Mathematics for Computer Science

15.12. The Pigeonhole Principle 479

Teaching Assistants. Here is another colorful example of a combinatorial argu-

ment.

Theorem 15.11.2. n

X

rD 0

n

r

!

2n

nr

!

D

3n

n

!

Proof. We give a combinatorial proof. LetSbe alln-card hands that can be dealt

from a deck containingndifferent red cards and2ndifferent black cards. First,

note that every3n-element set has

jSjD

3n

n

!

n-element subsets.

From another perspective, the number of hands with exactlyrred cards is

n

r

!

2n

nr

!

since there are

n

r

ways to choose therred cards and

2n

nr

ways to choose the

nrblack cards. Since the number of red cards can be anywhere from 0 ton, the

total number ofn-card hands is:

jSjD

Xn

rD 0

n

r

!

2n

nr

!

:

Equating these two expressions forjSjproves the theorem. 

Finding a Combinatorial Proof

Combinatorial proofs are almost magical. Theorem 15.11.2 looks pretty scary, but

we proved it without any algebraic manipulations at all. The key to constructing a

combinatorial proof is choosing the setSproperly, which can be tricky. Generally,

the simpler side of the equation should provide some guidance. For example, the

right side of Theorem 15.11.2 is

3n

n

, which suggests that it will be helpful to

chooseSto be alln-element subsets of some3n-element set.

15.12 The Pigeonhole Principle

Here is an old puzzle: