Advanced book on Mathematics Olympiad

6.2 Binomial Coefficients and Counting Methods 295

(

n

k

)

=

(

n− 1

k

)

+

(

n− 1

k− 1

)

allows the binomial coefficients to be arranged inPascal’s triangle:

1

11

121

1331

14641

1 5 10 10 5 1

... ... ... ... ... ... ... ... ... ... ... ...

Here every entry is obtained by summing the two entries just above it.
This section presents applications of the basic properties of binomial coefficients.
Here is a problem from the 2001 Hungarian Mathematical Olympiad.

Example.Letmandnbe integers such that 1≤m≤n. Prove thatmdivides the number

n

m∑− 1

k= 0

(− 1 )k

(

n

k

)

.

Solution.We would like to express the sum in closed form. To this end, we apply the
recurrence formula for binomial coefficients and obtain

n

m∑− 1

k= 0

(− 1 )k

(

n

k

)

=n

m∑− 1

k= 0

(− 1 )k

((

n− 1

k

)

+

(

n− 1

k− 1

))

=n

m∑− 1

k= 0

(− 1 )k

(

n− 1

k

)

−n

m∑− 2

k= 0

(− 1 )k

(

n− 1

k

)

=n(− 1 )m−^1

(

n− 1

m− 1

)

=m(− 1 )m−^1

(

n

m

)

.

The answer is clearly divisible bym. 

The methods used in proving combinatorial identities can be applied to problems
outside the field of combinatorics. As an example, let us take a fresh look at a property
that we encountered elsewhere in the solution to a problem about polynomials.

Example.Ifkandmare positive integers, prove that the polynomial

(xk+m− 1 )(xk+m−^1 − 1 )···(xk+^1 − 1 )

is divisible by

(xm− 1 )(xm−^1 − 1 )···(x− 1 )

in the ring of polynomials with integer coefficients.