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Document related concepts

Central limit theorem wikipedia , lookup

Transcript 
Welcome to .
Week 07 Thurs .
MAT135 Statistics
Probability
We’ve studied probability for
things with outcomes like:
H T
1 2 3 4 5 6
Win Lose
Probability
These were all “discrete” outcomes
Probability
Now we will look at probabilities
for things with an infinite
number of outcomes that can
be considered continuous
Probability
You can think of smooth
quantitative data graphs as a
series of skinnier and skinnier
bars
Probability
When the width of the bars
reach “zero” the graph is
perfectly smooth
Probability
SO, a smooth quantitative
(continuous) graph can be
thought of as a bar chart
where the bars have width zero
Probability
The probability for a continuous
graph is the area of its bar:
height x width
Probability
But…
the width of the bars on a
continuous graph are zero, so
P = Bar Area = height x zero
All the probabilities are
P = 0 !
Probability
Yep.
It’s true.
The probability of any specific
value on a continuous graph is:
ZERO
Probability
So…
Instead of a specific value, for
continuous graphs we find the
probability of a range of values
– an
area under
the curve
Probability
Because this would require
yucky calculus to find the
probabilities, commonly-used
continuous graphs are included
in Excel
Yay!
Questions?
Normal Probability
The most popular continuous
graph in statistics is the
NORMAL DISTRIBUTION
Normal Probability
Two descriptive statistics
completely define the shape of
a normal distribution:
Mean µ
Standard deviation σ
Normal Probability
PROJECT QUESTION 1
Suppose we have a normal
distribution, µ = 10
?
Normal Probability
PROJECT QUESTION 1
Suppose we have a normal
distribution, µ = 10 σ = 5
?
?
? 10
?
?
?
Normal Probability
PROJECT QUESTION 1
Suppose we have a normal
distribution, µ = 10 σ = 5
-5
0
5 10 15 20 25
Normal Probability
The standard normal
distribution has a mean µ = 0
and a standard deviation σ = 1
Normal Probability
PROJECT QUESTION 2
For the standard normal
distribution, µ = 0 σ = 1
?
?
?
?
?
?
?
Normal Probability
PROJECT QUESTION 2
For the standard normal
distribution, µ = 0 σ = 1
-3 -2 -1 0
1
2
3
Normal Probability
The standard normal is also
called “z”
Normal Probability
We can change any normallydistributed variable into a
standard normal
One with:
mean = 0
standard deviation = 1
Normal Probability
To calculate a “z-score”:
Take your value x
Subtract the mean µ
Divide by the standard
deviation σ
Normal Probability
z = (x - µ)/σ
Normal Probability
IN-CLASS PROBLEMS 3,4,5
Suppose we have a normal
distribution, µ = 10 σ = 2
z = (x - µ)/σ = (x-10)/2
Calculate the z values for
x = 9, 10, 15
Normal Probability
IN-CLASS PROBLEMS 3,4,5
z = (x - µ)/σ = (x-10)/2
x .
9 z = (9-10)/2 = -1/2
Normal Probability
IN-CLASS PROBLEMS 3,4,5
z = (x - µ)/σ = (x-10)/2
x .
9 z = (9-10)/2 = -1/2
10 z = (10-10)/2 = 0
Normal Probability
IN-CLASS PROBLEMS 3,4,5
z = (x - µ)/σ = (x-10)/2
x .
9 z = (9-10)/2 = -1/2
10 z = (10-10)/2 = 0
15 z = (15-10)/2 = 5/2
Normal Probability
-3 -2 -1 0
|
-1/2
1
2
3
|
5/2
Normal Probability
But…
What about the probabilities??
Normal Probability
We use the properties of the
normal distribution to calculate
the probabilities
Normal Probability
IN-CLASS PROBLEMS 6,7,8
What is the probability of
getting a z-score value between
-1 and 1
-2 and 2
-3 and 3
Normal Probability
You can use sneaky logic to
calculate other probabilities
Normal Probability
IN-CLASS PROBLEM 9
If the area under the entire
curve is 100%, how much of the
graph lies above “x”?
Normal Probability
P(x ≥ b) = 1 - P(x ≤ b)
or
= 100% - P(x ≤ b)
or
= 100% - 90% = 10%
Normal Probability
What about probabilities
between two “x” values?
Normal Probability
P(a ≤ x ≤ b)
equals
P(x ≤ b) – P(x ≤ a)
minus
Normal Probability
IN-CLASS PROBLEMS 10,11,12
What is the probability of
getting a z-score value between
-1 and 0
-2 and 1
-3 and -2
Normal Probability
You can use your
calculators to calculate
other normal
probabilities!
Normal Probability
IN-CLASS PROBLEM 13
Find the probability that a zscore is between -1.5 and 2
P(-1.5 ≤ z ≤ 2)
Normal Probability
IN-CLASS PROBLEM 13
Press 2nd VARS [DISTR]
Scroll down to
2:normalcdf(
Press ENTER
Normal Probability
IN-CLASS PROBLEM 13
It will say:
normalcdf(
Type:
-1.5,2)
Press ENTER
Answer:
0.91044
Normal Probability
IN-CLASS PROBLEM 14
What is the probability of
getting a z-score value between
–1 and 2.5 ?
Questions?
You survived!
Turn in your homework!
Don’t forget
your homework
due next week!
Have a great
rest of the week!
www.playbuzz.com
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