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Can any one help me calculate this integral :

$\int_{a}^{+\infty} \frac{y\ \exp{(-by)}} {1-\exp{(-cy)}} \ dy $

a, b & c are real constant numbers, b & c > 0

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    Are you italian? I can help you with that infinite series. Maybe this interests [you](http://math.stackexchange.com/questions/110457/closed-form-of-integral) and [this](http://math.stackexchange.com/questions/111435/infinite-series-representation-limited-or-not) too.2012-05-22

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Assuming $a>0$, you can write the integrand as $\sum_{n=0}^\infty y \exp((-b-nc)y)$ and the integral becomes the convergent series $\sum_{n=0}^\infty e^{-ab-acn} \frac{ab+acn+1}{(b+nc)^2} $
According to Maple this can be written using a hypergeometric function: $ \frac{ab+1}{b^2 e^{ab}}\ {\mbox{$_4$F$_3$}(1,{\frac {b}{c}},{\frac {b}{c}},{\frac {1+ \left( c+b \right) a}{ac}};\,{\frac {c+b}{c}},{\frac {c+b}{c}},{\frac {ab+1}{ac}};\, {{\rm e}^{-ac}} )} $ However, we can do somewhat better: first write $\dfrac{ab+acn+1}{(b+nc)^2} = \dfrac{a}{b+nc}+\dfrac{1}{(b+nc)^2}$. Now $ \sum_{n=0}^\infty e^{-ab-acn} \left( \dfrac{a}{b+nc} + \dfrac{1}{(b+nc)^2}\right) = {\rm e}^{-ab} \left( \dfrac{a}{c} {\rm LerchPhi} \left( {{\rm e}^{-ac}},1,{\frac {b}{c}} \right) + \dfrac{1}{c^2} {\rm LerchPhi} \left( {{\rm e}^{-ac}},2,{\frac {b}{c}} \right)\right) $ where ${\rm LerchPhi}(t,m,v) = \sum_{n=0}^\infty \dfrac{t^n}{(v+n)^m}$.

In the special case $a=0$ the series becomes $ \sum_{n=0}^\infty \frac{1}{(b+nc)^2} = \Psi \left( 1,{\frac {b}{c}} \right) {c}^{-2}$ where $\Psi(1,t) = \dfrac{d}{dt} \Psi(t) $ and $\Psi(t) = \dfrac{d}{dt} \ln \Gamma(t)$.