Revenue Management with Calendar-Aware and Dependent Demands: Asymptotically Tight Fluid Approximations

TL;DR

This paper develops an asymptotically optimal fluid approximation for revenue management models with calendar-aware, dependent demands, accommodating arbitrary distributions and improving policy performance.

Contribution

It introduces the first asymptotically optimal policy for revenue management with dependent demands and arbitrary distributions, using a novel fluid approximation approach.

Findings

Fluid approximation yields asymptotically optimal policies.

Performance guarantee approaches one as capacities and stages increase.

Using the correct fluid model significantly improves practical outcomes.

Abstract

When modeling the demand in revenue management systems, a natural approach is to focus on a canonical interval of time, such as a week, so that we forecast the demand over each week in the selling horizon. Ideally, we would like to use random variables with general distributions to model the demand over each week. The current demand can give a signal for the future demand, so we also would like to capture the dependence between the demands over different weeks. Prevalent demand models in the literature, which are based on a discrete-time approximation to a Poisson process, are not compatible with these needs. In this paper, we focus on revenue management models that are compatible with a natural approach for forecasting the demand. Building such models through dynamic programming is not difficult. We divide the selling horizon into multiple stages, each stage being a canonical interval of time on the calendar. We have random number of customer arrivals in each stage, whose distribution is arbitrary and depends on the number of arrivals in the previous stage. The question we seek to answer is the form of the corresponding fluid approximation. We give the correct fluid approximation in the sense that it yields asymptotically optimal policies. The form of our fluid approximation is surprising as its constraints use expected capacity consumption of a resource up to a certain time period, conditional on the demand in the stage just before the time period in question. As the resource capacities and number of stages increase with the same rate, our performance guarantee converges to one. To our knowledge, this result gives the first asymptotically optimal policy under dependent demands with arbitrary distributions. Our computational experiments indicate that using the correct fluid approximation can make a dramatic impact in practice.