Proof of Nuprl Lemma : alternating-series-tail-bound

Step * 1 1 of Lemma alternating-series-tail-bound

.....assertion.....
1. x : ℕ ⟶ ℝ
2. M : ℕ
3. ∀n:ℕ. ((M ≤ n) ⇒ ((r0 ≤ x[n]) ∧ (x[n + 1] ≤ x[n])))
4. lim n→∞.x[n] = r0
5. a : {M...}
6. b : ℕ
7. a ≤ b
⊢ ∀d,n,m:ℕ.
    ((a ≤ n)
    ⇒ ((m - n) ≤ d)
    ⇒ ((((-1)^n = 1 ∈ ℤ) ⇒ ((r0 ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ x[n])))
       ∧ (((-1)^n = (-1) ∈ ℤ) ⇒ ((-(x[n]) ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ r0)))))
BY
{ (CompleteInductionOnNat THEN Intros THEN (Decide ⌜m < n⌝⋅ THENA Auto)) }

1
1. x : ℕ ⟶ ℝ
2. M : ℕ
3. ∀n:ℕ. ((M ≤ n) ⇒ ((r0 ≤ x[n]) ∧ (x[n + 1] ≤ x[n])))
4. lim n→∞.x[n] = r0
5. a : {M...}
6. b : ℕ
7. a ≤ b
8. d : ℕ
9. ∀d:ℕd. ∀n,m:ℕ.
     ((a ≤ n)
     ⇒ ((m - n) ≤ d)
     ⇒ ((((-1)^n = 1 ∈ ℤ) ⇒ ((r0 ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ x[n])))
        ∧ (((-1)^n = (-1) ∈ ℤ) ⇒ ((-(x[n]) ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ r0)))))
10. n : ℕ
11. m : ℕ
12. a ≤ n
13. (m - n) ≤ d
14. m < n
⊢ (((-1)^n = 1 ∈ ℤ) ⇒ ((r0 ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ x[n])))
∧ (((-1)^n = (-1) ∈ ℤ) ⇒ ((-(x[n]) ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ r0)))

2
1. x : ℕ ⟶ ℝ
2. M : ℕ
3. ∀n:ℕ. ((M ≤ n) ⇒ ((r0 ≤ x[n]) ∧ (x[n + 1] ≤ x[n])))
4. lim n→∞.x[n] = r0
5. a : {M...}
6. b : ℕ
7. a ≤ b
8. d : ℕ
9. ∀d:ℕd. ∀n,m:ℕ.
     ((a ≤ n)
     ⇒ ((m - n) ≤ d)
     ⇒ ((((-1)^n = 1 ∈ ℤ) ⇒ ((r0 ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ x[n])))
        ∧ (((-1)^n = (-1) ∈ ℤ) ⇒ ((-(x[n]) ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ r0)))))
10. n : ℕ
11. m : ℕ
12. a ≤ n
13. (m - n) ≤ d
14. ¬m < n
⊢ (((-1)^n = 1 ∈ ℤ) ⇒ ((r0 ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ x[n])))
∧ (((-1)^n = (-1) ∈ ℤ) ⇒ ((-(x[n]) ≤ Σ{r(-1)^i * x[i] | n≤i≤m}) ∧ (Σ{r(-1)^i * x[i] | n≤i≤m} ≤ r0)))

Latex:

Latex:
.....assertion..... 1. x : \mBbbN{} {}\mrightarrow{} \mBbbR{} 2. M : \mBbbN{} 3. \mforall{}n:\mBbbN{}. ((M \mleq{} n) {}\mRightarrow{} ((r0 \mleq{} x[n]) \mwedge{} (x[n + 1] \mleq{} x[n]))) 4. lim n\mrightarrow{}\minfty{}.x[n] = r0 5. a : \{M...\} 6. b : \mBbbN{} 7. a \mleq{} b \mvdash{} \mforall{}d,n,m:\mBbbN{}. ((a \mleq{} n) {}\mRightarrow{} ((m - n) \mleq{} d) {}\mRightarrow{} ((((-1)\^{}n = 1) {}\mRightarrow{} ((r0 \mleq{} \mSigma{}\{r(-1)\^{}i * x[i] | n\mleq{}i\mleq{}m\}) \mwedge{} (\mSigma{}\{r(-1)\^{}i * x[i] | n\mleq{}i\mleq{}m\} \mleq{} x[n]))) \mwedge{} (((-1)\^{}n = (-1)) {}\mRightarrow{} ((-(x[n]) \mleq{} \mSigma{}\{r(-1)\^{}i * x[i] | n\mleq{}i\mleq{}m\}) \mwedge{} (\mSigma{}\{r(-1)\^{}i * x[i] | n\mleq{}i\mleq{}m\} \mleq{} r0))))) By Latex: (CompleteInductionOnNat THEN Intros THEN (Decide \mkleeneopen{}m < n\mkleeneclose{}\mcdot{} THENA Auto)) Home Index