Microeconometrics {Cameron2005}

Online Resources on Cameron:2005

ECON 615 Final Cheatsheet

Model Specification

Parametric Methods

  • Linear models (OLS, WLS, IV)
  • Maximum likelihood (ML) and nonlinear least-square (NLS) estimation
  • Generalized method of moments

Semiparametric Methods

  • Least absolute deviation (LAD) estimator
    • Maximum score (MS) estimator; (Manski, 1975)
      • Smoothed maximum score estimator; (Horowitz, 1992)
    • Censored LAD estimator; (Powell, 1981, 1983)
  • Symmetrically censored least square (SCLS) estimator; (Powell, 1986)
  • Partially Linear Model
    • Robinson Difference Estimator (Robinson, 1988) (9.7.3) (16.5)
  • Single Index Models (9.7.4)
  • Generalized Additive Models

Nonparametric Methods

  • Kernel Density Estimation
  • Conditional Density Estimation
  • Nonparametric Regression

Models for Cross-Section Data

Discrete Outcome/Choice Models

Binary outcome models

  1. MLEs as latent variable models
    1. Linear probability model
    2. Logit (logistic regression) model
    3. Probit model
  2. Grouped and Aggregated Data: Minimum chi-square estimator

Multinomial outcome models

  1. Unordered outcomes
    1. conditional logit (CL), multinomial logit (MNL)
      • Independence of Irrelevant Alternatives
    2. nested logit (NL)?, three-level nested logit
    3. multinomial probit (MNP)
  2. Ordered outcomes, and sequential decision
    1. ordered logit, ordered probit
  3. Specification test
    1. Likelihood ratio (LR)
    2. Hausman test
    3. Hausman-McFadden test
    4. Small-Hsiao pseudo-likelihood ratio test

Choice-based sampling: weighted MLE

Model selection

  1. AIC (Akaike information criterion)
  2. BIC (Bayesian information criterion)

Sample Selection Models

Sample Selection Models

  1. Tobit model (Censored model)
    • MLE
    • Two-step estimator (Ahn and Powell, 1993)
  2. Bivariate Sample Selection Model (Type 2 Tobit Model)
    • Heckman two-step estimator (Heckman, 1979)
  3. Roy models (Type 5 Tobit Model)

Simultaneous equations models

  • simultaneous equations Tobit model
  • simultaneous equations Probit model
  • coherency condition

Specification analysis

  • Heteroscedasticity, serial correlations, and nonnormality
    • Nelson test, 1981
    • Hausman test

Duration and Count Data Models

Duration Regression Models:

  • Proportional Hazard
  • Left Censoring
  • Markov Chain Models

Count Data Models:

  • Poisson and Negative Binomial Models
  • Simulated Maximum Likelihood (SML)

Models for Panel Data

Short Panels

Static Panel Data Models

Simple Regression Models with Variable Intercepts: (dep = time-inv + time-var + individual + error)

\[ y_it = z_i α + x_it β + u_i + ε_it \]

  • Pooled Model [disregard time periods]
    • Pooled OLS estimator [OLS over panel]
  • Individual-specific Effects Model
    • Random Effects (RE) Model (random intercept model, equicorrelated model, random components model) [individual-specific effect uncorrelated with regressors]
      • Between Estimator [OLS over individual time-averages]
      • Random Effects Estimator
        • [Feasible GLS over panel]
        • MLE
    • Fixed Effects (FE) Model [individual-specific effect correlated with regressors]
      • Within Estimator (Fixed Effects Estimator) (Lease-squares Dummy-variable (LSDV) Estimator) (Covariance Estimator) [OLS over panel after subtracting individual time-averages]
      • First Differences (FD) Estimator [OLS over panel after first-differences in time]
  • Specification Analysis
    • Individual-specific effect

Fixed effects are treated as nuisance parameters, while estimation of marginal effects are of sole interest.

Dynamic Panel Data Models

Dynamic Models with Variable Intercepts: (AR(1)) (dep = time-inv + time-var + lag_dep + individual + error)

\[ y_it = z_i α + x_it β + γ y_it-1 + u_i + ε_it \]

  • Random Effects Models
    • General FGLS Estimator [1. OLS residuals for error covariance matrix estimation; 2. FGLS]
    • ML Estimator
    • GMM Estimator (IV estimator)
  • Fixed Effects Model
    • GMM Estimator (IV estimator)
    • General FGLS
      • Fixed Effect GLS Estimator (FEGLS)
      • First-difference GLS (FDGLS)
    • Transformed ML Estimator

GMM estimator. y ~ covariates | gmm instruments | 'normal' instruments By default, all the variables of the model which are not used as GMM instruments are used as normal instruments with the same lag structure as the one specified in the model. Transformation: difference GMM; system GMM.

General FGLS is based on a two-step estimation process: first a model is estimated by OLS (pooling), fixed effects (within) or first differences (fd), then its residuals are used to estimate an error covariance matrix for use in a feasible-GLS analysis. This framework allows the error covariance structure inside every group (individual time series) to be fully unrestricted and is therefore robust against any type of intragroup heteroskedasticity and serial correlation. Conversely, this structure is assumed identical across groups and thus general FGLS estimation is inefficient under groupwise heteroskedasticity. Efficiency requires N >> T.

first difference with IV estimator

Pooled OLS is biased upward and is inconsistent. GLS and ML estimators are also generally biased. Within estimator is biased, because eliminating the individual effect causes a correlation between the transformed error term and the transformed lagged dependent variable.

Complication: Limited Dependent Variable

For FE models:

  1. Qualitative Choice Models (Discrete Data):
    • Incidental Parameters Problem
    • Conditional MLE,

  2. Sample Selection Models (Censored and Trancated Data):

    • Trimmed LS estimator for FE model. (Honore, 1992)
  • Bias-Adjusted Maximum Simulated Likelihood (MSL) Estimator [12.4]
  • Auxiliary Models [12.6]

Complication: Cross-Sectionally Dependent Panel Data

  • Spatial Approach,
  • Factor Approach,
  • Cross-sectional Mean Augmented Approach,
  • Test of Cross-Sectional Independence

General FGLS is inefficient under cross-sectional correlation.

Panel Data Approach for Program Evaluation

Treatment Evaluation

  • Selection on observables and unobservables;
  • Propensity Score Matching Estimator (Rosenbaum and Rubin)
  • Other estimators
    • Differences-in-differences estimator;
    • IV estimator for local average treatment effect (LATE); (under selection on unobservables)
    • (Control function estimator)
  • Regression discontinuity (RD) design;

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