English

Orthogonal Polynomials for Seminonparametric Instrumental Variables Model

Statistics Theory 2014-09-08 v1 Economics Applications Statistics Theory

Abstract

We develop an approach that resolves a {\it polynomial basis problem} for a class of models with discrete endogenous covariate, and for a class of econometric models considered in the work of Newey and Powell (2003), where the endogenous covariate is continuous. Suppose XX is a dd-dimensional endogenous random variable, Z1Z_1 and Z2Z_2 are the instrumental variables (vectors), and Z=(Z1Z2)Z=\left(\begin{array}{c}Z_1 \\Z_2\end{array}\right). Now, assume that the conditional distributions of XX given ZZ satisfy the conditions sufficient for solving the identification problem as in Newey and Powell (2003) or as in Proposition 1.1 of the current paper. That is, for a function π(z)\pi(z) in the image space there is a.s. a unique function g(x,z1)g(x,z_1) in the domain space such that E[g(X,Z1)  Z]=π(Z)Za.s.E[g(X,Z_1)~|~Z]=\pi(Z) \qquad Z-a.s. In this paper, for a class of conditional distributions XZX|Z, we produce an orthogonal polynomial basis Qj(x,z1)Q_j(x,z_1) such that for a.e. Z1=z1Z_1=z_1, and for all jZ+dj \in \mathbb{Z}_+^d, and a certain μ(Z)\mu(Z), Pj(μ(Z))=E[Qj(X,Z1)  Z],P_j(\mu(Z))=E[Q_j(X, Z_1)~|~Z ], where PjP_j is a polynomial of degree jj. This is what we call solving the {\it polynomial basis problem}. Assuming the knowledge of XZX|Z and an inference of π(z)\pi(z), our approach provides a natural way of estimating the structural function of interest g(x,z1)g(x,z_1). Our polynomial basis approach is naturally extended to Pearson-like and Ord-like families of distributions.

Keywords

Cite

@article{arxiv.1409.1620,
  title  = {Orthogonal Polynomials for Seminonparametric Instrumental Variables Model},
  author = {Yevgeniy Kovchegov and Nese Yildiz},
  journal= {arXiv preprint arXiv:1409.1620},
  year   = {2014}
}

Comments

18 pages

R2 v1 2026-06-22T05:49:05.919Z