-bdd-diff-reg-seq-mul" 0

         THENA (Try (Complete (Auto)) THEN Try ((RepUR ``rminus rabs rmax`` 0 THEN Complete (Auto))⋅))

)) }

1
1. x : ℝ
2. n : ℕ⁺
3. r(2 * n) = |r(2 * n)|
⊢ rnonneg2(reg-seq-add(r(2);-(|reg-seq-add(-(r(x n));reg-seq-mul(r(2 * n);x))|)))

Latex:

Latex:
1. x : \mBbbR{} 2. n : \mBbbN{}\msupplus{} 3. r(2 * n) = |r(2 * n)| \mvdash{} |-(r(x n)) + (r(2 * n) * x)| \mleq{} r(2) By Latex: (TACTIC:Unfold `rleq` 0 THEN (BLemma `rnonneg-iff` THENA Auto) THEN Unfold `rsub` 0 THEN (RWO "radd-bdd-diff" 0 THENA Auto) THEN Fold `reg-seq-add` 0 THEN (RWO "radd-bdd-diff" 0 THENA (Try (Complete (Auto)) THEN RepUR ``rminus rabs rmax`` 0 THEN Auto) ) THEN Try (Fold `reg-seq-add` 0) THEN (RWO "rmul-bdd-diff-reg-seq-mul" 0 THENA (Try (Complete (Auto)) THEN Try ((RepUR ``rminus rabs rmax`` 0 THEN Complete (Auto))\mcdot{})) )) Home Index