Institute for Economic and Social Research
测试

SEMINAR| Qihui Chen, CUHK

2020-12-24

Title: Robust and Optimal Estimation for Partially Linear IV Models with Partial Identification

Speaker: Qihui Chen,  CUHK Shenzhen

Time: December 21st, 2020, 13:30-15:00
Venue: Room 106B, Zhonghui Building

About the speaker

Qihui Chen received his Ph.D in Economics from the University of California, San Diego in 2017. Prior to that, he earned Bachelor’s degrees from Xiamen University and Master’s degrees from both Xiamen University and Singapore Management University. He joined the School of Management and Economics of CUHK-Shenzhen in July 2017. His research interests include econometric theory and applied econometrics.

Abstract:

This paper studies robust and optimal estimation of the slope coefficients in a partially linear instrumental variables model with nonparametric partial identification. We establish the root-n asymptotic normality of a penalized sieve minimum distance estimator of the slope coefficients. We show that the asymptotic normality holds regardless of whether the nonparametric function is point identified or only partially identified. However, in the presence of nonparametric partial identification, the slope coefficients may not be continuous in the underlying distribution and the asymptotic variance matrix may depend on the penalty, so classical efficiency analysis does not apply. We instead develop an optimally penalized estimator that minimizes the asymptotic variance of a linear functional of the slope coefficients estimator by employing an optimal penalty for a given weight, and propose a feasible two-step procedure. We also propose an iterated procedure to address how to choose both penalty and weight optimally and further improve efficiency. To conduct inference, we provide a consistent variance matrix estimator. Monte Carlo simulations examine the finite sample performance of our estimators.

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