Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue

Xiaoquan Gao; Nan Kong; Paul M. Griffin

doi:10.1109/WSC48552.2020.9384004

Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue

Xiaoquan Gao, Nan Kong, Paul M. Griffin

Marcus Department of Industrial and Manufacturing Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

3 Scopus citations

Abstract

Opioid overdose rescue is very time-sensitive. Hence, drone-delivered naloxone has the potential to be a transformative innovation due to its easily deployable and flexible nature. We formulate a Markov Decision Process (MDP) model to dispatch the appropriate drone after an overdose request arrives and to relocate the drone to its next waiting location after having completed its current task. Since the underlying optimization problem is subject to the curse of dimensionality, we solve it using ad-hoc state aggregation and evaluate it through a simulation with higher granularity. Our simulation-based comparative study is based on emergency medical service data from the state of Indiana. We compare the optimal policy resulting from the scaled-down MDP model with a myopic policy as the baseline. We consider the impact of drone type and service area type on outcomes, which offers insights into the performance of the MDP suboptimal policy under various settings.

Original language	English (US)
Title of host publication	Proceedings of the 2020 Winter Simulation Conference, WSC 2020
Editors	K.-H. Bae, B. Feng, S. Kim, S. Lazarova-Molnar, Z. Zheng, T. Roeder, R. Thiesing
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	830-841
Number of pages	12
ISBN (Electronic)	9781728194998
DOIs	https://doi.org/10.1109/WSC48552.2020.9384004
State	Published - Dec 14 2020
Event	2020 Winter Simulation Conference, WSC 2020 - Orlando, United States Duration: Dec 14 2020 → Dec 18 2020

Publication series

Name	Proceedings - Winter Simulation Conference
Volume	2020-December
ISSN (Print)	0891-7736

Conference

Conference	2020 Winter Simulation Conference, WSC 2020
Country/Territory	United States
City	Orlando
Period	12/14/20 → 12/18/20

All Science Journal Classification (ASJC) codes

Software
Modeling and Simulation
Computer Science Applications

Access to Document

10.1109/WSC48552.2020.9384004

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Gao, X., Kong, N., & Griffin, P. M. (2020). Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue. In K.-H. Bae, B. Feng, S. Kim, S. Lazarova-Molnar, Z. Zheng, T. Roeder, & R. Thiesing (Eds.), Proceedings of the 2020 Winter Simulation Conference, WSC 2020 (pp. 830-841). Article 9384004 (Proceedings - Winter Simulation Conference; Vol. 2020-December). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/WSC48552.2020.9384004

Gao, Xiaoquan ; Kong, Nan ; Griffin, Paul M. / Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue. Proceedings of the 2020 Winter Simulation Conference, WSC 2020. editor / K.-H. Bae ; B. Feng ; S. Kim ; S. Lazarova-Molnar ; Z. Zheng ; T. Roeder ; R. Thiesing. Institute of Electrical and Electronics Engineers Inc., 2020. pp. 830-841 (Proceedings - Winter Simulation Conference).

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title = "Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue",

abstract = "Opioid overdose rescue is very time-sensitive. Hence, drone-delivered naloxone has the potential to be a transformative innovation due to its easily deployable and flexible nature. We formulate a Markov Decision Process (MDP) model to dispatch the appropriate drone after an overdose request arrives and to relocate the drone to its next waiting location after having completed its current task. Since the underlying optimization problem is subject to the curse of dimensionality, we solve it using ad-hoc state aggregation and evaluate it through a simulation with higher granularity. Our simulation-based comparative study is based on emergency medical service data from the state of Indiana. We compare the optimal policy resulting from the scaled-down MDP model with a myopic policy as the baseline. We consider the impact of drone type and service area type on outcomes, which offers insights into the performance of the MDP suboptimal policy under various settings.",

author = "Xiaoquan Gao and Nan Kong and Griffin, {Paul M.}",

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Gao, X, Kong, N & Griffin, PM 2020, Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue. in K-H Bae, B Feng, S Kim, S Lazarova-Molnar, Z Zheng, T Roeder & R Thiesing (eds), Proceedings of the 2020 Winter Simulation Conference, WSC 2020., 9384004, Proceedings - Winter Simulation Conference, vol. 2020-December, Institute of Electrical and Electronics Engineers Inc., pp. 830-841, 2020 Winter Simulation Conference, WSC 2020, Orlando, United States, 12/14/20. https://doi.org/10.1109/WSC48552.2020.9384004

Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue. / Gao, Xiaoquan; Kong, Nan; Griffin, Paul M.
Proceedings of the 2020 Winter Simulation Conference, WSC 2020. ed. / K.-H. Bae; B. Feng; S. Kim; S. Lazarova-Molnar; Z. Zheng; T. Roeder; R. Thiesing. Institute of Electrical and Electronics Engineers Inc., 2020. p. 830-841 9384004 (Proceedings - Winter Simulation Conference; Vol. 2020-December).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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PY - 2020/12/14

Y1 - 2020/12/14

N2 - Opioid overdose rescue is very time-sensitive. Hence, drone-delivered naloxone has the potential to be a transformative innovation due to its easily deployable and flexible nature. We formulate a Markov Decision Process (MDP) model to dispatch the appropriate drone after an overdose request arrives and to relocate the drone to its next waiting location after having completed its current task. Since the underlying optimization problem is subject to the curse of dimensionality, we solve it using ad-hoc state aggregation and evaluate it through a simulation with higher granularity. Our simulation-based comparative study is based on emergency medical service data from the state of Indiana. We compare the optimal policy resulting from the scaled-down MDP model with a myopic policy as the baseline. We consider the impact of drone type and service area type on outcomes, which offers insights into the performance of the MDP suboptimal policy under various settings.

AB - Opioid overdose rescue is very time-sensitive. Hence, drone-delivered naloxone has the potential to be a transformative innovation due to its easily deployable and flexible nature. We formulate a Markov Decision Process (MDP) model to dispatch the appropriate drone after an overdose request arrives and to relocate the drone to its next waiting location after having completed its current task. Since the underlying optimization problem is subject to the curse of dimensionality, we solve it using ad-hoc state aggregation and evaluate it through a simulation with higher granularity. Our simulation-based comparative study is based on emergency medical service data from the state of Indiana. We compare the optimal policy resulting from the scaled-down MDP model with a myopic policy as the baseline. We consider the impact of drone type and service area type on outcomes, which offers insights into the performance of the MDP suboptimal policy under various settings.

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Gao X, Kong N, Griffin PM. Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue. In Bae KH, Feng B, Kim S, Lazarova-Molnar S, Zheng Z, Roeder T, Thiesing R, editors, Proceedings of the 2020 Winter Simulation Conference, WSC 2020. Institute of Electrical and Electronics Engineers Inc. 2020. p. 830-841. 9384004. (Proceedings - Winter Simulation Conference). doi: 10.1109/WSC48552.2020.9384004

Dynamic Optimization of Drone Dispatch for Substance Overdose Rescue

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