793 research outputs found
Designing Coalition-Proof Reverse Auctions over Continuous Goods
This paper investigates reverse auctions that involve continuous values of
different types of goods, general nonconvex constraints, and second stage
costs. We seek to design the payment rules and conditions under which
coalitions of participants cannot influence the auction outcome in order to
obtain higher collective utility. Under the incentive-compatible
Vickrey-Clarke-Groves mechanism, we show that coalition-proof outcomes are
achieved if the submitted bids are convex and the constraint sets are of a
polymatroid-type. These conditions, however, do not capture the complexity of
the general class of reverse auctions under consideration. By relaxing the
property of incentive-compatibility, we investigate further payment rules that
are coalition-proof without any extra conditions on the submitted bids and the
constraint sets. Since calculating the payments directly for these mechanisms
is computationally difficult for auctions involving many participants, we
present two computationally efficient methods. Our results are verified with
several case studies based on electricity market data
A Truthful Mechanism for the Generalized Assignment Problem
We propose a truthful-in-expectation, -approximation mechanism for a
strategic variant of the generalized assignment problem (GAP). In GAP, a set of
items has to be optimally assigned to a set of bins without exceeding the
capacity of any singular bin. In the strategic variant of the problem we study,
values for assigning items to bins are the private information of bidders and
the mechanism should provide bidders with incentives to truthfully report their
values. The approximation ratio of the mechanism is a significant improvement
over the approximation ratio of the existing truthful mechanism for GAP.
The proposed mechanism comprises a novel convex optimization program as the
allocation rule as well as an appropriate payment rule. To implement the convex
program in polynomial time, we propose a fractional local search algorithm
which approximates the optimal solution within an arbitrarily small error
leading to an approximately truthful-in-expectation mechanism. The presented
algorithm improves upon the existing optimization algorithms for GAP in terms
of simplicity and runtime while the approximation ratio closely matches the
best approximation ratio given for GAP when all inputs are publicly known.Comment: 18 pages, Earlier version accepted at WINE 201
Mechanism Design via Correlation Gap
For revenue and welfare maximization in single-dimensional Bayesian settings,
Chawla et al. (STOC10) recently showed that sequential posted-price mechanisms
(SPMs), though simple in form, can perform surprisingly well compared to the
optimal mechanisms. In this paper, we give a theoretical explanation of this
fact, based on a connection to the notion of correlation gap.
Loosely speaking, for auction environments with matroid constraints, we can
relate the performance of a mechanism to the expectation of a monotone
submodular function over a random set. This random set corresponds to the
winner set for the optimal mechanism, which is highly correlated, and
corresponds to certain demand set for SPMs, which is independent. The notion of
correlation gap of Agrawal et al.\ (SODA10) quantifies how much we {}"lose" in
the expectation of the function by ignoring correlation in the random set, and
hence bounds our loss in using certain SPM instead of the optimal mechanism.
Furthermore, the correlation gap of a monotone and submodular function is known
to be small, and it follows that certain SPM can approximate the optimal
mechanism by a good constant factor.
Exploiting this connection, we give tight analysis of a greedy-based SPM of
Chawla et al.\ for several environments. In particular, we show that it gives
an -approximation for matroid environments, gives asymptotically a
-approximation for the important sub-case of -unit
auctions, and gives a -approximation for environments with
-independent set system constraints
- β¦