Applied Statistics and Probability for Engineers

238 CHAPTER 7 POINT ESTIMATION OF PARAMETERS

(b) Show that the log likelihood is maximized by solving the

equations

(c) What complications are involved in solving the two equa-

tions in part (b)?

7-24. Consider the probability distribution in Exercise 7-22.

Find the moment estimator of .

7-25. Let X 1 , X 2 ,, Xnbe uniformly distributed on the in-

terval 0 to a. Show that the moment estimator of ais

Is this an unbiased estimator? Discuss the reasonableness of

this estimator.

7-26. Let X 1 , X 2 ,, Xnbe uniformly distributed on the

interval 0 to a. Recall that the maximum likelihood estimator

of ais.

(a) Argue intuitively why cannot be an unbiased estimator

for a.

(b) Suppose that. Is it reasonable that

consistently underestimates a? Show that the bias in the

estimator approaches zero as ngets large.

(c) Propose an unbiased estimator for a.

(d) Let Ymax(Xi). Use the fact that if and only

if each to derive the cumulative distribution func-

tion of Y. Then show that the probability density function

of Yis

Use this result to show that the maximum likelihood esti-

mator for ais biased.

7-27. For the continuous distribution of the interval 0 to a,

we have two unbiased estimators for a: the moment estimator

and , where max(Xi) is

the largest observation in a random sample of size n(see

Exercise 7-26). It can be shown that V 1 aˆ 12 a^2  13 n 2 and that

aˆ 1  2 X ˆa 2  31 n (^12) n 4 max 1 Xi 2
f 1 y 2 •
ny n^1
an
,0ya
0 , otherwise
Xiy
Yy
E 1 aˆ 2 na 1 n 12 aˆ
aˆ
aˆmax 1 Xi 2
p
aˆ 2 X.
p

£a
n
i 1
xi
n
§
(^1) 
≥
a
n
i 1
xi^ ln 1 xi 2
a
n
i 1
xi

a
n
i 1
ln 1 xi 2
n ¥
 1

. Show that if n 1 , is a better
estimator than. In what sense is it a better estimator of a?
7-28. Consider the probability density function

Find the maximum likelihood estimator for .

7-29. The Rayleigh distribution has probability density

function

(a) It can be shown that Use this information to

construct an unbiased estimator for .

(b) Find the maximum likelihood estimator of . Compare

your answer to part (a).

(c) Use the invariance property of the maximum likelihood

estimator to find the maximum likelihood estimator of the

median of the Raleigh distribution.

7-30. Consider the probability density function

(a) Find the value of the constant c.

(b) What is the moment estimator for ?

(c) Show that is an unbiased estimator for .

(d) Find the maximum likelihood estimator for .

7-31. Reconsider the oxide thickness data in Exercise 7-12

and suppose that it is reasonable to assume that oxide thick-

ness is normally distributed.

(a) Use the results of Example 7-9 to compute the maximum

likelihood estimates of and ^2.

(b) Graph the likelihood function in the vicinity of and ,

the maximum likelihood estimates, and comment on its

shape.

7-32. Continuation of Exercise 7-31. Suppose that for the

situation of Exercise 7-12, the sample size was larger (n40)

but the maximum likelihood estimates were numerically

equal to the values obtained in Exercise 7-31. Graph the

likelihood function for n40, compare it to the one from

Exercise 7-31 (b), and comment on the effect of the larger

sample size.

ˆ ˆ^2

ˆ 3 X

f 1 x 2 c 11 x 2 ,  1 x 1

E 1 X 22  2 .

f 1 x 2 

x



ex

(^2)  2 
, x0, 0 
f 1 x 2 
1
^2
xex, 0 x, 0 
aˆ
V 1 aˆ 22 a^2  3 n 1 n 224 ˆa 2
7-4 SAMPLING DISTRIBUTIONS
Statistical inference is concerned with making decisionsabout a population based on the
information contained in a random sample from that population. For instance, we may be
interested in the mean fill volume of a can of soft drink. The mean fill volume in the
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