TY - GEN
T1 - A lagrangian approach to dynamic resource allocation
AU - Gocgun, Yasin
AU - Ghate, Archis
PY - 2010
Y1 - 2010
N2 - We define a class of discrete-time resource allocation problems where multiple renewable resources must be dynamically allocated to different types of jobs arriving randomly. Jobs have geometric service durations, demand resources, incur a holding cost while waiting in queue, a penalty cost of rejection when the queue is filled to capacity, and generate a reward on completion. The goal is to select which jobs to service in each time-period so as to maximize total infinite-horizon discounted expected profit. We present Markov Decision Process (MDP) models of these problems and apply a Lagrangian relaxation-based method that exploits the structure of the MDP models to approximate their optimal value functions. We then develop a dynamic programming technique to efficiently recover resource allocation decisions from this approximate value function on the fly. Numerical experiments demonstrate that these decisions outperform well-known heuristics by at least 35% but as much as 220% on an average.
AB - We define a class of discrete-time resource allocation problems where multiple renewable resources must be dynamically allocated to different types of jobs arriving randomly. Jobs have geometric service durations, demand resources, incur a holding cost while waiting in queue, a penalty cost of rejection when the queue is filled to capacity, and generate a reward on completion. The goal is to select which jobs to service in each time-period so as to maximize total infinite-horizon discounted expected profit. We present Markov Decision Process (MDP) models of these problems and apply a Lagrangian relaxation-based method that exploits the structure of the MDP models to approximate their optimal value functions. We then develop a dynamic programming technique to efficiently recover resource allocation decisions from this approximate value function on the fly. Numerical experiments demonstrate that these decisions outperform well-known heuristics by at least 35% but as much as 220% on an average.
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U2 - 10.1109/WSC.2010.5679024
DO - 10.1109/WSC.2010.5679024
M3 - Conference contribution
AN - SCOPUS:79951643984
SN - 9781424498666
T3 - Proceedings - Winter Simulation Conference
SP - 3330
EP - 3340
BT - Proceedings of the 2010 Winter Simulation Conference, WSC'10
T2 - 2010 43rd Winter Simulation Conference, WSC'10
Y2 - 5 December 2010 through 8 December 2010
ER -