Advanced book on Mathematics Olympiad

296 6 Combinatorics and Probability

Solution.Let us analyze the quotient

pk,m(x)=

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

(xm− 1 )(xm−^1 − 1 )···(x− 1 )

,

which conjecturally is a polynomial with integer coefficients. The main observation
is that

lim

x→ 1

pk,m(x)=lim

x→ 1

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

(xm− 1 )(xm−^1 − 1 )···(x− 1 )

=lim

x→ 1

xk+m− 1

x− 1

···

xk+^1 − 1

x− 1

·

x− 1

xm− 1

···

x− 1

x− 1

=

(k+m)(k+m− 1 )···(k+ 1 )

m·(m− 1 )··· 1

=

(

k+m

m

)

.

With this in mind, we treatpk,m(x)as some kind of binomial coefficient. Recall that one
way of showing that

(n

m

)

=m!(nn−!m)!is an integer number is by means of Pascal’s triangle.
We will construct a Pascal’s triangle for the polynomialspk,m(x). The recurrence relation
(
k+m+ 1
m

)

=

(

k+m

m

)

+

(

k+m

m− 1

)

has the polynomial analogue

(xk+m+^1 − 1 )···(xk+^2 − 1 )

(xm− 1 )···(x− 1 )

=

(xk+m− 1 )···(xk+^1 − 1 )

(xm− 1 )···(x− 1 )

+xk+^1

(xk+m− 1 )···(xk+^2 − 1 )

(xm−^1 − 1 )···(x− 1 )

.

Now the conclusion follows by induction onm+k, with the base case the obvious
xk+^1 − 1
x− 1 =x

k+xk− (^1) +···+1. 
In quantum physics the variablexis replaced byq=ei
, where
is Planck’s con-
stant, and the polynomialspn−m,m(q)are denoted by
(n
m

)

qand called quantum binomial
coefficients (or Gauss polynomials). They arise in the context of the Heisenberg uncer-
tainty principle. Specifically, ifPandQare the linear transformations that describe,
respectively, the time evolution of the momentum and the position of a particle, then
PQ=qQP. The binomial formula for them reads

(Q+P)n=

∑n

k= 0

(

n

k

)

q

QkPn−k.

The recurrence relation we obtained a moment ago,