Dynamic Pricing in High-dimensions
Abstract
We study the pricing problem faced by a firm that sells a large number of products, described via a wide range of features, to customers that arrive over time. Customers independently make purchasing decisions according to a general choice model that includes products features and customers' characteristics, encoded as -dimensional numerical vectors, as well as the price offered. The parameters of the choice model are a priori unknown to the firm, but can be learned as the (binary-valued) sales data accrues over time. The firm's objective is to minimize the regret, i.e., the expected revenue loss against a clairvoyant policy that knows the parameters of the choice model in advance, and always offers the revenue-maximizing price. This setting is motivated in part by the prevalence of online marketplaces that allow for real-time pricing. We assume a structured choice model, parameters of which depend on out of the product features. We propose a dynamic policy, called Regularized Maximum Likelihood Pricing (RMLP) that leverages the (sparsity) structure of the high-dimensional model and obtains a logarithmic regret in . More specifically, the regret of our algorithm is of . Furthermore, we show that no policy can obtain regret better than .
Cite
@article{arxiv.1609.07574,
title = {Dynamic Pricing in High-dimensions},
author = {Adel Javanmard and Hamid Nazerzadeh},
journal= {arXiv preprint arXiv:1609.07574},
year = {2018}
}
Comments
47 pages