Well, If I did nothing incorrectly the SNF of $\begin{pmatrix}6&2&3&0\\
2&3&-4&1\\
-3&3&1&2\\
-1&2&-3&5\end{pmatrix}$ is ${\rm diag}(1,1,1,22)$

I'm reviewing for a combinatorics final exam in two days... can anybody confirm or deny whether my understanding of this is correct?

Using a generating function, find the number of ways to pick 6 balls from four different piles of 3 balls.

So I've got the generating function to be $(1+x+x^2+x^3)^4$, and I'm looking for the coefficient of $x^6$... I've determined this to be

$${4\choose 1}{5\choose 2}+{9\choose 6}$$

@PedroTamaroff Yeah, I did use that. I skipped a lot of details when typing out my question just to be brief. I got

$$h(x)=(1-x^4)^4\cdot\frac{1}{(1-x)^4}$$

So the first part expands to

$$1-{4\choose 1}x^4+{4\choose 2}x^8-{4\choose 3}x^{12}+{4\choose 4}x^{16}$$

where the second part expands to

$${r+3\choose r}x^r$$

In calculus, what does the question mean by For each sequence $${a_n}$$ find a number r such that $$\frac{a_n}{r^n}$$
has a finite non-zero limit.

$$a_n = (5 + 5 ^ n)^{- 4} $$
r=

I almost forgot I had this tab open from last night.
Thank the lord for desktop notifications!

Haven't we all? :P
I've got 4 exams coming up mid-june and I've hardly prepared for them *sigh*

@TedShifrin
Wolfram gets $ \frac{4}{3} \log ( 1 - x^{3}{4} ) + \mathcal{C} $.
Is it just a different form?
@Sawarnik
The integral above is pretty similar. You'll need a substitution that'll remove the radicals and leave you with a rational function.

@KhallilBenyattou A quick question for you, prove:
$$\displaystyle{\int_0^1 \frac{1+x^{30}}{1+x^{60}} = 1 + \frac{c}{31}}, \qquad \text{where } 0 < c < 1.$$