TY - GEN
T1 - Dynamic pricing with limited supply
AU - Babaioff, Moshe
AU - Dughmi, Shaddin
AU - Kleinberg, Robert
AU - Slivkins, Aleksandrs
PY - 2012
Y1 - 2012
N2 - We consider the problem of designing revenue maximizing online posted-price mechanisms when the seller has limited supply. A seller has k identical items for sale and is facing n potential buyers ("agents") that are arriving sequentially. Each agent is interested in buying one item. Each agent's value for an item is an independent sample from some fixed (but unknown) distribution with support [0,1]. The seller offers a take-it-or-leave-it price to each arriving agent (possibly different for different agents), and aims to maximize his expected revenue. We focus on mechanisms that do not use any information about the distribution; such mechanisms are called "detail-free" (an alternative term is "prior-independent"). They are desirable because knowing the distribution is unrealistic in many practical scenarios. We study how the revenue of such mechanisms compares to the revenue of the optimal offline mechanism that knows the distribution ("offline benchmark"). We present a detail-free online posted-price mechanism whose revenue is at most O((k log n) 2/3) less than the offline benchmark, for every distribution that is regular. In fact, this guarantee holds without any assumptions if the benchmark is relaxed to fixed-price mechanisms. Further, we prove a matching lower bound. The performance guarantee for the same mechanism can be improved to O(√k log n), with a distribution-dependent constant, if the ratio k/n is sufficiently small. We show that, in the worst case over all demand distributions, this is essentially the best rate that can be obtained with a distribution-specific constant.
AB - We consider the problem of designing revenue maximizing online posted-price mechanisms when the seller has limited supply. A seller has k identical items for sale and is facing n potential buyers ("agents") that are arriving sequentially. Each agent is interested in buying one item. Each agent's value for an item is an independent sample from some fixed (but unknown) distribution with support [0,1]. The seller offers a take-it-or-leave-it price to each arriving agent (possibly different for different agents), and aims to maximize his expected revenue. We focus on mechanisms that do not use any information about the distribution; such mechanisms are called "detail-free" (an alternative term is "prior-independent"). They are desirable because knowing the distribution is unrealistic in many practical scenarios. We study how the revenue of such mechanisms compares to the revenue of the optimal offline mechanism that knows the distribution ("offline benchmark"). We present a detail-free online posted-price mechanism whose revenue is at most O((k log n) 2/3) less than the offline benchmark, for every distribution that is regular. In fact, this guarantee holds without any assumptions if the benchmark is relaxed to fixed-price mechanisms. Further, we prove a matching lower bound. The performance guarantee for the same mechanism can be improved to O(√k log n), with a distribution-dependent constant, if the ratio k/n is sufficiently small. We show that, in the worst case over all demand distributions, this is essentially the best rate that can be obtained with a distribution-specific constant.
KW - dynamic pricing
KW - mechanism design
KW - multi-armed bandits
KW - revenue maximization
UR - http://www.scopus.com/inward/record.url?scp=84863515685&partnerID=8YFLogxK
U2 - 10.1145/2229012.2229023
DO - 10.1145/2229012.2229023
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AN - SCOPUS:84863515685
SN - 9781450314152
T3 - Proceedings of the ACM Conference on Electronic Commerce
SP - 74
EP - 91
BT - EC '12 - Proceedings of the 13th ACM Conference on Electronic Commerce
T2 - 13th ACM Conference on Electronic Commerce, EC '12
Y2 - 4 June 2012 through 8 June 2012
ER -