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Inference issues in OLS

Inference issues in OLS. Amine Ouazad Ass. Prof. of Economics. Outline. Heteroscedasticity Clustering Generalized Least Squares For heteroscedasticity For autocorrelation. Heteroscedasticity. Issue.

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Inference issues in OLS

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  1. Inference issues in OLS Amine Ouazad Ass. Prof. of Economics

  2. Outline • Heteroscedasticity • Clustering • Generalized Least Squares • For heteroscedasticity • For autocorrelation

  3. Heteroscedasticity

  4. Issue • The issue arises whenever the residual’s variance depends on the observation, or depends on the value of the covariates.

  5. Example #1

  6. Example #2 Here Var(y|x) is clearly increasing in x. Notice the underestimation of the size of the confidence intervals.

  7. Visual checks with multiple variables • Use the vector of estimates b, and predict E(Y|X) using the predict xb, xbstata command. • Draw the scatter plot of the dependent y and the prediction Xb on the horizontal axis.

  8. Causes • Unobservable that affects the variance of the residuals, but not the mean conditional on x. • y=a+bx+e. • with e=hz. The shock h satisfies E(h |x)=0, and E(z|x)=0 but the variance Var(z|x) depends on an unobservable z. • E(e|x)=0 (exogeneity), but Var(e|x)=Var(hz|x) depends on x. (previous example #1). • In practice, most regressions have heteroskedastic residuals.

  9. Examples • Variability of stock returns depends on the industry. • Stock Returni,t = a + b Market Returnt + ei,t. • Variability of unemployment depends on the state/country. • Unemploymenti,t= a + b GDP Growtht + ei,t. • Notice that both the inclusion of industry/state dummies and controlling for heteroskedasticity may be necessary.

  10. Heteroscedasticity: the framework • We set the ws so that their sum is equal to n, and they are all positive. The trace of the matrix W (see matrix appendix) is therefore equal to n.

  11. Consequences • The OLS estimator is still unbiased, consistent and asymptotically normal (only depends on A1-A3). • But the OLS estimator is then inefficient (the proof of the Gauss-Markov theorem relies on homoscedasticity). • And the confidence intervals calculated assuming homoscedasticity typically overestimate the power of the estimates/underestimate the size of the confidence intervals.

  12. Variance-covariance matrixof the estimator • Asymptotically • At finite and fixed sample size • xi is the i-th vector of covariates, a vector of size K. • Notice that if the wi are all equal to 1, we are back to the homoscedastic case and we get Var(b|x) = s2(X’X)-1 • We use the finite sample size formula to design an estimator of the variance-covariance matrix.

  13. White Heteroscedasticity consistent estimator of the variance-covariance matrix • The formula uses the estimated residuals ei of each observation, using the OLS estimator of the coefficients. • This formula is consistent (plim Est. Asy. Var(b)=Var(b)), but may yield excessively large standard errors for small sample sizes. • This is the formula used by the Stata robust option. • From this, the square of the k-th diagonal element is the standard error of the k-th coefficient.

  14. Test for heteroscedasticity • Null hypothesis H0: si2 = s2 for all i=1,2,…,n. • Alternative hypothesis Ha: at least one residual has a different variance. • Steps: • Estimate the OLS and predict the residuals ei. • Regress the square of the residuals on a constant, the covariates, their squares and their cross products (P covariates). • Under the null, all of the coefficients should be equal to 0, and NR2 of the regression is distributed as a c2 with P-1 degrees of freedom.

  15. Suggests another visual check • Examples #1 and #2 with one covariate. • Example with two covariates.

  16. Statatake aways • Always use robust standard errors • robust option available for most regressions. • This is regardless of the use of covariates. Adding a covariate does not free you from the burden of heteroscedasticity. • Test for heteroscedasticity: • hettestreports the chi-squared statistic with P-1 degrees of freedom, and the p-value. • A p-value lower than 0.05 rejects the null at 95%. • The test may be used with small sample sizes, to avoid the use of robust standard errors.

  17. Clustering

  18. Clustering, example #1 • Typical problem with clustering is the existence of a common unobservable component… • Common to all observations in a country, a state, a year, etc. • Take yit = xit + eit, a panel dataset where the residual eit=ui+hit. • Exercise: Calculate the variance-covariance matrix of the residuals.

  19. Clustering, example #2 • Other occurrence of clustering is the use of data at a higher level of aggregation than the individual observation. • Example: yij = xijb+zjg+eij. • This practically implies (but not theoretically), that Cov(eij,ei’j) is nonzero. • Example: • regression performanceit = c + dpolicyj(i) + eit. • regression stock returnit = constant + bMarkett + eit.

  20. Moulton paper

  21. The clustering model • Notice that the variance-covariance matrix can be designed this way by blocks. • In this model, the estimator is unbiased and consistent, but inefficient and the estimated variance-covariance matrix is biased.

  22. True variance-covariance matrix • With all the covariates fixed within group, the variance covariance matrix of the estimator is: • where m=n/p, the number of observations per group. • This formula is not exact when there are individual-specific covariates, but the term (1+(m-1)r) can be used as an approximate correction factor.

  23. Descriptive Statistics

  24. Stata • regress y x, cluster(unit) robust. • Clustering and robust s.e. s should be used at the same time. • This is the OLS estimator with corrected standard errors. • If x includes unit-specific variables, we cannot add a unit (state/firm/industry) dummy as well.

  25. Multi-way clustering • Multi-way clustering: • “Robust inference with multi-way clustering”, Cameron, Gelbach and Miller, Technical NBER Working Paper Number 327 (2006). • Has become the new norm very recently. • Example: clustering by year and state. • yit = xitb+ zig + wtd + eit • What do you expect? • ivreg2 , cluster(id year) . • ssc install ivreg2.

  26. Generalized least squares

  27. OLS is BLUE only under A4 • OLS is not BLUE if the variance-covariance matrix of the residuals is not diagonal. • What should we do? • Take general OLS model Y=Xb+e. • And assume that Var(e)=W. • Then take the square root of the matrix, W-1/2. This is a matrix that satisfiesW=(W-1/2 )’W-1/2. This matrix exists for any positive definite matrix.

  28. Sphericized model • The sphericized model is: W-1/2 Y= W-1/2 Xb+W-1/2e • This model satisfies A4 since Var(e|X)=s2.

  29. Generalized Least Squares • The GLS estimator is: • This estimator is BLUE. It is the efficient estimator of the parameter beta. • This estimator is also consistent and asymptotically normal. • Exercise: prove that the estimator is unbiased, and that the estimator is consistent.

  30. Feasible Generalized Least Squares • The matrix W in general is unknown. We estimate W using a procedure (see later) so that plim W = W. • Then the FGLS estimator b=(X’W-1X)-1X’W-1Y is a consistent estimator of b. • The typical problem is the estimation of W. There is no one size fits all estimation procedure.

  31. GLS for heteroscedastic models • Taking the formula of the GLS estimator, with a diagonal variance-covariance matrix. • Where each weight is the inverse of wi. Or the inverse of si2. Scaling the weights has no impact. • Stata application exercise: • Calculate weights and tse the weighted OLS estimator regress y x [aweight=w] to calculate the heteroscedastic GLS estimator, on a dataset of your choice.

  32. GLS for autocorrelation • Autocorrelation is pervasive in finance. Assume that et=ret-1+ht, (we say that et is AR(1)) where ht is the innovation, uncorrelated with et-1. • The problem is the estimation of r. Then a natural estimator of r is the coefficient of the regression of et on et-1. • Exercise 1 (for adv. students): find the inverse of W. • Exercise 2 (for adv. students): find W for an AR(2) process. • Exercise 3 (for adv. students): what about MA(2) ? • Variation: Panel specific AR(1) structure.

  33. Autocorrelation example

  34. GLS for clustered models • Correlation r within each group. • Exercise: write down the variance-covariance matrix W of the residuals. • Put forward an estimator of r. • What is the GLS estimator of b in Y=Xb+e with clustering? • Estimation using xtgls, re.

  35. Applications of GLS • The Generalized Least Squares model is seldom used. In practice, the variance of the OLS estimator is corrected for heteroscedasticity or clustering. • Take-away: use regress , cluster(.) robust • Otherwise: xtgls, panels(hetero) • xtgls, panels(correlated) • xtgls, panels(hetero) corr(ar1) • The GLS is mostly used for the estimation of random effects models. • xtreg, re

  36. Conclusion: no worries

  37. Take away for this session • Use regress, robust; always, unless the sample size is small. • Use regress, robust cluster(unit) if: • You believe there are common shocks at the unit level. • You have included unit level covariates. • Use ivreg2, cluster(unit1 unit2) for two way clustering. • Use xtgls for the efficient FGLS estimator with correlated, AR(1) or heteroscedastic residuals. • This might allow you to shrink the confidence intervals further, but beware that this is less standard than the previous methods.

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