In the book Data science for COVID-19. Vol. 1. Computational perspectives
Academic Press, Cambridge, United States of America
Summary
The purpose of this paper is to present a proposal for scheduling shuttle ambulance vehicles assigned to COVID-19 patients using one of the discrete optimization techniques, namely, the multi-objective multiple 0–1 knapsack problem.
The scheduling aims at achieving the best utilization of the predetermined planning time slot; the best utilization is evaluated by maximizing the number of evacuated people who might be infected with the virus to the isolation hospital and maximizing the effectiveness of prioritizing the patients relative to their health status. The complete mathematical model for the problem is formulated including the representation of the decision variables, the problem constraints, and the multi-objective functions.
The proposed multi-objective multiple knapsack model is applied to an illustrated case study in Cairo, Egypt, the case study aims at improving the scheduling of ambulance vehicles in the back and forth shuttle movements between patient’ locations and the isolation hospital. The case study is solved using a novel Discrete Binary Gaining-Sharing knowledge-based optimization algorithm (DBGSK). The detail procedure of the novel DBGSK is presented along with the complete steps for solving the case study.
Keywords: Binary Gaining-Sharing knowledge-based optimization; COVID-19 quarantine cases; Metaheuristics; Multi-objective Multiple Knapsack Problem; Scheduling shuttle ambulance
ISBN: 978-0-12-824536-1
DOI: https://doi.org/10.1016/B978-0-12-824536-1.00034-4
DOI of the book: https://doi.org/10.1016/C2020-0-01677-4
Published: 2021
Citation:
S.A. Hassan, P. Agrawal, T. Ganesh, A.W. Mohamed, Scheduling shuttle ambulance vehicles for COVID-19 quarantine cases, a multi-objective multiple 0–1 knapsack model with a novel discrete binary gaining-sharing knowledge-based optimization algorithm, in Data science for COVID-19. Vol. 1. Computational perspectives. Ed. Academic Press. Cambridge, United States of America, 2021.
IIT-21-260L