Binomial vs. Geometric
Chapter 6
Binomial and Geometric
Random Variables
Combinations
Formula:n
k
n
k n k
FHGIKJ
!
! !a fPractice:
16
4. FHGIKJ
6
4 6 4
!
! !a f
6 5 4 3 2 1
4 3 2 1 2 1a f
6 5
2 1 15
28
5. FHGIKJ
8
5 3
!
! !
8 7 6 5
5 3 2 1
!
! 56
Developing the FormulaX
P X( )
Outcomes Probability Rewritten
0
OcOcOc (. )(. )(. )75 75 75
.4219
1
OOcOc
OcOOc
OcOcO
(. )(. )(. )25 75 75
.4219
2
OOOc
OOcOOcOO
(. )(. )(. )25 25 75
.1407
3
OOO (. )(. )(. )25 25 25
.0156
1 .253a f
3 . .25 752a f a f1
3 . .25 751 2a f a f
.750a f
1 25 750 3
. .a f a f3
0
FHGIKJ
3
1
FHGIKJ
3
2
FHGIKJ
3
3
FHGIKJ
Developing the Formula
Rewritten
1 .253a f
3 . .25 752a f a f1
3 . .25 751 2a f a f
.750a f
1 25 750 3
. .a f a f3
0
FHGIKJ
3
1
FHGIKJ
3
2
FHGIKJ
3
3
FHGIKJ
n = # of observations
p = probablity of success
k = given value of variable
P X k( ) n
k
FHGIKJ pk
1
pn ka f
Binomial vs. GeometricThe Binomial Setting The Geometric Setting
What is
Binomial???
Just check your
BINS
What is
Geometric???
Just check your
BITS
Binomial vs. GeometricThe Binomial Setting The Geometric Setting
1. Binary: Only two possible
Outcomes (Success/Fail)
2. Independent: The
observations are all
independent
3. Number: There is a fixed
number of trials
4. Success: The probability
of success is the same for
each trial
4. Success: The probability
of success is the same for
each trial
1. Binary: Only two possible
outcomes (Success/Fail)
2. Independent: The
observations are all
independent
3. Trials: We go until the first
success
Working with probability distributions
State the distribution to be used
Binomial or Geometric
Define the variable
X = number of …
State important numbers
Binomial: n & p
Geometric: p
Twenty-five percent of the customers entering a grocery store between 5 p.m. and 7 p.m. use an express checkout. Consider five randomly selected customers, and let X denote the number among the five who use the express checkout.
binomial
X = # of people use express
n = 5 p = .25
What is the probability that two used express checkout?
binomial
X = # of people use express
n = 5 p = .25
2P X 5
2
2
.25 3
.75 .2637
What is the probability that at least four used express checkout?
binomial
X = # of people use express
n = 5 p = .25
4P X 5
4
4
.25 1
.75
.0156
55
.255
“Do you believe your children will have a higher standard of living than you have?” This question was asked to a national sample of American adults with children in a Time/CNN poll (1/29,96). Assume that the true percentage of all American adults who believe their children will have a higher standard of living is .60. Let X represent the number who believe their children will have a higher standard of living
from a random sample of 8 American adults.
binomial
X = # of people who believe…
n = 8 p = .60
Interpret P(X = 3) and find the numerical answer.
binomial
X = # of people who believe
n = 8 p = .60
3P X 8
3
3
.6 5
.4 .1239
The probability that 3 of the people from the
random sample of 8 believe their children will
have a higher standard of living.
Find the probability that none of the parents believe their children will have a higher standard.
binomial
X = # of people who believe
n = 8 p = .60
0P X 8
0
0
.6 8
.4 .0007
The Mean and Standard Deviation of a Binomial Random
VariableIf X is a binomial random variable with probability of success p on each trial and n number of trials, the expected value and std. dev. of the random variable is
x np (1 )x np p
Developing the Geometric Formula
X Probability
1 16
25
61
6d id i3 5
65
61
6d id id i4
56
56
56
16d id id id i
P X n a f 11
pna f p
The Mean of a Geometric Random Variable
If X is a geometric random variable with probability of success p on each trial, the expected value of the random variable (the expected number of trials to get the first success) is
1
p
Suppose we have data that suggest that 3% of a company’s hard disc drives are defective. You have been asked to determine the probability that the first defective hard drive is the fifth unit tested.
geometric
X = # of disc drives until defective
p = .03
5P X 4
.97 .03 .0266
A basketball player makes 80% of her free throws. We put her on the free throw line and ask her to shoot free throws until she misses one. Let X = the number of free throws the player takes until she misses.
geometric
X = # of free throws until miss
p = .20
What is the probability that she will make 5 shots before she misses?
geometric
X = # of free throws until miss
p = .20
6P X 5
.80 .20 .0655
What is the probability that she will miss 5 shots before she makes one?
geometric
Y = # of free throws until make
p = .80
6P Y 5
.20 .80 .00026
What is the probability that she will make at most 5 shots before she misses?
geometric
X = # of free throws until miss
p = .20
6P X .20 .80 .20
.7379
2
.80 .20
3
.80 .20 4
.80 .20 5
.80 .20