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Other Regression Models

Explore regression models with categorical predictors and learn how to handle non-linear relationships using curvilinear regression. Includes examples and transformation techniques.

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Other Regression Models

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  1. Other Regression Models Andy Wang CIS 5930 Computer Systems Performance Analysis

  2. Regression WithCategorical Predictors • Regression methods discussed so far assume numerical variables • What if some of your variables are categorical in nature? • If all are categorical, use techniques discussed later in the course • Levels - number of values a category can take

  3. HandlingCategorical Predictors • If only two levels, define bi as follows • bi = 0 for first value • bi = 1 for second value • This definition is missing from book in section 15.2 • Can use +1 and -1 as values, instead • Need k-1 predictor variables for k levels • To avoid implying order in categories

  4. Categorical Variables Example • Which is a better predictor of a high rating in the movie database, • winning an Oscar, • winning the Golden Palm at Cannes, or • winning the New York Critics Circle?

  5. Choosing Variables • Categories are not mutually exclusive • x1= 1 if Oscar 0 if otherwise • x2= 1 if Golden Palm 0 if otherwise • x3= 1 if Critics Circle Award 0 if otherwise • y = b0+b1 x1+b2 x2+b3 x3

  6. A Few Data Points Title Rating Oscar Palm NYC Gentleman’s Agreement 7.5 X X Mutiny on the Bounty 7.6 X Marty 7.4 X X X If 7.8 X La Dolce Vita 8.1 X Kagemusha 8.2 X The Defiant Ones 7.5 X Reds 6.6 X High Noon 8.1 X

  7. And Regression Says . . . • How good is that? • R2 is 34% of variation • Better than age and length • But still no great shakes • Are regression parameters significant at 90% level?

  8. Other Considerations • If categories are mutually exclusive, we can use the following • X1 = 1, X2 = 0 to represent category 1 • X1 = 0, X2 = 1 to represent category 2 • X1 = 0, X2 = 0 to represent category 3

  9. Other Considerations • Not okay to do the following • X1 = 1 for category 1 • X1 = 2 for category 2 • X1 = 3 for category 3 • Remember y = b0 + b1X1 • If b1X1 = 3, it can mean b1 = 3, X1 = 1; b1 = 1.5, X1 = 2; or b1 = 1, X1 = 3

  10. Curvilinear Regression • Linear regression assumes a linear relationship between predictor and response • What if it isn’t linear? • You need to fit some other type of function to the relationship

  11. When To UseCurvilinear Regression • Easiest to tell by sight • Make a scatter plot • If plot looks non-linear, try curvilinear regression • Or if non-linear relationship is suspected for other reasons • Relationship should be convertible to a linear form

  12. Types ofCurvilinear Regression • Many possible types, based on a variety of relationships: • Many others

  13. Transform Themto Linear Forms • Apply logarithms, multiplication, division, whatever to produce something in linear form • I.e., y = a + b*something • Or a similar form

  14. Sample Transformations • For y = aebx, take logarithm of y • ln(y) = ln(a) + bx • y’ = ln(y), b0 = ln(a), b1 = b • Do regression on y’ = b0+b1x • For y = a+b ln(x), • t(x) = ex • Do regression on y = a + bln(t(x))

  15. Sample Transformations • For y = axb, take log of both x and y • ln(y) = ln(a) + bln(x) • y’ = ln(y), b0 = ln(a), b1 = b, t(x) = ex • Do regression on y’ = b0 + b1ln(t(x))

  16. Corrections to Jain p. 257

  17. Transform Themto Linear Forms • If predictor appears in more than one transformed predictor variable, correlation likely! • For y = a + b(x_1 . x_2 + x_2)take log of both x and y • ln(y) = ln(a) + x_1 x_2 ln(b) + x_2 ln(b)

  18. General Transformations • Use some function of response variable y in place of y itself • Curvilinear regression is one example • But techniques are more generally applicable

  19. When To Transform? • If known properties of measured system suggest it • If data’s range covers several orders of magnitude • If homogeneous variance assumption of residuals (homoscedasticity) is violated

  20. Transforming Due To Homoscedasticity • If spread of scatter plot of residual vs. predicted response isn’t homogeneous, • Then residuals are still functions of the predictor variables • Transformation of response may solve the problem

  21. What TransformationTo Use? • Compute standard deviation of residuals at each y_hat • Assume multiple residuals at each predicted value • Plot as function of mean of observations • Assuming multiple experiments for single set of predictor values • Check for linearity: if linear, use a log transform

  22. Other Tests for Transformations • If variance against mean of observations is linear, use square-root transform • If standard deviation against mean squared is linear, use inverse (1/y) transform • If standard deviation against mean to a power is linear, use power transform • More covered in the book

  23. General Transformation Principle For some observed relation between standard deviation and mean, let transform to and regress on w

  24. Example: Log Transformation • If standard deviation against mean is linear, then So

  25. Confidence Intervalsfor Nonlinear Regressions • For nonlinear fits using general (e.g., exponential) transformations: • Confidence intervals apply to transformed parameters • Not valid to perform inverse transformation on intervals (which assume normality) • Must express confidence intervals in transformed domain

  26. Outliers • Atypical observations might be outliers • Measurements that are not truly characteristic • By chance, several standard deviations out • Or mistakes might have been made in measurement • Which leads to a problem: Do you include outliers in analysis or not?

  27. DecidingHow To Handle Outliers 1. Find them (by looking at scatter plot) 2. Check carefully for experimental error 3. Repeat experiments at predictor values for each outlier 4. Decide whether to include or omit outliers • Or do analysis both ways Question: Is first point in last lecture’s example an outlier on rating vs. age plot?

  28. Rating vs. Age

  29. Common Mistakesin Regression • Generally based on taking shortcuts • Or not being careful • Or not understanding some fundamental principle of statistics

  30. Not Verifying Linearity • Draw the scatter plot • If it’s not linear, check for curvilinear possibilities • Misleading to use linear regression when relationship isn’t linear

  31. Relying on ResultsWithout Visual Verification • Always check scatter plot as part of regression • Examine predicted line vs. actual points • Particularly important if regression is done automatically

  32. Some Nonlinear Examples

  33. Attaching ImportanceTo Values of Parameters • Numerical values of regression parameters depend on scale of predictor variables • So just because a parameter’s value seems “large,” not an indication of importance • E.g., converting seconds to microseconds doesn’t change anything fundamental • But magnitude of associated parameter changes

  34. Not SpecifyingConfidence Intervals • Samples of observations are random • Thus, regression yields parameters with random properties • Without confidence interval, impossible to understand what a parameter really means

  35. Not Calculating Coefficient of Determination • Without R2, difficult to determine how much of variance is explained by the regression • Even if R2 looks good, safest to also perform an F-test • Not that much extra effort

  36. Using Coefficient of Correlation Improperly • Coefficient of determination is R2 • Coefficient of correlation is R • R2 gives percentage of variance explained by regression, not R • E.g., if R is .5, R2 is .25 • And regression explains 25% of variance • Not 50%!

  37. Using Highly Correlated Predictor Variables • If two predictor variables are highly correlated, using both degrades regression • E.g., likely to be correlation between an executable’s on-disk and in-core sizes • So don’t use both as predictors of run time • Means you need to understand your predictor variables as well as possible

  38. Using Regression Beyond Range of Observations • Regression is based on observed behavior in a particular sample • Most likely to predict accurately within range of that sample • Far outside the range, who knows? • E.g., regression on run time of executables < memory size may not predict performance of executables > memory size

  39. Using Too ManyPredictor Variables • Adding more predictors does not necessarily improve model! • More likely to run into multicollinearity problems • So what variables to choose? • Subject of much of this course

  40. Measuring Too Littleof the Range • Regression only predicts well near range of observations • If you don’t measure commonly used range, regression won’t predict much • E.g., if many programs are bigger than main memory, only measuring those that are smaller is a mistake

  41. Assuming Good PredictorIs a Good Controller • Correlation isn’t necessarily control • Just because variable A is related to variable B, you may not be able to control values of B by varying A • E.g., if number of hits on a Web page correlated to server bandwidth, but might not boost hits by increasing bandwidth • Often, a goal of regression is finding control variables

  42. White Slide

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