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COURSE: JUST 3900 TIPS FOR APLIA Developed By: Ethan Cooper (Lead Tutor) John Lohman Michael Mattocks Aubrey Urwick. Chapters 4-6: Test Review. Chapter 4: Key Concepts. - PowerPoint PPT Presentation
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COURSE: JUST 3900TIPS FOR APLIA
Developed By: Ethan Cooper (Lead Tutor)
John LohmanMichael Mattocks
Aubrey Urwick
Chapters 4-6: Test Review
Chapter 4: Key Concepts Know that this chapter is on variability, which measures
the differences between scores and describes the degree to which the scores are spread out or clustered together.
Variability also measures how well an individual score represents the entire distribution.
The 3 measures of variability: the range, standard deviation, and the variance.
Chapter 4: The Range The range is the distance covered by the scores in a
distribution, from the smallest to the largest score. There are 2 formulas for the range that you should be
aware of for the test: range = URL for Xmax – LRL for Xmin
range = Xmax – Xmin
This is the definition used by many computer programs.
Remember: URL standsfor upper real limit, and LRL stands for lower reallimit.
Chapter 4: The Range Find the range for the following set of scores using both
formulas: 8, 1, 5, 1, 5
Chapter 4: The Range range = URL for Xmax – LRL for Xmin
range = 8.5 – 0.5 = 8 range = Xmax – Xmin
range = 8 – 1 = 7
Chapter 4: Sum of Squares Sum of Squares (SS) is the sum of the squared
deviations. There are 2 formulas you need to know to compute SS:
Definitional Formula (Population): Definitional Formula (Sample): Computational Formula (Population): Computational Formula (Sample):
Use when mean is a whole number.
Use for fractional means.
Chapter 4: Variance Variance is the mean squared deviation, or the average
squared distance from the mean. Population Variance: Sample Variance: The variance will play a bigger role as we move into
inferential statistics in the coming chapters. For now, just know that it is a necessary step to finding the standard deviation.
Chapter 4: Standard Deviation Standard deviation provides a measure of the standard,
or average, distance from the mean. A large standard deviation tells us that our scores are
widely distributed. A small standard deviation tells us that they are clustered
closely around the mean. It is calculated by taking the square root of the variance.
Population Standard Deviation: or Sample Standard Deviation: or
Chapter 4: Standard Deviation Find the standard deviation for the following population
of N =7 scores: 8, 1, 4, 3, 5, 3, 4
Chapter 4: Standard Deviation Step 1: Find the mean
Step 2: Find SS
X (X - µ) (X - µ)2
8 8 – 4 = 0 (4)2 = 161 1 – 4 = -3 (-3)2 = 94 4 – 4 = 0 (0)2 = 03 3 – 4 = -1 (-1)2 = 15 5 – 4 = 1 (1)2 = 13 3 – 4 = -1 (-1)2 = 14 4 – 4 = 0 (0)2 = 0
SS = 8 + 9 + 0 + 1 + 1 + 1 + 0 = 28
Because the mean is a whole number.
Chapter 4: Standard Deviation Step 3: Calculate the variance
Step 4: Find the standard deviation
Chapter 4: Sample Standard Deviation
A sample statistic is unbiased if the average value of the statistic is equal to the population parameter.
A sample statistic is biased if the average value of the statistic either overestimates or underestimates the corresponding population parameter.
To avoid bias when calculating s2 or s, we use n – 1, instead of n.
n – 1 is referred to as degrees of freedom, or df.
Chapter 4: Sample Standard Deviation
Find the standard deviation for the following sample of n = 4 scores: 7, 4, 2, 1
Chapter 4: Sample Standard Deviation
Step 1: Find the mean
Step 2: Find SS
X X2
7 (7)2 = 494 (4)2 = 162 (2)2 = 41 (1)2 = 1
∑ 𝑋=14 ∑ 𝑋 2=70
Because the mean contains decimals.
Chapter 4: Sample Standard Deviation
Step 2: Find SS
Step 3: Calculate the variance
Step 4: Find the standard deviation
Use n-1 in the denominator because we’re working with a sample.
Chapter 4: More About Standard Deviation
It should be noted that adding a constant to each score in a distribution does not change the standard deviation. Remember that standard deviation is a measure of variability, or the distance between scores. If the same number were added to every score, the entire distribution would shift to the right, but the distance between each score would remain the same.
Chapter 4: More About Standard Deviation
However, multiplying every score by a constant would cause the standard deviation to be multiplied by the same constant.
Imagine a distribution that included scores of X = 10 and X = 11. The distance between these scores is only 1 point.
Now imagine we multiply every score in this distribution by 2 points. Our new scores would be X = 20 and X = 22, 2 points apart.
Because the distance between scores changes when we multiply by a constant, the standard deviation also changes by the same constant.
Chapter 5: Key Concepts z-Scores specify the precise location of each X value
within a distribution. The sign of the z-score (+ or -) signifies whether the
score is above the mean (positive) or below the mean (negative).
The numerical value of the z-score describes the distance from the mean by counting the number of standard deviations between X and µ.
The z-score distribution will always have a mean of µ = 0 and a standard deviation of σ = 1.
Chapter 5: z-Scores The formulas for calculating the z-score:
Population z-score: Sample z-score:
Sometimes it’s necessary to calculate the X-value using the z-score, mean, and standard deviation.
Chapter 5: z-Scores For a population with µ = 50 and σ = 8, find the z-score
for each of the following X values: X = 54 X = 42 X = 62 X = 48
Chapter 5: z-Scores X = 54
X = 42
X = 62
X = 48
Chapter 5: Find X Find the X value that corresponds with the following z-
scores: (µ = 50 and σ = 8) z = -0.50 z = 0.75 z = -1.50 z = 0.25
Chapter 5: Find X z = -0.50
z = 0.75
z = -1.50
z = 0.25
Chapter 5: Standardized Distributions
Standardized distributions are composed of scores that have been transformed to create predetermined values for µ and σ.
Standardized distributions are used to make dissimilar distributions comparable.
A z-score distribution is an example of a standardized distribution.
Chapter 5: Standardized Distributions
A distribution with μ = 62 and σ = 8 is transformed into a standardized distribution with μ = 100 and σ = 20. Find the new, standardized score for each of the following X values: X = 60 X = 54 X = 72 X = 66
Chapter 5: Standardized Distributions
Step 1: Find the z-scores X = 60
Step 2: Find the X value for the new distribution
Chapter 5: Standardized Distributions
Step 1: Find the z-scores X = 54
X = 72
X = 66
Chapter 5: Standardized Distributions
Step 2: Find the X values for the new distribution X = 54, z = -1.00
X = 72, z = 1.25
X = 66, z = 0.50
Chapter 6: Key Concepts For a situation in which several different outcomes are
possible, the probability for any specific outcome is defined as a fraction of all the possible outcomes. Probability of A =
Probability can be represented as a fraction, decimal, or percent. p = 0.25 = ¼ = 25%
A random sample requires that each individual in the population has an equal chance of being selected.
An independent random sample requires that each individual has an equal chance of being selected and that the probability of being selected remains constant from one selection to the next.
Chapter 6: Random Sampling Sampling with replacement requires that selected
individuals be returned to the population before the next selection is made.
This ensures that the probability of selection remains constant from one selection to the next.
Unless otherwise specified, random sampling assumes replacement.
Probability does not remain constant when sampling without replacement.
Chapter 6: Random Sampling A psychology class consists of 14 males and 36 females.
If the professor selects names from the class list using random sampling,
a) What is the probability that the first student selected will be a female?
b) If a random sample of n = 3 students is selected and the first two are both females, what is the probability that the third student selected will be a male?
Chapter 6: Random Samplinga) p = 36/50 = 0.72b) p = 14/50 = 0.28 Because this is a random sample, replacement is assumed.
Therefore, the probability of selection remains constant.
Chapter 6: The Normal Distribution
When dealing with probability in this chapter, we are dealing with normal distributions.
The unit normal table lists proportions of the normal distribution for a full range of possible z-score values.
Percentage of the population located between z = 0 andZ = 1.
Normal distributions are symmetrical.
34.13%
13.59%
2.28%
Chapter 6: The Unit Normal Table
The first column (A) in the table lists z-scores corresponding to different positions in a normal distribution.
Column B presents the proportion in the body. The body is always the larger part of the distribution.
Column C presents the proportion in the tail. The tail is always the smaller part of the distribution.
Column D identifies the proportion located between the mean and the z-score.
Note: The normal distribution is symmetrical, so the proportions on the right are the same as the proportions on the left. And although the z-score values change signs (+ and -), the proportions are always positive.
Chapter 6: The Unit Normal Table
Find each of the probabilities for a normal distribution: p(z > 0.25) p(z > -0.75) p(z < 1.20) p(-0.25 < z < 0.25) p(-1.25 < z < 0.25)
Chapter 6: The Unit Normal Table
p(z > 0.25)
p(z > -0.75)
p(z < 1.20)
p(-0.25 < z < 0.25)
p(-1.25 < z < 0.25)
p = 0.4013
p = 0.7734
p = 0.8849
p = 0.0987
p = 0.4931
Find the proportion incolumn D for both z-scoresand add them together.
Chapter 6: Binomial Distributions
When a variable is measured on a scale consisting of exactly two categories, the resulting data are called binomial.
The normal distribution can be used to compute probabilities with binomial data.
The two categories are defined as A and B. The probabilities associated with each category are:
p = p(A) = the probability of A q = p(B) = the probability of B
The number of individuals or observations in the sample is identified by n.
The variable X refers to the number of times category A occurs in the sample.
p + q = 1.00
Chapter 6: Binomial Distributions
Binomial distributions tend to approximate a normal distribution when two conditions are met: pn ≥ 10 qn ≥ 10
Under these circumstances, the binomial distribution has the following parameters: Mean: µ = pn Standard deviation: σ = z = =
Chapter 6: Binomial Distributions
Notice that each X value is represented by a bar in the histogram. This means a score of X = 8 spans the interval of 7.5 to 8.5.
Chapter 6: Binomial Distributions
A multiple choice test has 48 questions, each with four response choices. If a student is simply guessing at the answers,
a) What is the probability of guessing correctly for any question?b) On average, how many questions would a student get correct
for the entire test?c) What is the probability that a student would get more than15
answers correct simply by guessing?d) What is the probability that a student would get 15 or more
answers correct simply by guessing?
Chapter 6: Binomial Distributions
a) p = ¼ = 0.25b) pn = 0.25(48) = 12
Chapter 6: Binomial Distributions
c) Step 1: Find pn and qn pn = (0.25)(48) = 12 qn = 0.75(48) = 36
Step 2: Find μ and σ µ = pn = 12 σ = = = =
Step 3: Find Z z = = = = =
Step 4: Find the proportion p(z > 1.17) = 0.1210
Both are greater than 10, so our distribution approximatesa normal distribution.
URL because we areexcluding the score X = 15.
Chapter 6: Binomial Distributions
d) Step 1: Find pn and qn pn = (0.25)(48) = 12 qn = 0.75(48) = 36
Step 2: Find μ and σ µ = pn = 12 σ = = = =
Step 3: Find Z z = = = = =
Step 4: Find the proportion p(z > 0.83) = 0.2033
LRL because we areincluding the score X = 15.