Welfare Analysis in Dynamic Models
This work addresses welfare analysis for researchers and policymakers in economics and social sciences, but it is incremental as it builds on existing dual and debiasing methods.
The paper tackles the problem of welfare analysis in dynamic models with high-dimensional state spaces by introducing metrics like average welfare and developing estimation and inference methods, including debiased approaches using techniques such as Lasso and neural networks, applied to a teacher absenteeism model.
This paper introduces metrics for welfare analysis in dynamic models. We develop estimation and inference for these parameters even in the presence of a high-dimensional state space. Examples of welfare metrics include average welfare, average marginal welfare effects, and welfare decompositions into direct and indirect effects similar to Oaxaca (1973) and Blinder (1973). We derive dual and doubly robust representations of welfare metrics that facilitate debiased inference. For average welfare, the value function does not have to be estimated. In general, debiasing can be applied to any estimator of the value function, including neural nets, random forests, Lasso, boosting, and other high-dimensional methods. In particular, we derive Lasso and Neural Network estimators of the value function and associated dynamic dual representation and establish associated mean square convergence rates for these functions. Debiasing is automatic in the sense that it only requires knowledge of the welfare metric of interest, not the form of bias correction. The proposed methods are applied to estimate a dynamic behavioral model of teacher absenteeism in \cite{DHR} and associated average teacher welfare.