Proof of Nuprl Lemma : rroot-exists1-ext

Step * of Lemma rroot-exists1-ext

No Annotations
∀i:{2...}. ∀x:{x:ℝ| (↑isEven(i)) ⇒ (r0 ≤ x)} .
∃q:{q:ℕ ⟶ ℝ|

      (∀n,m:ℕ.  (((r0 ≤ (q n)) ∧ (r0 ≤ (q m))) ∨ (((q n) ≤ r0) ∧ ((q m) ≤ r0))))

      ∧ ((↑isEven(i)) ⇒ (∀m:ℕ. (r0 ≤ (q m))))}
   lim n→∞.q n^i = x
BY
{ Extract of Obid: rroot-exists1
  not unfolding  divide near-root rlessw mu-ge absval
  finishing with Auto
  normalizes to:

  λi,x. eval xx = x in
        <λn.eval p = xx (2 * (n + 1)) in
            if (1 * 4 * (n + 1)) < (p * 2 * (n + 1))
               then if (p * 2 * (n + 1)) < ((-1) * 4 * (n + 1))
                       then eval r = near-root(i;p;4 * (n + 1);2 * (n + 1)) in
                            let r1,r2 = r
                            in eval k = r2 in
                               λn.((2 * n * r1) ÷ k)
                       else eval r = near-root(i;p;4 * (n + 1);2 * (n + 1)) in
                            let r1,r2 = r
                            in eval k = r2 in
                               λn.((2 * n * r1) ÷ k)
               else if (p * 2 * (n + 1)) < ((-1) * 4 * (n + 1))
                       then eval r = near-root(i;p;4 * (n + 1);2 * (n + 1)) in
                            let r1,r2 = r
                            in eval k = r2 in
                               λn.((2 * n * r1) ÷ k)
                       else (λk.(2 * k * 0))
        , λk.(k - 1)
        > }

Latex:

Latex:
No Annotations \mforall{}i:\{2...\}. \mforall{}x:\{x:\mBbbR{}| (\muparrow{}isEven(i)) {}\mRightarrow{} (r0 \mleq{} x)\} . \mexists{}q:\{q:\mBbbN{} {}\mrightarrow{} \mBbbR{}| (\mforall{}n,m:\mBbbN{}. (((r0 \mleq{} (q n)) \mwedge{} (r0 \mleq{} (q m))) \mvee{} (((q n) \mleq{} r0) \mwedge{} ((q m) \mleq{} r0)))) \mwedge{} ((\muparrow{}isEven(i)) {}\mRightarrow{} (\mforall{}m:\mBbbN{}. (r0 \mleq{} (q m))))\} lim n\mrightarrow{}\minfty{}.q n\^{}i = x By Latex: Extract of Obid: rroot-exists1 not unfolding divide near-root rlessw mu-ge absval finishing with Auto normalizes to: \mlambda{}i,x. eval xx = x in <\mlambda{}n.eval p = xx (2 * (n + 1)) in if (1 * 4 * (n + 1)) < (p * 2 * (n + 1)) then if (p * 2 * (n + 1)) < ((-1) * 4 * (n + 1)) then eval r = near-root(i;p;4 * (n + 1);2 * (n + 1)) in let r1,r2 = r in eval k = r2 in \mlambda{}n.((2 * n * r1) \mdiv{} k) else eval r = near-root(i;p;4 * (n + 1);2 * (n + 1)) in let r1,r2 = r in eval k = r2 in \mlambda{}n.((2 * n * r1) \mdiv{} k) else if (p * 2 * (n + 1)) < ((-1) * 4 * (n + 1)) then eval r = near-root(i;p;4 * (n + 1);2 * (n + 1)) in let r1,r2 = r in eval k = r2 in \mlambda{}n.((2 * n * r1) \mdiv{} k) else (\mlambda{}k.(2 * k * 0)) , \mlambda{}k.(k - 1) > Home Index