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Chapter 8. Introduction to Hypothesis Testing. Name of the game…. Hypothesis testing Statistical method that uses sample data to evaluate a hypothesis about a population. Experimental Hypotheses. Experimental hypotheses describe the predicted outcome we may or may not find in an experiment.
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Chapter 8 Introduction to Hypothesis Testing
Name of the game… • Hypothesis testing • Statistical method that uses sample data to evaluate a hypothesis about a population
Experimental Hypotheses Experimental hypotheses describe the predicted outcome we may or may not find in an experiment.
Order of Procedure • State hyp about pop • Before selecting a sample..use hyp to predict characteristics that sample should have • Obtain random sample • Compare sample data w/ prediction made in hyp
Of interest to the researcher… • Did the treatment have any effect on the individuals • Must be large (significant) differences in means
New Statistical Notation • The symbol for greater than is >. • The symbol for less than is <. • The symbol for greater than or equal tois ≥. • The symbol for less than or equal tois ≤. • The symbol for not equal to is ≠.
The Role of Inferential Statistics in Research
Sampling Error Remember: Sampling error results when random chance produces a sample statistic that does not equal the population parameter it represents.
Null Hypothesis H0 The null hypothesis describes the population parameters that the sample data represent if the predicted relationship does not exist.
Alternative Hypothesis H1 The alternative hypothesis describes the population parameters that the sample data represent if the predicted relationship exists.
Interpreting Significant Results • When we reject H0 and accept H1, we do not prove that H0 is false • While it is unlikely for a mean that lies within the rejection region to occur, the sampling distribution shows that such means do occur once in a while
Failing to Reject H0 • When the statistic does not fall beyond the critical value, the statistic does not lie within the region of rejection, so we do not reject H0 • When we fail to reject H0 we say the results are nonsignificant. Nonsignificant indicates that the results are likely to occur if the predicted relationship does not exist in the population.
Interpreting Nonsignificant Results • When we fail to reject H0, we do not prove that H0 is true • Nonsignificant results provide no convincing evidence—one way or the other—as to whether a relationship exists in nature
Errors in Statistical Decision Making
Type I Errors • A Type I error is defined as rejecting H0 when H0 is true • In a Type I error, there is so much sampling error that we conclude that the predicted relationship exists when it really does not • The theoretical probability of a Type I error equals a
Alpha a • Probability that the test will lead to a Type I error • Alpha level determines the probability of obtaining sample data in the critical region even though the null hypo is true
Type II Errors • A Type II error is defined as retaining H0 when H0 is false (and H1 is true) • In a Type II error, the sample mean is so close to the m described by H0that we conclude that the predicted relationship does not exist when it really does • The probability of a Type II error is b
Power • The goal of research is to reject H0 when H0 is false • The probability of rejecting H0 when it is false is called power
Parametric Statistics • Parametric statistics are procedures that require certain assumptions about the characteristics of the populations being represented. Two assumptions are common to all parametric procedures: • The population of dependent scores forms a normal distribution and • The scores are interval or ratio.
Nonparametric Procedures • Nonparametric statistics are inferential procedures that do not require stringent assumptions about the populations being represented.
Robust Procedures Parametric procedures are robust. If the data don’t meet the assumptions of the procedure perfectly, we will have only a negligible amount of error in the inferences we draw.
Predicting a Relationship • A two-tailed test is used when we predict that there is a relationship, but do not predict the direction in which scores will change. • A one-tailed test is used when we predict the direction in which scores will change.
One-Tailed Hypotheses • In a one-tailed test, if it is hypothesized that the independent variable causes an increase in scores, then the null hypothesis is that the population mean is less than or equal to a given value and the alternative hypothesis is that the population mean is greater than the same value. For example: • H0: m ≤ 50 • Ha: m > 50
A Sampling Distribution Showing the Region of Rejection for a One-tailed Test of Whether Scores Increase
One-Tailed Hypotheses • In a one-tailed test, if it is hypothesized that the independent variable causes a decrease in scores, then the null hypothesis is that the population mean is greater than or equal to a given value and the alternative hypothesis is that the population mean is less than the same value. For example: • H0: m ≥ 50 • Ha: m < 50
A Sampling Distribution Showing the Region of Rejection for a One-tailed Test of Whether Scores Decrease
Choosing One-Tailed Versus Two-Tailed Tests Use a one-tailed test only when confident of the direction in which the dependent variable scores will change. When in doubt, use a two-tailed test.
The z-Test The z-test is the procedure for computing a z-score for a sample mean on the sampling distribution of means.
We know the true standard deviation of the population described by the null hypothesis Assumptions of the z-Test • We have randomly selected one sample • The dependent variable is at least approximately normally distributed in the population and involves an interval or ratio scale • We know the mean of the population of raw scores under some other condition of the independent variable
Setting up for a Two-Tailed Test • Choose alpha. Common values are 0.05 and 0.01. • Locate the region of rejection. For a two-tailed test, this will involve defining an area in both tails of the sampling distribution. • Determine the critical value. Using the chosen alpha, find the zcrit value that gives the appropriate region of rejection.
A Sampling Distribution for H0 Showing the Region of Rejection for a = 0.05 in a Two-tailed Test
Two-Tailed Hypotheses • In a two-tailed test, the null hypothesis states that the population mean equals a given value. For example, H0: m = 100. • In a two-tailed test, the alternative hypothesis states that the population mean does not equal the same given value as in the null hypothesis. For example, Ha: m 100.
The z-score is computed using the same formula as before • where Computing z
Rejecting H0 • When the zobt falls beyond the critical value, the statistic lies in the region of rejection, so we reject H0 and accept Ha • When we reject H0 and accept Ha we say the results are significant. Significant indicates that the results are too unlikely to occur if the predicted relationship does not exist in the population.
Interpreting Significant Results • When we reject H0 and accept Ha, we do not prove that H0 is false • While it is unlikely for a mean that lies within the rejection region to occur, the sampling distribution shows that such means do occur once in a while
Failing to Reject H0 • When the zobt does not fall beyond the critical value, the statistic does not lie within the region of rejection, so we do not reject H0 • When we fail to reject H0 we say the results are nonsignificant. Nonsignificant indicates that the results are likely to occur if the predicted relationship does not exist in the population.
Interpreting Nonsignificant Results • When we fail to reject H0, we do not prove that H0 is true • Nonsignificant results provide no convincing evidence—one way or the other—as to whether a relationship exists in nature
Compute and compute zobt Summary of the z-Test • Determine the experimental hypotheses and create the statistical hypothesis • Set up the sampling distribution • Compare zobt to zcrit
