TY - GEN
T1 - Partial Allocations in Budget-Feasible Mechanism Design
T2 - 19th InternationalConference on Web and Internet Economics, WINE 2023
AU - Amanatidis, Georgios
AU - Klumper, Sophie
AU - Markakis, Evangelos
AU - Schäfer, Guido
AU - Tsikiridis, Artem
N1 - Publisher Copyright:
© 2024, The Author(s), under exclusive license to Springer Nature Switzerland AG.
PY - 2024
Y1 - 2024
N2 - Budget-feasible procurement has been a major paradigm in mechanism design since its introduction by Singer [24]. An auctioneer (buyer) with a strict budget constraint is interested in buying goods or services from a group of strategic agents (sellers). In many scenarios it makes sense to allow the auctioneer to only partially buy what an agent offers, e.g., an agent might have multiple copies of an item to sell, they might offer multiple levels of a service, or they may be available to perform a task for any fraction of a specified time interval. Nevertheless, the focus of the related literature has been on settings where each agent’s services are either fully acquired or not at all. A reason for this is that in settings with partial allocations, without any assumptions on the costs, there are strong inapproximability results (see, e.g., Chan and Chen [10], Anari et al. [5]). Under the mild assumption of being able to afford each agent entirely, we are able to circumvent such results. We design a polynomial-time, deterministic, truthful, budget-feasible, (2+3) -approximation mechanism for the setting where each agent offers multiple levels of service and the auctioneer has a discrete separable concave valuation function. We then use this result to design a deterministic, truthful and budget-feasible mechanism for the setting where any fraction of a service can be acquired and the auctioneer’s valuation function is separable concave (i.e., the sum of concave functions). The approximation ratio of this mechanism depends on how “nice” the concave functions are, and is O(1) for valuation functions that are sums of O(1)-regular functions (e.g., functions like log (1 + x) ). For the special case of a linear valuation function, we improve the best known approximation ratio from 1 + ϕ (by Klumper and Schäfer [17]) to 2. This establishes a separation result between this setting and its indivisible counterpart.
AB - Budget-feasible procurement has been a major paradigm in mechanism design since its introduction by Singer [24]. An auctioneer (buyer) with a strict budget constraint is interested in buying goods or services from a group of strategic agents (sellers). In many scenarios it makes sense to allow the auctioneer to only partially buy what an agent offers, e.g., an agent might have multiple copies of an item to sell, they might offer multiple levels of a service, or they may be available to perform a task for any fraction of a specified time interval. Nevertheless, the focus of the related literature has been on settings where each agent’s services are either fully acquired or not at all. A reason for this is that in settings with partial allocations, without any assumptions on the costs, there are strong inapproximability results (see, e.g., Chan and Chen [10], Anari et al. [5]). Under the mild assumption of being able to afford each agent entirely, we are able to circumvent such results. We design a polynomial-time, deterministic, truthful, budget-feasible, (2+3) -approximation mechanism for the setting where each agent offers multiple levels of service and the auctioneer has a discrete separable concave valuation function. We then use this result to design a deterministic, truthful and budget-feasible mechanism for the setting where any fraction of a service can be acquired and the auctioneer’s valuation function is separable concave (i.e., the sum of concave functions). The approximation ratio of this mechanism depends on how “nice” the concave functions are, and is O(1) for valuation functions that are sums of O(1)-regular functions (e.g., functions like log (1 + x) ). For the special case of a linear valuation function, we improve the best known approximation ratio from 1 + ϕ (by Klumper and Schäfer [17]) to 2. This establishes a separation result between this setting and its indivisible counterpart.
KW - Budget-Feasible Mechanism Design
KW - Multiple Levels of Service
KW - Procurement Auctions
UR - http://www.scopus.com/inward/record.url?scp=85181984880&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85181984880&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-48974-7_3
DO - 10.1007/978-3-031-48974-7_3
M3 - Conference contribution
AN - SCOPUS:85181984880
SN - 9783031489730
T3 - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
SP - 41
EP - 58
BT - Web and Internet Economics
A2 - Garg, Jugal
A2 - Klimm, Max
A2 - Kong, Yuqing
PB - Springer Science and Business Media Deutschland GmbH
Y2 - 4 December 2023 through 8 December 2023
ER -