let $a,b,n$ be positive integer numbers,and such $a,b\le n$, show that $$\dfrac{1}{n}\sum_{k=0}^{n-1}\binom{k}{a}\binom{k}{b}\le\dfrac{1}{a+b+1}\binom{n}{a}\binom{n}{b}$$
this inequality maybe can use Integral inequality to solve it.because $$\int_{0}^{1}x^{a+b}dx=\dfrac{1}{a+b+1},\int_{0}^{1}x^{n-1}dx=\dfrac{1}{n}$$
Thank you for you help.
Since the inequality is symmetric in $a$ and $b$ we may (and will), suppose $a\leq b\leq n$.
Moreover, the inequality is trivially satisfied if $n=b$. So let us suppose that the inequality is proved for some $n\geq b$. It follows that $$\eqalign{ \sum_{k=0}^n\binom{k}{a}\binom{k}{b}&=\sum_{k=0}^{n-1}\binom{k}{a}\binom{k}{b}+ \binom{n}{a}\binom{n}{b} \cr &\leq \frac{n}{a+b+1}\binom{n}{a}\binom{n}{b}+\binom{n}{a}\binom{n}{b}\cr &\leq \frac{a+b+n+1}{a+b+1}\binom{n}{a}\binom{n}{b}\cr} $$ Now the desired inequality for $n+1$ would follow if we have $$ \frac{a+b+n+1}{a+b+1}\binom{n}{a}\binom{n}{b}\leq \frac{n+1}{a+b+1}\binom{n+1}{a}\binom{n+1}{b} $$ This is equivalent to $$ (n+1+a+b)(n+1-a)(n+1-b)\leq(n+1)^3 $$ or $$ n+1 \geq \frac{a^2b+b^2a}{a^2+b^2+ab}=b-\frac{b^3}{a^2+ab+b^2} $$ and this inequality is trivially satisfied since $n+1>b$. This ends the proof by induction.$\qquad\square$