2.5 Monotone Sequences 105- Which of the following sequences are eventually monotone (or strictly) in-
creasing (or decreasing)? Justify your answers, assuming the usual prop-
erties of trigonometric functions where necessary.
(a) {(-~)n}(c) {n+ (-~)n}
(e) {2 + (-l)n}
(g) {sin n
27r }(i) { n }
2n(k) {cos 2:}
(m) { n23
:: ~ 2}- Prove Theorem 2.5.3 (b).
- Prove Corollary 2.5.4.
(d) {n^2 - lOn + 100}
(f) {3n
2
+n(-1r}(h) {sin n?r}(j) { ~~}(1) {sin
3
:}(n) {Jn- k}
- The proof of Theorem 2.5.3 (monotone convergence theorem) depends
heavily on the completeness property of R Find a bounded, monotone
increasing sequence in the (incomplete) field Q that fails to converge in
Q. - Consider the sequence {xn} defined inductively by x 1 = 1, and Vn EN,
Xn+l = y'6 + Xn· Prove that {xn} converges, and find its limit. [Hint: See
Example 2.5.8.J - Consider the sequence {xn} defined inductively by x 1 = 1, and Vn EN,
Xn+l = y'4xn + 5. Prove that {xn} converges, and find its limit. [Hint:
See Example 2.5.8.J - Consider the sequence {xn} defined inductively by x 1 = 1, and Vn EN,
xn+l =
2
xn
7+
3. Prove that { xn} converges, and find its limit.
9. Consider the sequence {xn} defined inductively by x 1 = 1, and Vn E N,
2.
Xn+i = nxn. Prove that { Xn} converges, and find its limit.
n+l
10. Consider the sequence {xn} defined inductively by x 1 = c E JR, and
Vn E N, Xn+i = x;;,. For what values of c does {xn} converge, and to
what?