Subventions et des contributions :

Subvention ou bourse octroyée s'appliquant à plus d'un exercice financier. (2017-2018 à 2022-2023)

In dynamic scheduling problems, the aim is to optimally assign arriving jobs (e.g., product orders in manufacturing; patients in healthcare) to resources (e.g., machines in manufacturing; nurses in healthcare) over time in a continuously-changing environment (e.g., machines break down; new more urgent patients arrive).

While many optimization methods for scheduling have been proposed and implemented in scheduling software, in practice the resulting ‘optimal’ schedules are not necessarily acceptable to the end users. Frequently, the schedules are manually modified before implementation, and, if the schedules repeatedly do not meet user expectations, the software itself might be discarded. The main premise of this proposal is that the true characteristics of the system and user preferences are captured by the data collected about the problem and its past (implemented) solutions, and that as a result the mismatch between the schedules created by software and those desired by the user can be reduced or eliminated through data-driven modelling.

Modern information systems are capable of collecting data on past job and resource characteristics (e.g., arrival times, processing times), real-time system status updates (e.g., number of jobs currently in the system), and past scheduling decisions (e.g., decisions made by managers in the past). Traditionally, each of these data sources has been considered in isolation by distinct research areas, namely queueing theory, classical scheduling, and inverse scheduling, respectively.

My research program will leverage the availability of both historical and real-time system and preference data through the integration of combinatorial scheduling, queueing theory and inverse optimization techniques. The resulting hybrid scheduling models will capture system characteristics and user preferences better than traditional approaches, producing schedules that would be more readily accepted by the users. Thus, this research has the potential to increase the adoption of scheduling software in practice, which will in turn lead to greater productivity and efficiency of those systems.