Publication: Exact optimization and decomposition approaches for shelf space allocation
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Date
2022-01-19
Authors
Gençosman, Burcu Çağlar
Authors
Beğen, Mehmet A.
Journal Title
Journal ISSN
Volume Title
Publisher
Elsevier
Abstract
A B S T R A C T Shelf space is one of the scarcest resources, and its effective management to maximize profits has become essential to gain a competitive advantage for retailers. We consider the shelf space allocation problem with additional features (e.g., integer facings, rectangular arrangement restrictions) motivated by litera-ture and our interactions with a local bookstore. We determine optimal number of facings of all products in two aspects (width and height of a rectangular arrangement space for each product), and allocate them as contiguous rectangles to maximize profit. We first develop a mixed-integer linear mathematical programming model (MIP) for our problem and propose a solution method based on logic-based Ben-ders decomposition (LBBD). Next, we construct an exact 2-stage algorithm (IP1/IP2), inspired by LBBD, which can handle larger and real-world size instances. To compare performances of our methods, we generate 100 test instances inspired by real-world applications and benchmarks from the literature. We observe that IP1/IP2 finds optimal solutions for real-world instances efficiently and can increase the local bookstore's profit up to 16.56%. IP1/IP2 can provide optimal solutions for instances with 100 products in minutes and optimally solve up to 250 products (assigned to 8 rows x 160 columns) within a time limit of 1800 s. This exact 2-stage IP1/IP2 solution approach can be effective in solving similar problems such as display problem of webpage design, allocation of product families in grocery stores, and flyer advertising.
Description
Keywords
Data mining approach, Benders decomposition, Product selection, Assortment, Model, Algorithm, Sales, Management, Cuts, Retailing, Shelf space allocation, Rectangular display problem, Mixed-integer linear programming, Logic-based benders decomposition, 2-stage algorithm, Social sciences, Science & technology, Technology, Management, Business & economics, Operations research & management science