27
$\begingroup$

My question has two parts:

  1. How can I nicely define the infinite sequence $0.9,\ 0.99,\ 0.999,\ \dots$? One option would be the recursive definition below; is there a nicer way to do this? Maybe put it in a form that makes the second question easier to answer. $s_{i+1} = s_i + 9\cdot10^{-i-2},\ s_0 = 0.9$ Edit: Suggested by Kirthi Raman: $(s_i)_{i\ge1} = 1 - 10^{-i}$

  2. Once I have the sequence, what would be the limit of the infinite product below? I find the question interesting since $0.999... = 1$, so the product should converge (I think), but to what? What is the "last number" before $1$ (I know there is no such thing) that would contribute to the product? $\prod_{i=1}^{\infty} s_i$

  • 0
    You can prove it converges because it is decreasing and bounded below by 0.2012-05-06

3 Answers 3

32

To elaborate, and extend on GEdgar's answer: there is what is called the $q$-Pochhammer symbol

$(a;q)_n=\prod_{k=0}^{n-1} (1-aq^k)$

and $(a;q)_\infty$ is interpreted straightforwardly. The product you are interested in is equivalent to $\left(\frac1{10};\frac1{10}\right)_\infty\approx0.8900100999989990000001$.

One can also express the $q$-Pochhammer symbol $(q;q)_\infty$ in terms of the Dedekind $\eta$ function $\eta(\tau)$ or the Jacobi $\vartheta$ function $\vartheta_2(z,q)$; in particular we have

$\left(\frac1{10};\frac1{10}\right)_\infty=\sqrt[24]{10}\eta\left(\frac{i\log\,10}{2\pi}\right)=\frac{\sqrt[24]{10}}{\sqrt 3}\vartheta_2\left(\frac{\pi}{6},\frac1{\sqrt[6]{10}}\right)$


I might as well... there is the following identity, due to Euler (the pentagonal number theorem):

$(q;q)_\infty=\prod_{j=1}^\infty(1-q^j)=\sum_{k=-\infty}^\infty (-1)^k q^\frac{k(3k-1)}{2}$

which, among other things, gives you a series you can use for quickly estimating your fine product:

$\left(\frac1{10};\frac1{10}\right)_\infty=1+\sum_{k=1}^\infty (-1)^k\left(10^{-\frac{k}{2}(3k+1)}+10^{-\frac{k}{2}(3k-1)}\right)$

Three terms of this series gives an approximation good to twenty digits; five terms of this series yields a fifty-digit approximation.

  • 14
    No special function is too special for J.M.! :)2012-05-07
9

By looking at the decimal representation, it appears that:

$ \prod_{i=1}^\infty\left(1-\frac1{10^i}\right)= \sum_{i=1}^\infty \frac{8 + \frac{10^{2^i-1}-1}{10^{2i-1}} + \frac1{10^{6i-2}} + \frac{10^{4i}-1}{10^{12i-2}} }{10^{(2i-1)(3i-2)}} $

I don't have a proof, but the pattern is so regular that I'm confident.

  • 0
    Ramanujan style.2013-02-26
4

See: "Dedekind eta function".

  • 0
    For a series representation, see Euler's "pentagonal number theorem" ... http://en.wikipedia.org/wiki/Pentagonal_number_theorem2012-05-06