Prove: $\lim_{n\to\infty}r^n = +\infty\,, r > 1;$ $\lim_{n\to\infty}r^n = 0\,, 0 \le r < 1.$
I am not quite sure how to prove this, but once someone proves it I will make sure to ask questions if I'm in doubt. Thank you very much! :)
Prove: $\lim_{n\to\infty}r^n = +\infty\,, r > 1;$ $\lim_{n\to\infty}r^n = 0\,, 0 \le r < 1.$
I am not quite sure how to prove this, but once someone proves it I will make sure to ask questions if I'm in doubt. Thank you very much! :)
I first saw the proof that $r^n \to 0$ if $0 \le r < 1$ and $r^n \to \infty$ if $r > 1$ in Courant and Robbin's "What is Mathematics?" many years ago. As stated by others, the proof uses Bernoulli's inequality and, implicitly, Archimede's axiom about the real numbers.
They also have a simple proof that $n^{1/n} \to 1$ as integer $n \to \infty$.
One nice thing about these proofs is that all the bounds are explicit and easily computable.
Hint: Use Bernoulli's inequality: $ (1+x)^n \ge 1 + nx \quad \mbox{for $x\ge 0$} $ This can be proven by induction.
Perhaps one can add something to the answer by lhf for the case $0\lt r\lt 1$.
For such an $r$, let $r=\dfrac{1}{1+x}$. Then $x \gt 0$. Now go to the answer by lhf.