Abstract
Multi-criteria inventory classification groups inventory items into classes, each of which is managed by a specific re-order policy according to its priority. However, the tasks of inventory classification and control are not carried out jointly if the classification criteria and the classification approach are not robustly established from an inventory-cost perspective. Exhaustive simulations at the single item level of the inventory system would directly solve this issue by searching for the best re-order policy per item, thus achieving the subsequent optimal classification without resorting to any multi-criteria classification method. However, this would be very time-consuming in real settings, where a large number of items need to be managed simultaneously.In this article, a reduction in simulation effort is achieved by extracting from the population of items a sample on which to perform an exhaustive search of best re-order policies per item; the lowest cost classification of in-sample items is, therefore, achieved. Then, in line with the increasing need for ICT tools in the production management of Industry 4.0 systems, supervised classifiers from the machine learning research field (i.e. support vector machines with a Gaussian kernel and deep neural networks) are trained on these in-sample items to learn to classify the out-of-sample items solely based on the values they show on the features (i.e. classification criteria). The inventory system adopted here is suitable for intermittent demands, but it may also suit non-intermittent demands, thus providing great flexibility. The experimental analysis of two large datasets showed an excellent accuracy, which suggests that machine learning classifiers could be implemented in advanced inventory classification systems.
Highlights
In this paper, we focus on classifying items for inventory control
This paper investigates the use of supervised machine learning classifiers as effective ICT tools for multi-criteria inventory classification (MCIC), in particular support vector machines with Gaussian kernel (SVM) and deep neural networks (DNN)
The use of a linear classifier in the final layer is common to DNN and SVM with the radial basis function kernel; both algorithms expand the features space and use linear classifiers to obtain non-linear classifications in the original space
Summary
We focus on classifying items for inventory control. When a classification framework is applied to inventories, it determines the importance of items and the level of controls placed on the items (Onwubolu and Dube 2006). Multi-criteria inventory classification A pioneering contribution on MCIC was provided by Flores et al (1992) They applied the Analytical Hierarchy Process (AHP) to classify items in terms of annual usage value (given by the product of the unit cost and the total annual demand), average unit cost, criticality, and the lead-time. A forecast-based periodic inventory control system is implemented, where the inventory status of each item is periodically reviewed and an order is placed to reach the order-up-to level Si,t This is dynamically computed with a model originally introduced by Syntetos et al (2010), where the aim is to reach a target service level tCSLi, assigned to single items as the probability of not incurring in a backorder during a replenishment cycle. This implies an inventory system constrained by a measure of service level, in particular the target service level
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