Abstract
The presence of outliers in the data has implications for stochastic frontier analysis, and indeed any performance analysis methodology, because they may lead to imprecise parameter estimates and, crucially, lead to an exaggerated spread of efficiency predictions. In this paper we replace the normal distribution for the noise term in the standard stochastic frontier model with a Student’s t distribution, which generalises the normal distribution by adding a shape parameter governing the degree of kurtosis. This has the advantages of introducing flexibility in the heaviness of the tails, which can be determined by the data, as well as containing the normal distribution as a limiting case, and we outline how to test against the standard model. Monte Carlo simulation results for the maximum simulated likelihood estimator confirm that the model recovers appropriate frontier and distributional parameter estimates under various values of the true shape parameter. The simulation results also indicate the influence of a phenomenon we term ‘wrong kurtosis’ in the case of small samples, which is analogous to the issue of ‘wrong skewness’ previously identified in the literature. We apply a Student’s t-half normal cost frontier to data for highways authorities in England, and this formulation is found to be preferred by statistical testing to the comparator normal-half normal cost frontier model. The model yields a significantly narrower range of efficiency predictions, which are non-monotonic at the tails of the residual distribution.
Highlights
Frontier analysis is concerned with the measurement of efficiency relative to an estimated production or cost frontier
As such our model provides a natural extension to the tools of practitioners in the field
This paper proposes a new stochastic frontier model as a means to account for outlying observations in the context of stochastic frontier analysis
Summary
Frontier analysis is concerned with the measurement of efficiency relative to an estimated production or cost frontier. For example Berger and Humphrey (1991) observe heavy tailed distribution of costs in banking, an industry to which efficiency analysis is often applied As such the issue in this paper has broad applicability across the performance literature. In this paper we outline and discuss the merits and empirical application of a new stochastic frontier model which accommodates the influence of outlying observations This is the stochastic frontier model with a Student’s t distribution for the noise term. Our model is an original and significant contribution to the literature, not just in being able to better accommodate outlying observations in efficiency analysis relative to the standard SF model, but it is the first contribution to contain as a testable limiting case the standard SF model As such our model provides a natural extension to the tools of practitioners in the field.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
