1 / 35

Empirical Models to deal with Unobserved Heterogeneity

Empirical Models to deal with Unobserved Heterogeneity. Antonio Álvarez University of Oviedo &Cajastur. Universidad de Las Palmas de Gran Canaria, 31/10/2011. Unobserved heterogeneity (I). Definition

erika
Télécharger la présentation

Empirical Models to deal with Unobserved Heterogeneity

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Empirical Models to deal with Unobserved Heterogeneity Antonio Álvarez University of Oviedo &Cajastur Universidad de Las Palmas de Gran Canaria, 31/10/2011

  2. Unobserved heterogeneity (I) • Definition • Characteristics of the individuals (firms, regions, persons,…) that are not measured in the sample • Examples • Input quality in production functions • Genetic level of the herds • Land fragmentation • Management • Consequences of unobserved heterogeneity • If not accounted for, may cause biased estimates • Griliches (1957)

  3. Unobserved heterogeneity (II) • In empirical economics we are interested in some unobservables • Technological characteristics (Marginal products…) • The change in technology (Technical change) • The use of technology (Technical Efficiency) • Empirical approach • Estimation of production, cost or distance functions

  4. Technical Efficiency (I) Concept of Efficiency Y Production Frontier Inefficiency: distance to the technological frontier X

  5. Technical Efficiency (II) Frontier Models Deterministic Frontiers Y = f(x) – u ; u0 Stochastic Frontiers Y = f(x) + v – u; u0

  6. Modeling Production Technology • Typical production function • Firms may have different technical characteristics (marginal products) due to differences in input use • Typical production frontier • Technology, Technical change and Technical Efficiency are modeled but firm heterogeneity is confounded

  7. Unobserved Heterogeneity Models • Traditional models of firm heterogeneity • Different parameters for different firms • Fixed Effects • Random Effects • Heterogeneity is confounded with (time invariant) technical efficiency

  8. Objectives of the Seminar • Review some techniques that allow to separate unobserved firm heterogeneity and efficiency • Present two applications

  9. Separating Unobserved Firm Heterogeneity from Inefficiency

  10. Summary of literature • Several new models attempt to separate unobserved firm heterogeneity and inefficiency • Stochastic Frontier with Fixed Effects • Kumbhakar and Hjalmarsson(1993), Greene (2005) • Alvarez (2006) • Random Coefficient Models • Tsionas (2002), Huang (2004) • Alvarez, Arias and Greene (2005) • Latent Class Models • Orea and Kumbhakar (2004) • Alvarez and del Corral (2008)

  11. Stochastic Frontier Model • Uit is (time-varying) technical inefficiency • Firm Heterogeneity is confounded with efficiency

  12. Stochastic Frontier with Fixed Effects • i captures time-invariant heterogeneity • Technological differences • “Persistent” inefficiency • Uit captures time-varying heterogeneity • Time-varying inefficiency (catch-up) • Time-varying technological differences (sector composition) • Greene (2005):Estimation by “brute force” ML

  13. SF Latent Class Models • Orea and Kumbhakar (2004) • Estimation by ML • Number of classes is unknown

  14. Different Groups (Classes) y x

  15. Application of the Stochastic Frontier with Fixed Effects Model Separating firm heterogeneity from inefficiency in regional production functions

  16. Data • Panel of 50 Spanish provinces (1985-1999) • Output: GVA • Inputs: • Private capital (K) • Labor (L) • Human Capital (HC) • Public Capital (G)

  17. Empirical Model • Functional form: Cobb-Douglas • Neutral Technical Change • Stochastic Frontier with Fixed Effects (SFFE) • Vit is assumed to be N(0,σv) • Uit is assumed to follow a half-normal distribution: N+(0,σu)

  18. Estimation • Greene (2002) • Estimation by ML • “Maximization of the unconditional log likelihood function can, in fact, be done by ‘brute force’ even in the presence of possibly thousands of nuisance parameters by using Newton’s method and some well known results from matrix algebra”

  19. Comparing inefficiency Corr (Uit_SFFE,Uit_PSF)= 0.50

  20. Comparing fixed effects Corr (FE_SFFE,FE_Within)= 0.19

  21. Ranking of Fixed Effects

  22. Main findings • The models with Uit yield similar results, which in turn are very different from the FE model • The estimated fixed effects in the FE and SFFE models are very different

  23. Application of the Latent Class Model Identifying different technologies: extensive vs intensive dairy farms

  24. Dairy Farming in Spain • Recent trends • Large reduction in the number of farms • 50% reduction during 2000-2008 • Quota System • Since 1991 • Farms have grown • Average quota almost doubled in last seven years • Change in the production system • Many farms have adopted more intensive systems

  25. Intensive vs Extensive Systems • Characteristics of intensive systems • Farms produce more liters of milk per hectare of land • How? • More cows per hectare of land • Higher use of concentrates per cow • Higher genetic level of the herds • Unobservable!!!

  26. Objectives • Are there differences in technological characteristics between extensive and intensive farms? • H0: Intensive farms have higher returns to scale • They have grown more than extensive farms • Are there differences in technical efficiency? • H0: Intensive farms produce closer to their frontier • We consider that the intensive system is “easier” to manage

  27. Latent Class Stochastic Frontiers • Latent Class Stochastic Frontier Model • Likelihood function • Probabilities • Number of classes

  28. Data • Panel data set • 169 dairy farms • 6 years (1999-2004) • Output • Milk liters • Inputs • Cows, Feed (kg.), Land (hectares), crop expenses (euros)

  29. Empirical Model • Translog stochastic production frontier • Control variables • Time dummies • Location dummies • Separating variables • Cows per hectare of land • Feed per cow

  30. Estimation results *, **, *** indicate significance at the 10%, 5% and 1% levels

  31. Characteristics of the Systems

  32. Scale Elasticity inthe LCM Intensive farms have higher scale elasticity than extensive farms

  33. Technical Efficiency

  34. Discussion • The results of the LCM help to explain two empirical facts • Farms grow despite the decline in the price of milk • Large farms buy quota from small farms • The marginal value of quota is price minus marginal cost

  35. Conclusions • It is important to model unobserved heterogeneity • Some new techniques provide an interesting framework to control for firm heterogeneity

More Related