English

Policy Optimization Using Semi-parametric Models for Dynamic Pricing

Machine Learning 2022-05-05 v2 Econometrics Optimization and Control Methodology Machine Learning

Abstract

In this paper, we study the contextual dynamic pricing problem where the market value of a product is linear in its observed features plus some market noise. Products are sold one at a time, and only a binary response indicating success or failure of a sale is observed. Our model setting is similar to Javanmard and Nazerzadeh [2019] except that we expand the demand curve to a semiparametric model and need to learn dynamically both parametric and nonparametric components. We propose a dynamic statistical learning and decision-making policy that combines semiparametric estimation from a generalized linear model with an unknown link and online decision-making to minimize regret (maximize revenue). Under mild conditions, we show that for a market noise c.d.f. F()F(\cdot) with mm-th order derivative (m2m\geq 2), our policy achieves a regret upper bound of O~d(T2m+14m1)\tilde{O}_{d}(T^{\frac{2m+1}{4m-1}}), where TT is time horizon and O~d\tilde{O}_{d} is the order that hides logarithmic terms and the dimensionality of feature dd. The upper bound is further reduced to O~d(T)\tilde{O}_{d}(\sqrt{T}) if FF is super smooth whose Fourier transform decays exponentially. In terms of dependence on the horizon TT, these upper bounds are close to Ω(T)\Omega(\sqrt{T}), the lower bound where FF belongs to a parametric class. We further generalize these results to the case with dynamically dependent product features under the strong mixing condition.

Keywords

Cite

@article{arxiv.2109.06368,
  title  = {Policy Optimization Using Semi-parametric Models for Dynamic Pricing},
  author = {Jianqing Fan and Yongyi Guo and Mengxin Yu},
  journal= {arXiv preprint arXiv:2109.06368},
  year   = {2022}
}

Comments

71 pages, Major Revision

R2 v1 2026-06-24T05:56:21.330Z