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I am interested in approximating the sum of the squares of the multinomial coefficients, i.e.

$a_\ell^p := \sum_{k_0+\ldots+k_p = \ell} (\frac{\ell!}{k_0! \ldots k_p!})^2$

or more general,

$a_\ell^{\alpha_0,\ldots, \alpha_p} := \sum_{k_0+\ldots+k_p = \ell} (\prod_{i=0}^p \alpha_i^{k_i})^2(\frac{\ell!}{k_0! \ldots k_p!})^2$

Here $p$ is prime, and $\ell$ is an integer smaller then $p$, $k_i$ are non-negative integers. I would like to obtain some simple expression in terms of $\ell$ and $p$, a good approximation for large $p$, an upper bound will be good.

I saw some results on recursive formula for such expressions, but not estimates. Should I just go with a Stirling formula in all the terms or is there something better done in this direction?

Does someone knows what would be the Mathematica/Maple code for calculating such sums as functions from $p$ and $l$?

Thanks!

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  • $\begingroup$ That $p$ is prime doesn't affect anything. It probably helps to view this as a question about random walks, rescaling so $\sum \alpha_i = 1$. $\endgroup$ Apr 21, 2013 at 16:45
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    $\begingroup$ Even for $p=2$ (the next case after the standard binomial identity), it seems like the sum doesn't have a closed form. oeis.org/A002893 If you were interested in a fixed $p$ as $\ell\to \infty$ then you should be able to get asymptotics from the Central Limit Theorem or local variations, or Laplace's method, maybe something like $(p+1)^{2\ell}(c \ell)^{-p/2}$. However, you specify $\ell \lt p$. $\endgroup$ Apr 21, 2013 at 20:26

2 Answers 2

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Douglas already commented that the asymptotics for fixed $p$ and $l\to \infty$ shoudl follow from standard methods. One gets $$a_{\ell}^p\approx (p+1)^{2\ell+\frac{p+1}{2}}(4\pi \ell)^{-\frac{p}{2}}.$$ See theorem 4 in "Counting Abelian squares", by Richmond and Shallit. Notice that these numbers appear also in combinatorics when considering abelian squares, or more generally abelian powers, on a fixed alphabet.

For the asymptotics that you're interested in, at least in the unweighted case, one can say $$a _{\ell} ^p=\sum _{j=0} ^{\ell} \binom{p}{j}\sum _{a _1+ \cdots +a _j = \ell \atop a _i \geq 1} \binom{\ell}{a _1,a _2,\dots,a _j}^2$$ which makes it clear that $a _{\ell}^p$ is a polynomial in $p$ of fixed degree $\ell$. The coefficient of $\binom{p}{\ell}$ is $(\ell!)^2$, and the coefficient of $\binom{p}{\ell -1}$ is $\frac{\ell-1}{4}(\ell!)^2$, so you have $$a _{\ell}^p =\ell!p^{\ell}-\ell!\frac{\ell(\ell-1)}{4}p^{\ell-1}+O(p^{\ell-2}).$$

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  • $\begingroup$ Thank you for the answer and the link, it is very useful. Indeed, in my case I can only send $p$ to $\infty$, but $l$ is always smaller then $p$ and therefore your second comment is the type of result I was looking for. If you have time, can you please explain more in details - I understood the recursive formula for $f_k(n)$ in the paper but what you wrote is different, and I didn't quite get it.. $\endgroup$
    – Liss
    Apr 25, 2013 at 10:31
  • $\begingroup$ I figured out how you got the coefficients in front of the powers of $p$, but I am only confused with the minus of the second term? Sorry if am asking dumb questions $\endgroup$
    – Liss
    Apr 25, 2013 at 10:41
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Gjergji has given a very nice result, just want to explain Gjergji's answer for $$ a^p_l = l!p^l - l!\frac{l(l-1)}{4} p^{l-1} + O(p^{l-2})$$ To determine the coeffients of $p^l$, we see that this order is only included in $p \choose l$ because $$ {p\choose l} = \frac{(p-l+1)(p-l+2)\cdots (p)}{l!}$$ And in this case the term $\sum_{\substack{a_1 + \ldots + a_l = l \\ a_i \geq 1}} {l \choose {a_1, a_2, \ldots,a_l }}^2 = (l!)^2$ because we can only choose $a_i = 1, \forall i$. Therefore the coefficient of $p^l$ is $l!$. To determine the coefficient in $p^{l-1}$, we can see that it is contibuted by both $p \choose l$ and $ p \choose l-1$, for the term $p \choose l$, it contributes $$ -(1 + 2 +\ldots + l-1)(l!) = -\frac{l(l-1)}{2}l!$$ For the term comtributed by $p \choose l-1$, notice $\sum_{\substack{a_1 + \ldots + a_{l-1} = l \\ a_i \geq 1}} {l \choose {a_1, a_2, \ldots,a_{l-1} }}^2 = (l-1)\frac{(l!)^2}{4}$, where the $(l-1)$ factor comes from the summation. Therefore the coefficient by $p \choose l-1$ is $(l-1)\frac{(l!)^2}{4} \frac{1}{(l-1)!} = l!\frac{l(l-1)}{4}$. So totally the coefficent is $-l!\frac{l(l-1)}{4}$, which is what Gjergji got in his answer.

That's actually how the minus sign comes from.

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