Prove the following Combinatorial identity

Question

For any m $\ge$ 1. Prove that $$\sum_{j=0}^m\frac{1}{j+1}{m \choose j} = \frac{1}{m+1}(2^{m+1} -1 )$$

Attempt: I tried using subsets after rearranging the equation. Then even though the R.H.S gives the no of substes of n+1 excluding empty. I am unable to get a interpretation for L.H.S

score 3 · Accepted Answer · answered Sep 10 '16 at 20:12

3

HINT:

$$\frac1{j+1}\binom{m}j=\frac1{m+1}\binom{m+1}{j+1}$$

(This is an identity worth knowing; it comes up quite often.)

answered Sep 10 '16 at 20:12

Brian M. Scott

631,399

How to prove it. I have never seen this – Amrita Sep 10 '16 at 20:13
1

@Amrita: One way is to rewrite the binomial coefficients in terms of factorials. $$\binom{m+1}{j+1}=\frac{(m+1)!}{(j+1)!(m-j)!}=\frac{m+1}{j+1}\binom{m}j$$ – Brian M. Scott Sep 10 '16 at 20:14

score 1 · Answer 2 · answered Sep 10 '16 at 20:11

1

Start with $$ (1+x)^m=\sum_{j=0}^{m}{m\choose j}x^j $$ and integrate both sides from $0$ to $1$.

answered Sep 10 '16 at 20:11

carmichael561

54,793

Sorry should I integrate with respect to m. The RHS ${m \choose j}$ is constant. How do you do for $x^j$ . My calculus is weak – Amrita Sep 10 '16 at 20:23
1

No, integrate with respect to $x$. $\int_0^1x^j;dx=\frac{1}{j+1}$, and $\int_0^1(1+x)^m;dx=\frac{2^{m+1}-1}{m+1}$. – carmichael561 Sep 10 '16 at 20:24

Prove the following Combinatorial identity

2 Answers2