Let $n$ and $m$ be positive integers with $n \gt m$. Can you show that the constant term of $${(1+x)^n}\left(\frac{1}{x} - 1\right)^m$$ is not equal to zero?
binomial expansion of $(1+x)^n \left(\dfrac{1}{x} -1\right)^m$
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0I tried $\LaTeX$-ifying your equation; please check that I did this correctly (I did not know if you meant $(\frac{1}{x}-1)^m$ or $(\frac{1}{x-1})^m$, but I'm guessing the former). – 2012-03-30
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0Thanks for the editing! Your writing is correct. – 2012-03-30
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4You can expand : \begin{align*} (1+x)^n \left( \frac 1x - 1 \right)^m & = \left( \sum_{i=0}^n \binom ni x^i\right) \left( \sum_{j=0}^m \binom mj x^{-j} (-1)^{m-j}\right) \\ & = \sum_{i=0}^n \sum_{j=0}^m \binom ni \binom mj x^{i-j} (-1)^{m-j} \\ \end{align*} so that the constant term is $$ \sum_{j=0}^{m} \binom nj \binom mj (-1)^{m-j} $$ (let $i=j$ to find the possible coefficients that belong to this sum). Does that help? – 2012-03-30
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0Yes, it is. Also the case when n=m. If n is odd, it is zero. But for even n it is ((-1)^(n/2))(n choose n/2) – 2012-03-30
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0For the cases $n=m+k$, where $ k=1,2,3,4 $, it is done. – 2012-03-31
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0Please either make @PatrickDaSilva rewrite his comment as an answer or do it yourself and accept it to close the question. – 2013-02-10