CFA-SEM
Chapter 4
Multiple Regression Analysis
LEARNING OBJECTIVES
Upon completing this chapter, you should be able to do the following:
Determine when regression analysis is the appropriate statistical tool in analyzing a problem.
Understand how regression helps us make predictions using the least squares concept.
Use dummy variables with an understanding of their interpretation.
Be aware of the assumptions underlying regression analysis and how to assess them.
Chapter 4
Multiple Regression Analysis
LEARNING OBJECTIVES continued . . .
Upon completing this chapter, you should be able to do the following:
Select an estimation technique and explain the difference between stepwise and simultaneous regression.
Interpret the results of regression.
Apply the diagnostic procedures necessary to assess “influential”
observations.
Chapter 4
Multiple Regression Analysis
Multiple regression analysis . . . is a statistical technique that can be used to analyze the relationship between a single dependent (criterion) variable and several independent (predictor) variables.
Multiple Regression Defined
Multiple Regression
Y’ = b0 + b1X1 + b2X2 + . . . + bnXn + e
Y = Dependent Variable = # of credit cards
b0 = intercept (constant) = constant number of credit cards independent of family size and income.
b1 = change in # of credit cards associated with a unit
change in family size (regression coefficient).
b2 = change in # of credit cards associated with a unit change in income (regression coefficient).
X1 = family size
X2 = income
e = prediction error (residual)
Variate (Y’) = X1b1 + X2b2 + . . . + Xnbn
A variate value (Y’) is calculated for each respondent.
The Y’ value is a linear combination of the entire set of variables that best achieves the statistical objective.
Y’
X1
X2
X3
Multiple Regression Decision Process
Stage 1: Objectives of Multiple Regression
Stage 2: Research Design of Multiple Regression
Stage 3: Assumptions in Multiple Regression Analysis
Stage 4: Estimating the Regression Model and Assessing Overall Fit
Stage 5: Interpreting the Regression Variate
Stage 6: Validation of the Results
Stage 1: Objectives of Multiple Regression
In selecting suitable applications of multiple regression, the researcher must consider three primary issues:
the appropriateness of the research problem,
specification of a statistical relationship, and
selection of the dependent and independent variables.
Selection of Dependent and Independent Variables
The researcher should always consider three issues that can affect any decision about variables:
The theory that supports using the variables,
Measurement error, especially in the dependent variable, and
Specification error.
Measurement Error in Regression
Measurement error that is problematic can be addressed through either of two approaches:
Summated scales, or
Structural equation modeling procedures.
Rules of Thumb 4–1
Meeting Multiple Regression Objectives
Only structural equation modeling (SEM) can directly accommodate measurement error, but using summated scales can mitigate it when using multiple regression.
When in doubt, include potentially irrelevant variables (as they can only confuse interpretation) rather than possibly omitting a relevant variable (which can bias all regression estimates).
Stage 2: Research Design of a Multiple Regression Analysis
Issues to consider . . .
Sample size,
Unique elements of the dependence relationship – can use dummy variables as independents, and
Nature of independent variables – can be both fixed and random.
Rules of Thumb 4–2
Sample Size Considerations
Simple regression can be effective with a sample size of 20, but maintaining power at .80 in multiple regression requires a minimum sample of 50 and preferably 100 observations for most research situations.
The minimum ratio of observations to variables is 5 to 1, but the preferred ratio is 15 or 20 to 1, and this should increase when stepwise estimation is used.
Maximizing the degrees of freedom improves generalizability and addresses both model parsimony and sample size concerns.
Rules of Thumb 4–3
Variable Transformations
Nonmetric variables can only be included in a regression analysis by creating dummy variables.
Dummy variables can only be interpreted in relation to their reference category.
Adding an additional polynomial term represents another inflection point in the curvilinear relationship.
Quadratic and cubic polynomials are generally sufficient to represent most curvilinear relationships.
Assessing the significance of a polynomial or interaction term is accomplished by evaluating incremental R2, not the significance of individual coefficients, due to high multicollinearity.
Stage 3: Assumptions in Multiple Regression Analysis
Linearity of the phenomenon measured.
Constant variance of the error terms.
Independence of the error terms.
Normality of the error term distribution.
Rules of Thumb 4–4
Assessing Statistical Assumptions
Testing assumptions must be done not only for each dependent and independent variable, but for the variate as well.
Graphical analyses (i.e., partial regression plots, residual plots and normal probability plots) are the most widely used methods of assessing assumptions for the variate.
Remedies for problems found in the variate must be accomplished by modifying one or more independent variables as described in Chapter 2.
Stage 4: Estimating the Regression Model and Assessing Overall Model Fit
In Stage 4, the researcher must accomplish three basic tasks:
Select a method for specifying the regression model to be estimated,
Assess the statistical significance of the overall model in predicting the dependent variable, and
Determine whether any of the observations exert an undue influence on the results.
Variable Selection Approaches
Confirmatory (Simultaneous)
Sequential Search Methods:
Stepwise (variables not removed once included in regression equation).
Forward Inclusion & Backward Elimination.
Hierarchical.
Combinatorial (All-Possible-Subsets)
Variable Description Variable Type
Data Warehouse Classification Variables
X1 Customer Type nonmetric
X2 Industry Type nonmetric
X3 Firm Size nonmetric
X4 Region nonmetric
X5 Distribution System nonmetric
Performance Perceptions Variables
X6 Product Quality metric
X7 E-Commerce Activities/Website metric
X8 Technical Support metric
X9 Complaint Resolution metric
X10 Advertising metric
X11 Product Line metric
X12 Salesforce Image metric
X13 Competitive Pricing metric
X14 Warranty & Claims metric
X15 New Products metric
X16 Ordering & Billing metric
X17 Price Flexibility metric
X18 Delivery Speed metric
Outcome/Relationship Measures
X19 Satisfaction metric
X20 Likelihood of Recommendation metric
X21 Likelihood of Future Purchase metric
X22 Current Purchase/Usage Level metric
X23 Consider Strategic Alliance/Partnership in Future nonmetric
Description of HBAT Primary Database Variables
Regression Analysis Terms
Explained variance = R2 (coefficient of determination).
Unexplained variance = residuals (error).
Adjusted R-Square = reduces the R2 by taking into account the sample size and the number of independent variables in the regression model (It becomes smaller as we have fewer observations per independent variable).
Standard Error of the Estimate (SEE) = a measure of the accuracy of the regression predictions. It estimates the variation of the dependent variable values around the regression line. It should get smaller as we add more independent variables, if they predict well.
Regression Analysis Terms Continued . . .
Total Sum of Squares (SST) = total amount of variation that exists to be explained by the independent variables. TSS = the sum of SSE and SSR.
Sum of Squared Errors (SSE) = the variance in the dependent variable not accounted for by the regression model = residual. The objective is to obtain the smallest possible sum of squared errors as a measure of prediction accuracy.
Sum of Squares Regression (SSR) = the amount of improvement in explanation of the dependent variable attributable to the independent variables.
Least Squares Regression Line
X
Y
Y = average
Total Deviation
Deviation not explained by regression
Deviation explained by regression
Statistical vs. Practical Significance?
The F statistic is used to determine if the overall regression model is statistically significant. If the F statistic is significant, it means it is unlikely your sample will produce a large R2 when the population R2 is actually zero. To be considered statistically significant, a rule of thumb is there must be <.05 probability the results are due to chance.
If the R2 is statistically significant, we then evaluate the strength of the linear association between the dependent variable and the several independent variables. R2, also called the coefficient of determination, is used to measure the strength of the overall relationship. It represents the amount of variation in the dependent variable associated with all of the independent variables considered together (it also is referred to as a measure of the goodness of fit). R2 ranges from 0 to 1.0 and represents the amount of the dependent variable “explained” by the independent variables combined. A large R2 indicates the straight line works well while a small R2 indicates it does not work well.
Even though an R2 is statistically significant, it does not mean it is practically significant. We also must ask whether the results are meaningful. For example, is the value of knowing you have explained 4 percent of the variation worth the cost of collecting and analyzing the data?
Rules of Thumb 4–5
Estimation Techniques
No matter which estimation technique is chosen, theory must be a guiding factor in evaluating the final regression model because:
Confirmatory Specification, the only method to allow direct testing of a pre-specified model, is also the most complex from the perspectives of specification error, model parsimony and achieving maximum predictive accuracy.
Sequential search (e.g., stepwise), while maximizing predictive accuracy, represents a completely “automated” approach to model estimation, leaving the researcher almost no control over the final model specification.
Combinatorial estimation, while considering all possible models, still removes control from the researcher in terms of final model specification even though the researcher can view the set of roughly equivalent models in terms of predictive accuracy.
No single method is “Best” and the prudent strategy is to use a combination of approaches to capitalize on the strengths of each to reflect the theoretical basis of the research question.
Regression Coefficient Questions
Three questions about the statistical significance of any regression coefficient:
Was statistical significance established?
How does the sample size come into play?
Does it have practical significance in addition to statistical significance?
Rules of Thumb 4–6
Statistical Significance and Influential Observations
Always ensure practical significance when using large sample sizes, as the model results and regression coefficients could be deemed irrelevant even when statistically significant due just to the statistical power arising from large sample sizes.
Use the adjusted R2 as your measure of overall model predictive accuracy.
Statistical significance is required for a relationship to have validity, but statistical significance without theoretical support does not support validity.
While outliers may be easily identifiable, the other forms of influential observations requiring more specialized diagnostic methods can be equal to or even more impactful on the results.
Types of Influential Observations
Influential observations . . . include all observations that have a disproportionate effect on the regression results. There are three basic types based upon the nature of their impact on the regression results:
Outliers are observations that have large residual values and can be identified only with respect to a specific regression model.
Leverage points are observations that are distinct from the remaining observations based on their independent variable values.
Influential observations are the broadest category, including all observations that have a disproportionate effect on the regression results. Influential observations potentially include outliers and leverage points but may include other observations as well.
Corrective Actions for Influentials
Influentials, outliers, and leverage points are based on one of four conditions, each of which has a specific course of corrective action:
An error in observations or data entry – remedy by correcting the data or deleting the case,
A valid but exceptional observation that is explainable by an extraordinary situation – remedy by deletion of the case unless variables reflecting the extraordinary situation are included in the regression equation,
An exceptional observation with no likely explanation – presents a special problem because there is no reason for deleting the case, but its inclusion cannot be justified either, suggesting analyses with and without the observations to make a complete assessment, and
An ordinary observation in its individual characteristics but exceptional in its combination of characteristics – indicates modifications to the conceptual basis of the regression model and should be retained.
Assessing Multicollinearity
The researcher’s task is to . . .
Assess the degree of multicollinearity,
Determine its impact on the results, and
Apply the necessary remedies if needed.
Multicollinearity Diagnostics
Variance Inflation Factor (VIF) – measures how much the variance of the regression coefficients is inflated by multicollinearity problems. If VIF equals 0, there is no correlation between the independent measures. A VIF measure of 1 is an indication of some association between predictor variables, but generally not enough to cause problems. A maximum acceptable VIF value would be 10; anything higher would indicate a problem with multicollinearity.
Tolerance – the amount of variance in an independent variable that is not explained by the other independent variables. If the other variables explain a lot of the variance of a particular independent variable we have a problem with multicollinearity. Thus, small values for tolerance indicate problems of multicollinearity. The minimum cutoff value for tolerance is typically .10. That is, the tolerance value must be smaller than .10 to indicate a problem of multicollinearity.
Interpretation of Regression Results
Coefficient of Determination
Regression Coefficients (Unstandardized – bivariate)
Beta Coefficients (Standardized)
Variables Entered
Multicollinearity ??
Rules of Thumb 4–7
Interpreting the Regression Variate
Interpret the impact of each independent variable relative to the other variables in the model, as model respecification can have a profound effect on the remaining variables:
Use beta weights when comparing relative importance among independent variables.
Regression coefficients describe changes in the dependent variable, but can be difficult in comparing across independent variables if the response formats vary.
Multicollinearity may be considered “good” when it reveals a suppressor effect, but generally it is viewed as harmful since increases in multicollinearity:
reduce the overall R2 that can be achieved,
confound estimation of the regression coefficients, and
negatively affect the statistical significance tests of coefficients.
Rules of Thumb 4–7 continued . . .
Interpreting the Regression Variate
Generally accepted levels of multicollinearity (tolerance values up to .10, corresponding to a VIF of 10) almost always indicate problems with multicollinearity, but these problems may be seen at much lower levels of collinearity or multicollinearity.
Bivariate correlations of .70 or higher may result in problems, and even lower correlations may be problematic if they are higher than the correlations between the dependent and independent variables.
Values much lower than the suggested thresholds (VIF values of even 3 to 5) may result in interpretation or estimation problems, particularly when the relationships with the dependent variable are weaker.
Residuals Plots
Histogram of standardized residuals – enables you to determine if the errors are normally distributed.
Normal probability plot – enables you to determine if the errors are normally distributed. It compares the observed (sample) standardized residuals against the expected standardized residuals from a normal distribution.
ScatterPlot of residuals – can be used to test regression assumptions. It compares the standardized predicted values of the dependent variable against the standardized residuals from the regression equation. If the plot exhibits a random pattern then this indicates no identifiable violations of the assumptions underlying regression analysis.
Stage 6: Validation of the Results
Additional or Split Samples
Calculating the PRESS Statistic
Comparing Regression Models
Forecasting with the Model
Variable Description Variable Type
Data Warehouse Classification Variables
X1 Customer Type nonmetric
X2 Industry Type nonmetric
X3 Firm Size nonmetric
X4 Region nonmetric
X5 Distribution System nonmetric
Performance Perceptions Variables
X6 Product Quality metric
X7 E-Commerce Activities/Website metric
X8 Technical Support metric
X9 Complaint Resolution metric
X10 Advertising metric
X11 Product Line metric
X12 Salesforce Image metric
X13 Competitive Pricing metric
X14 Warranty & Claims metric
X15 New Products metric
X16 Ordering & Billing metric
X17 Price Flexibility metric
X18 Delivery Speed metric
Outcome/Relationship Measures
X19 Satisfaction metric
X20 Likelihood of Recommendation metric
X21 Likelihood of Future Purchase metric
X22 Current Purchase/Usage Level metric
X23 Consider Strategic Alliance/Partnership in Future nonmetric
Description of HBAT Primary Database Variables
Multiple Regression Learning Checkpoint
When should multiple regression be used?
Why should multiple regression be used?
What level of statistical significance and
R2 would justify use of multiple regression?
How do you use regression coefficients?