Abstract
This research studies a cash inventory problem in an ATM Network to satisfy customers cash needs over multiple periods with deterministic demand. The objective is to determine the amount of money to place in Automated Teller Machines (ATMs) and cash centers for each period over a given time horizon. The algorithms are designed as a multi-echelon inventory problem with single-item capacitated lot-sizing to minimize total costs of running ATM network. In this study, we formulate the problem as a Mixed Integer Program (MIP) and develop an approach based on reformulating the model as a shortest path formulation for finding a near-optimal solution of the problem. This reformulation is the same as the traditional model, except the capacity constraints, inventory balance constraints and setup constraints related to the management of the money in ATMs are relaxed. This new formulation gives more variables and constraints, but has a much tighter linear relaxation than the original and is faster to solve for short term planning. Computational results show its effectiveness, especially for large sized problems.
Highlights
This research focuses on cash management for an Automated Teller Machines (ATMs) network in Thailand
The algorithms are designed as a multi-echelon inventory problem with single-item capacitated lot-sizing to minimize total costs of running ATM network
We formulate the problem as a Mixed Integer Program (MIP) and develop an approach based on reformulating the model as a shortest path formulation for finding a near-optimal solution of the problem
Summary
This research focuses on cash management for an ATM network in Thailand. ATM planning and replenishment to serve customer’s cash needs are a key service of commercial banks. Wakinaga and Sawaki (2008) studied a dynamic programming approach for solving the dynamic lot size model for the case where single-item is produced and shipped by an overseas export company They explored the problem with the constraint of production and shipment capacity so as to minimize the total cost over the finite planning horizon with deterministic demands. Berk et al (2008) developed the dynamic programming formulation of the single item lot-sizing problem for a walm/cold process with finite capacity and possible lost sales and solved the problem with a polynomial solution algorithm based on the lost-sales-improvements of the full commitment problem They obtained the optimal solution in case of positive setup times and the heuristic solutions in another cases
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