Advanced High-School Mathematics

(Tina Meador) #1

SECTION 6.1 Discrete Random Variables 329


Next,


∑∞
n=1

n^2 (1−p)n−^1 =

∑∞
n=1

n(n−1)(1−p)n−^1 +

∑∞
n=1

n(1−p)n−^1

= (1−p)

∑∞
n=1

n(n−1)(1−p)n−^2 +

∑∞
n=1

n(1−p)n−^1

= (1−p)

d^2
dx^2

(1 +x+x^2 +···)

∣∣
∣∣
∣x=1−p+

1

p^2

= (1−p)
d^2
dx^2

(
1
1 −x

)∣∣
∣∣
∣x=1−p+

1

p^2

=

2(1−p)
p^3

+

1

p^2

=

2 −p
p^3

Therefore,


Var(X) =

2 −p
p^2


1

p^2

=

1 −p
p^2

6.1.5 The binomial distribution


In this situation we performnindependent trials, where each trial has
two outcomes—call them success and failure. We shall let p be the
probability of success on any trial, so that the probability of failure on
any trial is 1−p. The random variableXis the total number of successes
out of thentrials. This implies, of course, that the distribution of X
is summarized by writing


P(X=k) =

Ñ
n
k

é
pk(1−p)n−k.

The mean and variance ofX are very easily computed once we realize
thatXcan be expressed as a sum ofnindependentBernoullirandom
variables. The Bernoulli random variableBis what models the tossing
of a coin: it has outcomes 0 and 1 with probabilities 1−p and p,
respectively. Very simple calculations shows that


E(B) =p and Var(B) =p(1−p).
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