Nonparametric, Stochastic Frontier Models with Multiple Inputs and Outputs

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2022-08-08 DOI:10.1080/07350015.2022.2110882

L. Simar, P. W. Wilson

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引用次数: 6

Abstract

Abstract Stochastic frontier models along the lines of Aigner et al. are widely used to benchmark firms’ performances in terms of efficiency. The models are typically fully parametric, with functional form specifications for the frontier as well as both the noise and the inefficiency processes. Studies such as Kumbhakar et al. have attempted to relax some of the restrictions in parametric models, but so far all such approaches are limited to a univariate response variable. Some (e.g., Simar and Zelenyuk; Kuosmanen and Johnson) have proposed nonparametric estimation of directional distance functions to handle multiple inputs and outputs, raising issues of endogeneity that are either ignored or addressed by imposing restrictive and implausible assumptions. This article extends nonparametric methods developed by Simar et al. and Hafner et al. to allow multiple inputs and outputs in an almost fully nonparametric framework while avoiding endogeneity problems. We discuss properties of the resulting estimators, and examine their finite-sample performance through Monte Carlo experiments. Practical implementation of the method is illustrated using data on U.S. commercial banks.

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多输入和多输出的非参数随机前沿模型

摘要Aigner等人的随机前沿模型被广泛用于衡量企业的效率表现。模型通常是全参数的，具有边界以及噪声和低效过程的函数形式规范。Kumbhakar等人的研究试图放松参数模型中的一些限制，但到目前为止，所有这些方法都局限于单变量响应变量。一些人（例如，Simar和Zelenyuk；Kuosmann和Johnson）提出了方向距离函数的非参数估计，以处理多个输入和输出，提出了内生性问题，这些问题要么被忽视，要么通过强加限制性和不可信的假设来解决。本文扩展了Simar等人和Hafner等人开发的非参数方法。在几乎完全非参数的框架中允许多个输入和输出，同时避免内生性问题。我们讨论了所得估计量的性质，并通过蒙特卡罗实验检验了它们的有限样本性能。利用美国商业银行的数据说明了该方法的实际实施。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464