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Say i got $\displaystyle{\frac{(1-2x)}{(1+3x)^3}}$

I used $\displaystyle{\frac{1}{(1+3x)}}$ $=\sum_{n=0}^\infty(-3)^n x^n$ and differentiated twice

I got $\displaystyle{\frac{(1-2x)}{(1+3x)^3}}$ = $=\sum_{n=0}^\infty [((n)(n-1)(-3)^n)/18] x^{(n-2)}$

Multiply (1-2x) on both side I got

= $\sum_{n=0}^\infty [((n)(n-1)(-3)^n)/18] x^{(n-2)}$ - $2\sum_{n=0}^\infty [((n-1)(n-2)(-3)^{(n-1)}))/18] x^{(n-2)}$

$=\sum_{n=0}^\infty [(5n-4)(n-1)(-3)^n /54 ] x^{(n-2)}$

Is that correct ? I had a feeling that its wrong...

Coefficient of $z^{(n-2)}$ is $\displaystyle{\frac{(5n-4)(n-1)(-3)^n}{54}}$?

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    Please write (1-2x)/(1+3x)^3 instead of 1-2x/(1+3x)^3, because a-b/c is likely to be interpreted as a-(b/c) rather than (a-b)/c. Even better, you can use LaTeX here to write $\displaystyle{\frac{1-2x}{(1+3x)^3}}$. The syntax I used for that is `$\displaystyle{\frac{1-2x}{(1+3x)^3}}$`; you put the LaTeX math between dollar signs. Please include the sums when you mean a series. For example, you really want $\frac{1}{1+3x}=\sum_{n=0}^\infty(-3)^nx^n$ rather than what you wrote in the second line. (If you're new to LaTeX, you can right-click then click "Show Source" to see how it is done.)2011-05-04
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    Thank you and I will edit it.2011-05-04
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    @Jono: Thanks. Some of the things in your edit are presumably not what was intended. For example, you now have $1-2x$ in two numerators where I believe you want $1$. The syntax `$\frac{a}{b}$` gives $\frac{a}{b}$, so you can adjust the numerator and denominator in brackets to get the fraction you want.2011-05-04
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    Format adjusted, thank you.2011-05-04
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    When you want exponents of more than one character, you need to put them in braces: x^{(n+1)} gives $x^{(n+1)}$ while x^(n+1) gives $x^(n+1)$2011-05-04
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    All format is corrected. thank you2011-05-04

2 Answers 2

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You have a small mistake in the second line: $\frac{1-2x}{1+3x}=(1-2x)\overset{\infty}{\underset{n=0}{\sum}}(-3)^nx^n$.
But you can use the following: for all $a \in \mathbb{C}$ we have $(1+x)^a=\overset{\infty}{\underset{n=0}{\sum}}\binom{a}{n}x^n$, where $\binom{a}{n}$ is the formal notation for $\frac{a(a-1)\cdot...\cdot(a-n+1)}{n!}$ and $\binom{a}{0}=1$. Applying this, you can check your answer.

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    sorry it was suppose to be a 1, error during edit2011-05-04
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Adding on Dennis Gulko's answer.

For any $m \in \mathbb{N}$ fixed, it holds $$ \frac{1}{{(1 + mx)^m }} = \sum\limits_{n = 0}^\infty {\frac{{m \cdots (m + n - 1)}}{{n!}}( - m)^n x^n }, $$ provided that $|x|$ is sufficiently small.

This fact (confirmed numerically) can be shown in a probabilistic setting as follows. Let $X$ be a gamma$(m,1)$ random variable, so that $X$ has density function $f(x)=e^{ - x} x^{m - 1} /\Gamma (m)$, $x > 0$. The moment-generating function (MGF) of $X$ is given by $$ {\rm E}[e^{tX} ] = \frac{1}{{(1 - t)^m }} $$ (indeed, note that $1/(1-t)$ is the MGF of the exponential$(1)$ distribution, and $X$ can be written as a sum of $m$ independent exponential$(1)$ variables). Further, the $n$th moment ($n=0,1,2,\ldots$) of $X$ is given by $$ \mu_n' = \int_0^\infty {x^n f(x)\,{\rm d}x} = \frac{1}{{\Gamma (m)}}\int_0^\infty {x^{n + m - 1} e^{ - x} \,{\rm d}x} = \frac{{\Gamma (n + m)}}{{\Gamma (m)}} = m \cdots (m + n - 1) $$ (note that $\mu_0' = 1$). Hence, for all $t$ in a neighborhood of $0$, it holds $$ {\rm E}[e^{tX} ] = \sum\limits_{n = 0}^\infty {\frac{{\mu _n' }}{{n!}}t^n } = \sum\limits_{n = 0}^\infty {\frac{{m \cdots (m + n - 1)}}{{n!}}t^n } . $$ Finally, putting $t = -mx$, we get $$ \frac{1}{{(1 + mx)^m }} = \sum\limits_{n = 0}^\infty {\frac{{m \cdots (m + n - 1)}}{{n!}}( - m)^n x^n } . $$

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    =\ sorry but that made me even more confuse2011-05-04
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    and I don't mean to be rude, I really just want to know if I multiply (1-2x) on both side correctly or not because the answer seems to be so messy2011-05-04