Abstract
We study price optimization of perishable inventory over multiple, consecutive selling seasons in the presence of demand uncertainty. Each selling season consists of a finite number of discrete time periods, and demand per time period is Bernoulli distributed with price-dependent parameter. The set of feasible prices is finite, and the expected demand corresponding to each price is unknown to the seller, whose objective is to maximize cumulative expected revenue. We propose an algorithm that estimates the unknown parameters in a learning phase, and in each subsequent season applies a policy determined as the solution to a sample dynamic program, which modifies the underlying dynamic program by replacing the unknown parameters by the estimate. Revenue performance is measured by the regret: the expected revenue loss relative to the optimal attainable revenue under full information. For a given number of seasons n, we show that if the number of seasons allocated to learning is asymptotic to (n^2log n)^{1/3}, then the regret is of the same order, uniformly over all unknown demand parameters. An extensive numerical study that compares our algorithm to six benchmarks adapted from the literature demonstrates the effectiveness of our approach.
Highlights
1.1 BackgroundPricing of a perishable product is a central problem in many industries
In Gallego and van Ryzin (1994), an optimal price is shown to be a function of the state (t, c) of the system, where t denotes remaining time to the end of the season and c denotes remaining inventory; this function increases with remaining time and decreases with remaining inventory
We show that the prices generated by our pricing strategy converge to the optimal prices corresponding to the Markov Decision Process (MDP) defined in Sect. 2, as the number of selling seasons n grows large
Summary
1.1 BackgroundPricing of a perishable product is a central problem in many industries. The firm seeks to set prices in a way that maximizes the expected revenue Instances of this problem are found in many industries, including fashion, retail, air travel, hospitality, and leisure. In Gallego and van Ryzin (1994), an optimal price is shown to be a function of the state (t, c) of the system, where t denotes remaining time to the end of the season and c denotes remaining inventory; this function increases with remaining time and decreases with remaining inventory. To compute these optimal prices, it is essential to know the relationship between price and expected demand—often referred to as the demand function or demand curve
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