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46-320-01 Tests and Measurements Intersession 2006
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More Correlation Spearman’s rho: two sets of ranks Biserial correlation: continuous and artificial dichotmous variable Point biserial correlation: true dichotmous variable
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Hypothesis Testing Review Independent and Dependent variables In Psychology we test hypotheses Null Hypothesis (H 0 ): a statement of relationship between the IV and DV, usually a statement of no difference or no relationship – we assume there is no relationship between IV and DV Alternative/Research Hypothesis (H a ): states a relationship, or effect, of the IV on the DV
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Hypothesis Examples H 0 : Men and women do not differ in IQ ( men = women ) H a : Men and women do differ in IQ ( men women ) Any difference in value of the DV between the levels of the IV can be explained in 2 ways – the effect of the IV or sampling error
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Hypothesis Testing with Correlations Null Hypothesis: there is no significant relationship between X and Y Alternative Hypothesis: there is a significant relationship between X and Y (r is significantly different from 0) We can use Appendix 3 (p. 641) df = N – 2 r obs =.832 r crit =.195 Reject H o
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Regression We know the degree to which 2 variables are related - correlation How do we predict the score on Y if we know X? Regression line Principle of least squares
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Equation Explained Y’: predicted value of Y b: regression coefficient = slope Describes how much change is expected in Y with one unit increase in X a: intercept = value of Y when X is 0
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Line of Best Fit Actual (Y) and predicted (Y’) scores are almost never the same Residual Deviations from Y’ at a minimum Prediction Interpreting plot
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More Correlation Standard error of estimate Coefficient of determination Coefficient of alienation Shrinkage Cross validation Correlation does not equal causation! Third variable
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Multivariate Analysis 3 or more variables Many predictors, one outcome Linear Regression: linear combination of variables Weights Raw regression coefficients Standardized regression coefficients Predictive power
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More Multivariate Discriminant Analysis Prediction of nominal category Multiple discriminant analysis Factor Analysis No criterion Interrelation Data reduction Principal components Factor loadings Rotation
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Reliability Assess sources of error Complex traits Relatively free from error = reliable Spearman, Thorndike 1904 Coefficients Kuder and Richardson 1934 Cronbach 1972 on IRT True Score
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Reliability Error and True Score X = T + E Random Error produces a distribution Mean is the estimated true score
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Reliability True score should not change with repeated administrations Standard error of measurement Larger = less reliable Use to create confidence intervals
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Reliability Domain Sampling Model Shorter test estimate, but sample = error Reliability: Usually expressed as a correlation Reliability: Sampling distribution, correlations b/w all scores, average correlation
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Reliability Reliability: Percentage of observed variation attributable to variation in the true score r =.30: 70% of variance in scores due to random factors
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Sources of Error Why are observed scores different from true scores? Situational factors Unrepresentative q’s What else?
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Test-Retest Reliability Error of repeated administration Correlation b/w 2 times Consider: Carryover effects Time interval Changing characteristics
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Parallel Forms Reliability 2 forms that measure the same thing Correlation between two forms Counterbalanced order Consider time interval Example: WRAT-3
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Internal Consistency Split-Half reliability Divide and correlate (internal consistency) Check method of dividing Why use Spearman-Brown formula? Each test ½ length – decreases reliability Cronbach’s alpha – unequal variances
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Internal Consistency Intercorrelations among items within same test Extent to which items measure same ability/trait Low? Several characteristics? Use KR 20, coefficient alpha Considers all ways of splitting data
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Difference Scores Same trait: reliability = 0 Use z-score transformations Generally low
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Observer Differences Estimate reliability of observers Interrater Reliability Percentage Agreement Kappa Corrects for chance agreement 1 (perfect agreement) to –1 (less than chance alone) Interpreting: >.75 = “excellent”.40 to.75 = “fair to good” <.40 = “poor”
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Interpreting Reliability General rule of thumb: Above 0.70 to 0.80 – good Higher the stakes, higher the r Use confidence intervals (from standard error of estimate)
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Low Reliability Increase items Spearman-Brown prophecy formula Factor item analysis Omit items that do not load onto one factor Drop items Correct for Attenuation (low correlations)
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Validity Agreement b/w a test score and what it is intended to measure Face validity: Looks like it’s valid Content-validity Representative/fair sample of items Construct underrepresentation Construct-irrelevant variance
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Criterion-Related Validity How well a test corresponds with a criterion Predictive validity Concurrent validity Validity Coefficient Coefficient of determination
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Evaluating Validity Coefficients Changes in cause of relationship Meaning of criterion Validity population Sample size Criterion vs predictor Restricted range Validity generalization Differential prediction
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Construct-Related Validity Define a construct and develop its measure Main type of validity needed Convergent evidence Correlates with other measures of construct Meaning from associated variables Discriminant evidence Low correlations with unrelated constructs Criterion-referenced tests
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