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Applied Econometrics Instrumental Variable Approach

Applied Econometrics Instrumental Variable Approach. Nguyen Ngoc Anh Nguyen Ha Trang. DEPOCEN. Topics That Will Be Covered in this Workshop. Why use IV? Discussion of endogeneity bias Statistical motivation for IV What is an IV? Identification issues

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Applied Econometrics Instrumental Variable Approach

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  1. Applied EconometricsInstrumental Variable Approach Nguyen Ngoc Anh Nguyen Ha Trang DEPOCEN

  2. Topics That Will Be Covered in this Workshop • Why use IV? • Discussion of endogeneity bias • Statistical motivation for IV • What is an IV? • Identification issues • Statistical properties of IV estimators • How is an IV model estimated? • Software and data examples • Diagnostics: IV relevance, IV exogeneity, Hausman

  3. Review of the Linear Model (in metrix algebra) • Population model: Y = α + βX + ε • Assume that the true slope is positive, so β > 0 • Sample model: Y = a + bX + e • Least squares (LS) estimator of β: bLS= (X′X)–1X′Y = Cov(X,Y) / Var(X) • Under what conditions can we speak of bLS as a causal estimate of the effect of X on Y?

  4. Review of the Linear Model • Key assumption of the linear model: • E(|x) = E( ) = 0  Cov(x, ) = E(x ) = 0 • E(X′e) = Cov(X,e) = E(e | X) = 0 • Exogeneity assumption = X is uncorrelated with the unobserved determinants of Y • Important statistical property of the LS estimator under exogeneity: E(bLS) =β + Cov(X,e) / Var(X) plim(bLS) =β + Cov(X,e) / Var(X) Second terms 0, so bLS unbiased and consistent

  5. Review of the Linear Model When you regress Y on X, Y = β0 + β1X + ε and the OLS estimate of β1 can be described as But since X and εare correlated, bOLS does not estimateβ1 but some other quantity that depends on the correlation of X and ε

  6. Endogeneity and the Evaluation Problem • When is the exogeneity assumption violated? • Measurement error → Attenuation bias • Instantaneous causation → Simultaneity bias • Omitted variables → Selection bias • Selection bias is the problem in observational research that undermines causal inference • Measurement error and instantaneous causation can be posed as problems of omitted variables • Potential outcome approach!!!!

  7. X Y W When Is the Exogeneity Assumption Violated? Omitted variable (W) that is correlated with both X and Y • Classic problem of omitted variables bias • Coefficient on X will absorb the indirect path through W, whose sign depends on Cov(X,W) and Cov(W,Y) Things more complicated in applied settings because there are bound to be many W’s, not to mention that the “smearing” problem applies in this context also

  8. Example #1: Police Hiring • Measurement error • Mobilization of sworn officers (M.E. in X) as well as differential victim reporting or crime recording (M.E. in Y) may be correlated with police size • Instantaneous causation • More police might be hired during a crime wave • Omitted variables • Large departments may differ in fundamental ways difficult to measure (e.g., urban, heterogeneous)

  9. Example #2: Delinquent Peers • Measurement error • Highly delinquent youth probably overestimate the delinquency of their peers (M.E. in X), and likely underestimate their own delinquency (M.E. in Y) • Instantaneous causation • If there is influence/imitation, then it is bidirectional • Omitted variables • High-risk youth probably select themselves into delinquent peer groups (“birds of a feather”)

  10. Regression EstimationIgnoring Omitted Variables • Suppose we estimate treatment effect model: Y = α + βX + ε • Let’s assume without loss of generality that X is a binary “treatment” (= 1 if treated; = 0 if untreated) • Least squares estimator: bLS = Cov(X,Y) / Var(X) = E(Y | X = 1) – E(Y | X = 0) • Simply the difference in means between “treated” units (X = 1) and “untreated” units (X = 0)

  11. Estimating Treatment Effects Consider treatment assignment (dummy variable) X and outcome Y Regress Y on X Yi = β0 + β1Xi + εi The estimate of β1 is just the difference between the mean Y for X = 1 (the treatment group) and the mean Y for X = 0 (the control group) Thus the OLS estimate is = β1 +

  12. Estimating Treatment Effects(With Random Assignment) If the treatment is randomly assigned, then X is uncorrelated with ε(X is exogenous) If X is uncorrelated with εif and only if But if , then the mean difference is = β1 + = β1 This implies that standard methods (OLS) give an unbiased estimate of β1, which is the average treatment effect That is, the treatment-control mean difference is an unbiased estimate of β1,

  13. What goes wrong without randomization? If we do not have randomization, there is no guarantee that X is uncorrelated with ε(X may be endogenous) Thus the OLS estimate is still = β1 + If X is correlated with ε, then Hence does not estimate β1, but some other quantity that depends on the correlation of X and ε If X is correlated with ε, then standard methods give a biased estimate of β1

  14. Omitted Variables in applied research • What variables of interest to us are surely endogenous? • Micro = Employment, education, marriage, military service, fertility, conviction, family structure,.... • Macro = Poverty, unemployment rate, collective efficacy, immigrant concentration,.... • Basically, EVERYTHING! • (I’m sorry ....... But it suck)

  15. Potential outcome framework

  16. Traditional Strategies to Deal with Omitted Variables • Randomization (physical control) • Covariate adjustment (statistical control) • Control for potential W’s in a regression model • But...we have no idea how many W’s there are, so model misspecification is still a real problem here

  17. Quasi-Experimental Strategies to Deal with Omitted Variables • Difference in differences (fixed-effects model) • Requires panel data • Propensity score matching • Requires a lot of measured background variables • Similar to covariate adjustment, but only the treated and untreated cases which are “on support” are utilized • Instrumental variables estimation • Requires an exclusion restriction

  18. Z e X Y W Instrumental Variables Estimation Is a Viable Approach • An “instrumental variable” for X is one solution to the problem of omitted variables bias • Requirements for Z to be a valid instrument for X • Relevant = Correlated with X • Exogenous = Not correlated with Y but through its correlation with X

  19. Important Point about Instrumental Variables Models • I often hear...“A good instrument should not be correlated with the dependent variable” • WRONG!!! • Z has to be correlated with Y, otherwise it is useless as an instrument • It can only be correlated with Y through X • (trong X có 2 phần, 1 phần dính với e một phần với Y, muốn tận dụng phần dính với Y) • A good instrument must not be correlated with the unobserved determinants of Y

  20. X Y Z Important Point about Instrumental Variables Models • Not all of the available variation in X is used • Only that portion of X which is “explained” by Z is used to explain Y X = Endogenous variable Y = Response variable Z = Instrumental variable

  21. X Y Z X Y Z Important Point about Instrumental Variables Models Best-case scenario: A lot of X is explained by Z, and most of the overlap between X and Y is accounted for Realistic scenario: Very little of X is explained by Z, or what is explained does not overlap much with Y

  22. Important Point about Instrumental Variables Models • The IV estimator is BIASED • In other words, E(bIV) ≠β (finite-sample bias) • The appeal of IV derives from its consistency • “Consistency” is a way of saying that E(b) → β as N → ∞ • So…IV studies often have very large samples • But with endogeneity, E(bLS) ≠β and plim(bLS) ≠β anyway • Asymptotic behavior of IV plim(bIV) =β + Cov(Z,e) / Cov(Z,X) • If Z is truly exogenous, then Cov(Z,e) = 0

  23. Instrumental Variables Terminology • Three different models to be familiar with • First stage: X = α0 + α1Z + ω • Structural model: Y = β0 + β1X + ε • Reduced form: Y = δ0 + δ1Z + ξ

  24. More on the Method of Two-Stage Least Squares (2SLS) • Step 1: X = a0 + a1Z1 + a2Z2 +  + akZk + u • Obtain fitted values (X̃) from the first-stage model • Step 2: Y = b0 + b1X̃ + e • Substitute the fitted X̃ in place of the original X • Note: If done manually in two stages, the standard errors are based on the wrong residual e = Y – b0 – b1X̃ when it should be e = Y – b0 – b1X • Best to just let the software do it for you

  25. Some examples

  26. Some examples

  27. Including Control Variables in an IV/2SLS Model • Control variables (W’s) should be entered into the model at both stages • First stage: X = a0 + a1Z + a2W + u • Second stage: Y = b0 + b1X̃ + b2W + e • Control variables are considered “instruments,” they are just not “excluded instruments” • They serve as their own instrument

  28. Functional Form Considerations with IV/2SLS • Binary endogenous regressor (X) • Consistency of second-stage estimates do not hinge on getting first-stage functional form correct • Binary response variable (Y) • IV probit (or logit) is feasible but is technically unnecessary • In both cases, linear model is tractable, easily interpreted, and consistent • Although variance adjustment is well advised

  29. Technical Conditions Required for Model Identification • Order condition = At least the same # of IV’s as endogenous X’s • Just-identified model: # IV’s = # X’s • Overidentified model: # IV’s > # X’s • Rank condition = At least one IV must be significant in the first-stage model • Number of linearly independent columns in a matrix • E(X | Z,W) cannot be perfectly correlated with E(X | W)

  30. Instrumental Variables and Randomized Experiments • Imperfect compliance in randomized trials • Some individuals assigned to treatment group will not receive Tx, and some assigned to control group will receive Tx • Assignment error; subject refusal; investigator discretion • Some individuals who receive Tx will not change their behavior, and some who do not receive Tx will change their behavior • A problem in randomized job training studies and other social experiments (e.g., housing vouchers)

  31. Durbin-Wu-Hausman (DWH) Test • Balances the consistency of IV against the efficiency of LS • H0: IV and LS both consistent, but LS is efficient • H1: Only IV is consistent • DWH test for a single endogenous regressor: DWH = (bIV – bLS) / √(s2bIV – s2bLS) ~ N(0,1) • If |DWH| > 1.96, then X is endogenous and IV is the preferred estimator despite its inefficiency

  32. Durbin-Wu-Hausman (DWH) Test • A roughly equivalent procedure for DWH: 1. Estimate the first-stage model 2. Include the first-stage residual in the structural model along with the endogenous X 3. Test for significance of the coefficient on residual • Note: Coefficient on endogenous X in this model is bIV (standard error is smaller, though) • First-stage residual is a “generated regressor”

  33. Software Considerations • Basic model specification in Stata ivreg y (x = z) w [weight = wtvar], options y = dependent variable x = endogenous variable z = instrumental variable w = control variable(s)

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