I am trying to prove the following identity but not sure how to prove it.
[The followings are equivalent forms of the original equality I asked.] $$ \binom{m+n}{s+1} - \binom{n}{s+1} = \sum_{i=0}^s \frac{m}{s-i+1}\binom{m+1+2(s-i)}{s-i}\binom{n-2(s-i+1)}{i}. $$ $$ {m+n\choose s+1} - {n\choose s+1} = \sum_{q=0}^s \frac{m}{q+1} {m+1+2q\choose q} {n-2-2q\choose s-q} $$ $$ \binom{m+n}{s} = \sum_{i=0}^{s} \frac{m}{m+2i} \binom{m+2i}{i}\binom{n-2i}{s-i} $$
[Please ignore my attempt. It only explains one of equivalent forms.]
My attempt is to use the combinatorial argument. The lefthand side could be understood as follow. Suppose we have a box containing $m$ black balls and $n$ white balls. We randomly draw $s+1$ balls out of it. Then the LHS represents the number of ways that the selected $s+1$ balls.
However, not sure how to make a combinatorial argument on the RHS. Based on the RHS, the sum of all cases of drawing $s-i$ balls from somewhere and $i$ balls from white balls. But it is unclear to me to show the above identity.
Any suggestions/answers would be very appreciated. Thanks.
Remark. What follows answers one of several queries that appeared at this post, which each query replacing the previous one. We suggest making a list so that all the different varieties may be examined.
Starting from the claim
$$\bbox[5px,border:2px solid #00A000]{ {m+n\choose s+1} - {n\choose s+1} = \sum_{q=0}^s \frac{m}{q+1} {m+1+2q\choose q} {n-2-2q\choose s-q}}$$
we observe that
$${m+1+2q\choose q+1} - {m+1+2q\choose q} \\ = \frac{m+1+q}{q+1} {m+1+2q\choose q} - {m+1+2q\choose q} \\ = \frac{m}{q+1} {m+1+2q\choose q}.$$
Therefore we have two sums,
$$\sum_{q=0}^s {m+1+2q\choose q+1} {n-2-2q\choose s-q} - \sum_{q=0}^s {m+1+2q\choose q} {n-2-2q\choose s-q}.$$
For the first one we write
$$\sum_{q=0}^s [w^{q+1}] (1+w)^{m+1+2q} [z^{s-q}] (1+z)^{n-2-2q} \\ = \underset{w}{\mathrm{res}}\; (1+w)^{m+1} [z^s] (1+z)^{n-2} \sum_{q=0}^s \frac{1}{w^{q+2}} z^q (1+w)^{2q} (1+z)^{-2q}.$$
We may extend $q$ beyond $s$ because of the coefficient extractor $[z^s]$ in front, getting
$$\underset{w}{\mathrm{res}}\; \frac{1}{w^2} (1+w)^{m+1} [z^s] (1+z)^{n-2} \sum_{q\ge 0} z^q w^{-q} (1+w)^{2q} (1+z)^{-2q} \\ =\underset{w}{\mathrm{res}}\; (1+w)^{m+1} [z^s] (1+z)^{n-2} \frac{1}{w^2} \frac{1}{1-z(1+w)^2/w/(1+z)^2} \\ =\underset{w}{\mathrm{res}}\; (1+w)^{m+1} [z^s] (1+z)^{n} \frac{1}{w} \frac{1}{w(1+z)^2-z(1+w)^2}.$$
Repeat the calculation for the second one to get
$$\underset{w}{\mathrm{res}}\; (1+w)^{m+1} [z^s] (1+z)^{n} \frac{1}{w(1+z)^2-z(1+w)^2}.$$
Now we have
$$\left(\frac{1}{w}-1\right)\frac{1}{w(1+z)^2-z(1+w)^2} = \frac{1}{w-z} \frac{1}{w(1+w)} - \frac{1}{1-wz} \frac{1}{1+w} \\ = \frac{1}{1-z/w} \frac{1}{w^2(1+w)} - \frac{1}{1-wz} \frac{1}{1+w}.$$
We thus obtain two components, the first is
$$\underset{w}{\mathrm{res}}\; (1+w)^{m+1} [z^s] (1+z)^{n} \frac{1}{1-z/w} \frac{1}{w^2(1+w)} \\ = \underset{w}{\mathrm{res}}\; \frac{1}{w^2} (1+w)^{m} [z^s] (1+z)^{n} \frac{1}{1-z/w} \\ = \underset{w}{\mathrm{res}}\; \frac{1}{w^2} (1+w)^{m} \sum_{q=0}^s {n\choose q} \frac{1}{w^{s-q}} = \sum_{q=0}^s {n\choose q} \underset{w}{\mathrm{res}}\; \frac{1}{w^{s-q+2}} (1+w)^{m} \\ = \sum_{q=0}^s {n\choose q} [w^{s-q+1}] (1+w)^m = [w^{s+1}] (1+w)^m \sum_{q=0}^s {n\choose q} w^q \\ = - {n\choose s+1} + [w^{s+1}] (1+w)^m \sum_{q=0}^{s+1} {n\choose q} w^q.$$
We may extend $q$ beyond $s+1$ due to the coefficient extractor in front, to get
$$- {n\choose s+1} + [w^{s+1}] (1+w)^m \sum_{q\ge 0} {n\choose q} w^q = - {n\choose s+1} + [w^{s+1}] (1+w)^{m+n}$$
This is
$$\bbox[5px,border:2px solid #00A000]{ {m+n\choose s+1} - {n\choose s+1}.}$$
We have the claim, so we just need to prove that the second component will produce zero. We obtain
$$\underset{w}{\mathrm{res}}\; (1+w)^{m+1} [z^s] (1+z)^{n} \frac{1}{1-wz} \frac{1}{1+w} \\ =\underset{w}{\mathrm{res}}\; (1+w)^{m} [z^s] (1+z)^{n} \frac{1}{1-wz} \\ =\underset{w}{\mathrm{res}}\; (1+w)^{m} \sum_{q=0}^s {n\choose q} w^{s-q} = \sum_{q=0}^s {n\choose q} \underset{w}{\mathrm{res}}\; w^{s-q} (1+w)^{m} = 0.$$
This concludes the argument.