Unobserved heterogeneity in duration models

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Issues of heterogeneity in duration models can take on different forms. On the one hand, unobserved heterogeneity can play a crucial role when it comes to different sampling methods, such as stock or flow sampling.[1] On the other hand, duration models have also been extended to allow for different subpopulations, with a strong link to mixture models. Many of these models impose the assumptions that heterogeneity is independent of the observed covariates, it has a distribution that depends on a finite number of parameters only, and it enters the hazard function multiplicatively.[2]

One can define the conditional hazard as the hazard function conditional on the observed covariates and the unobserved heterogeneity.[3] In the general case, the cumulative distribution function of ti* associated with the conditional hazard is given by F(t|xi , vi ; θ). Under the first assumption above, the unobserved component can be integrated out and we obtain the cumulative distribution on the observed covariates only, i.e.

G(t ∨ xi ; θ , ρ) = ∫ F (t ∨ xi, ν ; θ ) h ( ν ; ρ ) dν [4]

where the additional parameter ρ parameterizes the density of the unobserved component v. Now, the different estimation methods for stock or flow sampling data are available to estimate the relevant parameters.

A specific example is described by Lancaster. Assume that the conditional hazard is given by

λ(t ; xi , vi ) = vi exp (x [5] β) α t α-1

where x is a vector of observed characteristics, v is the unobserved heterogeneity part, and a normalization (often E[vi] = 1) needs to be imposed. It then follows that the average hazard is given by exp(x'β) αtα-1. More generally, it can be shown that as long as the hazard function exhibits proportional properties of the form λ ( t ; xi, vi ) = vi κ (xi ) λ0 (t), one can identify both the covariate function κ(.) and the hazard function λ(.).[6]

Recent examples provide a nonparametric approaches to estimating the baseline hazard and the distribution of the unobserved heterogeneity under fairly weak assumptions.[7] In grouped data, the strict exogeneity assumptions for time-varying covariates are hard to relax. Parametric forms can be imposed for the distribution of the unobserved heterogeneity,[8] even though semiparametric methods that do not specify such parametric forms for the unobserved heterogeneity are available.[9]

References[edit]

  1. ^ Salant, S. W. (1977): Search Theory and Duration Data: A Theory of Sorts. The Quarterly Journal of Economics, 91(1), pp. 39-57
  2. ^ Wooldridge, J. (2002): Econometric Analysis of Cross Section and Panel Data, MIT Press, Cambridge, Mass.
  3. ^ Lancaster, T. (1990): The Econometric Analysis of Transition Data. Cambridge University Press, Cambridge.
  4. ^ Wooldridge, J. (2002): Econometric Analysis of Cross Section and Panel Data, MIT Press, Cambridge, Mass.
  5. ^ i
  6. ^ Lancaster, T. (1990): The Econometric Analysis of Transition Data. Cambridge University Press, Cambridge.
  7. ^ Horowitz, J. L. (1999): Semiparametric and Nonparametric Estimation of Quantal Response Models. Handbook of Statistics, Vol. 11, ed. by G. S. Maddala, C. R. Rao, and H. D. Vinod. North Holland, Amsterdam.
  8. ^ McCall, B. P. (1994): Testing the Proportional Hazards Assumption in the Presence of Unmeasured Heterogeneity. Journal of Applied Econometrics, 9, pp. 321-334
  9. ^ Heckman, J. J. and B. Singer (1984): A Method for Minimizing the Impact of Distributional Assumptions in Econometric Models for Duration Data. Econometrica, 52, pp. 271-320
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