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Decomposition of the Knapsack Problem for Increasing the Capacity of Operating Rooms

Author

Listed:
  • Alexander Alekseevich Lazarev

    (Institute of Control Sciences, 65 Profsoyuznaya Street, 117997 Moscow, Russia)

  • Darya Vladimirovna Lemtyuzhnikova

    (Institute of Control Sciences, 65 Profsoyuznaya Street, 117997 Moscow, Russia
    Moscow Aviation Institute, 4, Volokolamskoe Shosse, 125993 Moscow, Russia)

  • Mikhail Lvovich Somov

    (Institute of Control Sciences, 65 Profsoyuznaya Street, 117997 Moscow, Russia)

Abstract

This paper is aimed at the problem of scheduling surgeries in operating rooms. To solve this problem, we suggest using some variation of the bin packing problem. The model is based on the actual operation of 10 operating rooms, each of which belongs to a specific department of the hospital. Departments are unevenly loaded, so operations can be moved to operating rooms in other departments. The main goal is to increase patient throughput. It is also necessary to measure how many operations take place in other departments with the proposed solution. The preferred solution is a solution with fewer such operations, all other things being equal. Due to the fact that the mixed-integer linear programming model turned out to be computationally complex, two approximation algorithms were also proposed. They are based on decomposition. The complexity of the proposed algorithms is estimated, and arguments are made regarding their accuracy from a theoretical point of view. To assess the practical accuracy of the algorithms, the Gurobi solver is used. Experiments were conducted on real historical data on surgeries obtained from the Burdenko Neurosurgical Center. Two decomposition algorithms were constructed and a comparative analysis was performed for 10 operating rooms based on real data.

Suggested Citation

  • Alexander Alekseevich Lazarev & Darya Vladimirovna Lemtyuzhnikova & Mikhail Lvovich Somov, 2022. "Decomposition of the Knapsack Problem for Increasing the Capacity of Operating Rooms," Mathematics, MDPI, vol. 10(5), pages 1-18, March.
    • Handle: RePEc:gam:jmathe:v:10:y:2022:i:5:p:784-:d:761580
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    References listed on IDEAS

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    1. Oleg V. Shylo & Oleg A. Prokopyev & Andrew J. Schaefer, 2013. "Stochastic Operating Room Scheduling for High-Volume Specialties Under Block Booking," INFORMS Journal on Computing, INFORMS, vol. 25(4), pages 682-692, November.
    2. Hans, Erwin & Wullink, Gerhard & van Houdenhoven, Mark & Kazemier, Geert, 2008. "Robust surgery loading," European Journal of Operational Research, Elsevier, vol. 185(3), pages 1038-1050, March.
    3. Bahman Naderi & Vahid Roshanaei & Mehmet A. Begen & Dionne M. Aleman & David R. Urbach, 2021. "Increased Surgical Capacity without Additional Resources: Generalized Operating Room Planning and Scheduling," Production and Operations Management, Production and Operations Management Society, vol. 30(8), pages 2608-2635, August.
    4. Şeyda Gür & Tamer Eren & Hacı Mehmet Alakaş, 2019. "Surgical Operation Scheduling with Goal Programming and Constraint Programming: A Case Study," Mathematics, MDPI, vol. 7(3), pages 1-24, March.
    5. Shuwan Zhu & Wenjuan Fan & Shanlin Yang & Jun Pei & Panos M. Pardalos, 2019. "Operating room planning and surgical case scheduling: a review of literature," Journal of Combinatorial Optimization, Springer, vol. 37(3), pages 757-805, April.
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