Why is it that I can change the random variable X into a Z score?

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Transcript Why is it that I can change the random variable X into a Z score?

CHAPTER 5 REVIEW
As a part of a promotion for a new type of cracker, free
trial samples are offered to shoppers in a local
supermarket. The probability that a shopper will buy a
packet of crackers after tasting the free sample is 0.20.
Different shoppers can be regarded as independent trials.
If the random variable X is the number of the next 100
shoppers that buy a packet of the crackers after tasting a
free sample, then the probability that 20 or more shoppers
buy a packet is approximately...
1. The 100 trials are independent.
2. There is a fixed number of trials, 100.
3. There only two possible outcomes for each event.
4. The probability of success is fixed from trial to trial.
As a part of a promotion for a new type of cracker, free
trial samples are offered to shoppers in a local
supermarket. The probability that a shopper will buy a
packet of crackers after tasting the free sample is 0.20.
Different shoppers can be regarded as independent trials.
If the random variable X is the number of the next 100
shoppers that buy a packet of the crackers after tasting a
free sample, then the probability that 20 or more shoppers
buy a packet is approximately...
The random variable X is binomial.
P(X  20) = 1- P(X  19)
Using the binomial program on your TI or Excel I get
approximately 46%.
There are 20 multiple choice questions on an exam, each
having responses a, b, c, or d. Each question is worth 5
points and only one option per question is correct. Suppose
the student guesses the answer to each question, and the
guesses from question to question are independent. The
probability that the student gets between 5 and 10 questions
correct, including 5 and 10 is...
There are 20 multiple choice questions on an exam, each
having responses a, b, c, or d. Each question is worth 5
points and only one option per question is correct. Suppose
the student guesses the answer to each question, and the
guesses from question to question are independent. The
probability that the student gets between 5 and 10 questions
correct, including 5 and 10 is...
1. The 20 trials are independent.
2. There is a fixed number of trials, 20.
3. There only two possible outcomes for each event.
4. The probability of success is fixed from trial to trial, p = 0.25.
There are 20 multiple choice questions on an exam, each
having responses a, b, c, or d. Each question is worth 5
points and only one option per question is correct. Suppose
the student guesses the answer to each question, and the
guesses from question to question are independent. The
probability that the student gets between 5 and 10 questions
correct, including 5 and 10 is...
The random variable X is binomial: n = 20 and p = 0.25
P(5  X  10) = P(X  10) - P(X  4)
 58.1% using the program on the TI or
Excel.
There are 20 multiple choice questions on an exam, each
having responses a, b, c, or d. Each question is worth 5
points and only one option per question is correct. Suppose
the student guesses the answer to each question, and the
guesses from question to question are independent. The
probability that the student gets between 5 and 10 questions
correct, including 5 and 10 is...
Would this problem be suitable to use the normal
approximation?
Since np = 20(0.25)  10 it would not be suitable to use a
normal approximation.
An important result in statistics says that in many situations
for large sample sizes the sampling distribution of the
sample mean is approximately normal.
This famous result is known as...
a. the law of large numbers.
b. the multiplication rule.
c. the central limit theorem.
d. the bell curve.
Suppose that you are a student worker in the statistics
department and they agree to pay you using the random pay
system. Each week the department chair flips a coin. If it
comes up heads, your pay for the week is $80 and if it comes
up tails your pay for the week is $40. Your friend is working
for the engineering department and makes $65 per week. The
probability that your total earnings in 100 weeks are on
average more that your friends is approximately
First we need to determine what type of
distribution we have here.
I will organize the information. The pay is determined by the
flip of a coin. Since the variable of interest is the amount of
money I have earned, let the random variable X, be the amount
of money I have earned.
Suppose that you are a student worker in the statistics
department and they agree to pay you using the random pay
system. Each week the department chair flips a coin. If it
comes up heads, your pay for the week is $80 and if it comes
up tails your pay for the week is $40. Your friend is working
for the engineering department and makes $65 per week. The
probability that your total earnings in 100 weeks are on
average more that your friends is approximately...
Probability Distribution:
X
$40
$80
P(x)
0.5
0.5
When I look at the question I can see that I want to
calculate P(X  $65). Thus, I am really considering the
sampling distribution of X, for n = 100. In other words, for
every run of 100, what percentage generate an average
greater than $65?
Suppose that you are a student worker in the statistics
department and they agree to pay you using the random pay
system. Each week the department chair flips a coin. If it
comes up heads, your pay for the week is $80 and if it comes
up tails your pay for the week is $40. Your friend is working
for the engineering department and makes $65 per week. The
probability that your total earnings in 100 weeks are on
average more that your friends is approximately...
Probability Distribution:
X
$40
$80
P(x) 0.5
0.5
P(X  $65).
Now I need to consider how to calculate this probability.
The distribution X is not normal, it is discreet. However, the
central limit theorem says that the sampling distribution of X
is approximately normal for n large enough.
Suppose that you are a student worker in the statistics
department and they agree to pay you using the random pay
system. Each week the department chair flips a coin. If it
comes up heads, your pay for the week is $80 and if it comes
up tails your pay for the week is $40. Your friend is working
for the engineering department and makes $65 per week. The
probability that your total earnings in 100 weeks are on
average more that your friends is approximately...
Probability Distribution:
X
P(x)
P(X  $65).
Thus, we need to find  and .
 = 40(0.5) + 80 (0.5) = 20 + 40 = 60.
2 = (40-60)2 (0.5) + (80-60)2(0.5)
 = 20
$40
$80
0.5
0.5
Suppose that you are a student worker in the statistics
department and they agree to pay you using the random pay
system. Each week the department chair flips a coin. If it
comes up heads, your pay for the week is $80 and if it comes
up tails your pay for the week is $40. Your friend is working
for the engineering department and makes $65 per week. The
probability that your total earnings in 100 weeks are on
average more that your friends is approximately...
Probability Distribution:
 = 60 and  = 20
P(X  $65) = P (Z >
65  60
20
100
)
P(Z > 2.5) = .0062
X
$40
$80
P(x)
0.5
0.5
There are 20 multiple choice questions on an exam, each
having responses a, b, c, or d. Each question is worth
5 points and only one option per question is correct. Suppose
the student guesses the answer to each question, and the
guesses from question to question are independent. The
probability that the student gets no questions correct is...
Let the random variable X count the number of incorrect
responses. We note this is a binomial setting, but since we
want to calculate an extreme event we can rely on the same
technique we used in chapter 4.
We want to calculate
P(X = 20) =
P(answer 1st question incorrect and second incorrect and ... and last incorrect)=
(3/4)(3/4)...(3/4) = (3/4)20 = 0.00317
The weights of medium oranges packaged by an orchard are
normally distributed with a mean of 14 ounces and a standard
deviation of 2 ounces. What is the probability of choosing 4
oranges at random and having the average weight exceed 15
ounces?
We want to calculate P(X > 15) where the random variable X
is the average weight of 15 medium oranges. So this is a
problem involving the sampling distribution of the mean.
P(X > 15) = P(Z
15  14
> 2
4
)
= P(Z > 1) = 0.1587
Why is it that I can
change the random
variable X into a Z
score?
The weights of medium oranges packaged by an orchard are
normally distributed with a mean of 14 ounces and a standard
deviation of 2 ounces. What is the probability of choosing 4
oranges at random and having the average weight exceed 15
ounces?
We want to calculate P(X > 15) where the random variable X
is the average weight of 15 medium oranges. So this is a
problem involving the sampling distribution of the mean.
Why is it that I can change the random variable X into a Z
score? The distribution is normal to begin with so the sampling
distribution is also normally distributed.
A population’s distribution is normal. If we look at the
sampling distribution of this population, where the sample
size is n = 2, then we would find that
a. the sampling distribution is not normal.
b. the sampling distribution is approximately normal.
c. the sampling distribution is exactly normal.
d. it is impossible to know without running some
simulations.
A population’s distribution is not normal. If we look at the
sampling distribution of this population, where the sample
size is n = 40, then we would find that
a. the sampling distribution is not normal.
b. the sampling distribution is approximately normal.
c. the sampling distribution is exactly normal.
d. it is impossible to know without running some
simulations.
A survey asks a random sample of 1500 adults in Ohio if
they support an increase in the state sales tax from 5% to
6%, with the additional revenue going to education. Let p
denote the proportion in the sample that say they support the
increase. Suppose that 40% of all adults in Ohio support the
increase. The probability that p is more than 0.45 is
Instead of dealing with the population proportion, let us
look a the count instead. If we surveyed 1500 adults in this
population where the population proportion is 0.45 then,
0.40(1500) = 600, we would expect around 600 adults to be
in favor of the proposal.
So we want to know P(X > 675), where the random variable
X counts the number of people in favor of the proposal.
A survey asks a random sample of 1500 adults in Ohio if
they support an increase in the state sales tax from 5% to
6%, with the additional revenue going to education. Let p
denote the proportion in the sample that say they support the
increase. Suppose that 40% of all adults in Ohio support the
increase. The probability that p is more than 0.45 is
So we want to know P(X > 675), where the random variable
X counts the number of people in favor of the proposal.
We can use a normal approximation here since np > 10 and
n(1 - p) > 10 also. We have  = 600 and  = 18.97.
P(X > 675) = P(Z >
674.5  600
18.97
)0
The amount of coffee (in ounces) filled in a jar by a machine
has a normal distribution with a mean amount of 16 ounces
and a standard deviation of 0.2 ounces.
A. The company producing this
product can only sell jars that have
16 or more ounces of coffee. What
percentage of the jars, in the long
run, will not be sellable?
The amount of coffee (in ounces) filled in a jar by a machine
has a normal distribution with a mean amount of 17 ounces
and a standard deviation of 0.4 ounces.
A. The company producing this product can only
sell jars that have 16 or more ounces of coffee.
What percentage of the jars, in the long run, will
not be sellable?
P(X < 16), where the random
variable X is the amount of coffee in
the jar in ounces.
P(X < 16) = P(Z <
16  17 )
.4
= P(Z < -2.5)
= 0.00621
The amount of coffee (in ounces) filled in a jar by a machine
has a normal distribution with a mean amount of 17 ounces
and a standard deviation of 0.4 ounces.
B. If one were to randomly select 4 jars from the production
line, what is the probability of 2 or more jars being rejected?
Let the random variable X count the number
of jars out of 4 that will be rejected. From
the past problem we know that the
probability of producing a rejected jar is
0.00621.
Note: if we assume independence then we
have a binomial situation.
So, I will calculate P(X  2) using a binomial function.
P(X  2) = 0.00029
The amount of coffee (in ounces) filled in a jar by a machine
has a normal distribution with a mean amount of 17 ounces
and a standard deviation of 0.4 ounces.
C. If one were to randomly select 4 jars from the production
line, what is the probability that the average amount of coffee in
the four jars is 16.5 ounces or less?
Since we are considering the average of the
four jars, it is a sampling distribution
problem. We want P(X < 16.5).
So, I will calculate P(X < 16.5) = P(Z
16.5  17
< .4
4
) = P(Z < -2.5) =
0.00621.
THE END ?