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Factors of sums and alternating sums of products of $q$-binomial coefficients and powers of $q$-integers. (arXiv:1705.06236v1 [math.NT])
来源于:arXiv
We prove that, for all positive integers $n_1, \ldots, n_m$, $n_{m+1}=n_1$,
and non-negative integers $j$ and $r$ with $j\leqslant m$, the following two
expressions \begin{align*} &\frac{1}{[n_1+n_m+1]}{n_1+n_{m}\brack
n_1}^{-1}\sum_{k=0}^{n_1} q^{j(k^2+k)-(2r+1)k}[2k+1]^{2r+1}\prod_{i=1}^m
{n_i+n_{i+1}+1\brack n_i-k},\\[5pt] &\frac{1}{[n_1+n_m+1]}{n_1+n_{m}\brack
n_1}^{-1}\sum_{k=0}^{n_1}(-1)^k q^{{k\choose
2}+j(k^2+k)-2rk}[2k+1]^{2r+1}\prod_{i=1}^m {n_i+n_{i+1}+1\brack n_i-k}
\end{align*} are Laurent polynomials in $q$ with integer coefficients, where
$[n]=1+q+\cdots+q^{n-1}$ and ${n\brack k}=\prod_{i=1}^k(1-q^{n-i+1})/(1-q^i)$.
This gives a $q$-analogue of some divisibility results of sums and alternating
sums involving binomial coefficients and powers of integers obtained by Guo and
Zeng. We also confirm some related conjectures of Guo and Zeng by establishing
their $q$-analogues. Several conjectural congruences for sums involving
products of $q$-ballot numbers $\left({2n\b 查看全文>>