Picking is the process of retrieving products from inventory. It is mostly done manually by dedicated employees called pickers and is considered the most expensive of warehouse operations. To reduce the picking cost, customer orders can be grouped into batches that are then collected by traveling the shortest possible distance.
This work presents an exponential linear programming formulation to tackle the joint order batching and picker routing problem. Variables, or columns, are related to the picking routes in the warehouse. Computing such routess is generally an intractable routing problem and relates to the well known traveling salesman problem (TSP). Nonetheless, the rectangular warehouse's layouts can be used to efficiently solve the corresponding TSP and take into account in the development of an efficient subroutine, called oracle. We therefore investigate whether such an oracle allows for an effective exponential formulation. In order to tackle the exponential number of variables, we develop a column generation heuristic with performance guarantee. The pricing problem approximates the distances, and when finding a solution the oracle is used to get the optimal distance of this solution. The performance of the proposed column generation is strenghten using stabilization techniques and a rich column set.
Experimented on a publicly available benchmark, the algorithm proves to be very effective. It improves many of the best known solutions and provides very strong lower bounds. Finally, this approach is applied to another industrial case to demonstrate its interest for this field of application.
| Subject : | : | Abstracts |
| Topics | : | Special Session: Rich Routing and logistic (organized by GT2L) |
| Keywords | : | order batching ; picker routing ; column generation |
| PDF version | : |  PDF version |
