TY - GEN
T1 - A Dynamic Programming-Based Real-Time Predictive Optimal Gear Shift Strategy for Conventional Heavy-Duty Vehicles
AU - Xu, Chu
AU - Al-Mamun, Abdullah
AU - Geyer, Stephen
AU - Fathy, Hosam K.
N1 - Funding Information:
ACKNOWLEDGMENTS This work was funded by the ARPA-E NEXTCAR program. The authors gratefully acknowledge this support. Furthermore, assistance, support, and extensive collaboration from Volvo Group North America in the simulation-based analyses included in this paper is gratefully acknowledged by the paper’s university-based authors.
Publisher Copyright:
© 2018 AACC.
PY - 2018/8/9
Y1 - 2018/8/9
N2 - This paper examines the problem of utilizing upcoming terrain and vehicle speed predictions for gear shift trajectory optimization in conventional heavy-duty vehicles. The paper is motivated by the fuel savings potential of such optimization, especially in connected and automated heavy-duty trucks. A key goal of this work is to develop a computationally tractable online shifting algorithm with a fuel saving potential approaching that of existing offline global optimization methods from the literature. We consider two optimization objectives, namely, fuel consumption and gear shift frequency. We use dynamic programming to navigate the Pareto tradeoff between these objectives offline, for known vehicle duty cycles. The resulting gear shift trajectories collapse to an instantaneous shift map in the Pareto limit where fuel consumption minimization is the sole objective. We construct a neural network that anticipates the upcoming Pareto-optimal gear shift decision, given a sequence of gear shifts deemed ideal by the simple, instantaneous Pareto-limit shift map. We train this neural network using mix of urban, suburban, and highway drive cycles. The neural network reduces fuel consumption by 0.43%-4.16% in simulation, compared to a benchmark rule-based gear shift strategy.
AB - This paper examines the problem of utilizing upcoming terrain and vehicle speed predictions for gear shift trajectory optimization in conventional heavy-duty vehicles. The paper is motivated by the fuel savings potential of such optimization, especially in connected and automated heavy-duty trucks. A key goal of this work is to develop a computationally tractable online shifting algorithm with a fuel saving potential approaching that of existing offline global optimization methods from the literature. We consider two optimization objectives, namely, fuel consumption and gear shift frequency. We use dynamic programming to navigate the Pareto tradeoff between these objectives offline, for known vehicle duty cycles. The resulting gear shift trajectories collapse to an instantaneous shift map in the Pareto limit where fuel consumption minimization is the sole objective. We construct a neural network that anticipates the upcoming Pareto-optimal gear shift decision, given a sequence of gear shifts deemed ideal by the simple, instantaneous Pareto-limit shift map. We train this neural network using mix of urban, suburban, and highway drive cycles. The neural network reduces fuel consumption by 0.43%-4.16% in simulation, compared to a benchmark rule-based gear shift strategy.
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U2 - 10.23919/ACC.2018.8430948
DO - 10.23919/ACC.2018.8430948
M3 - Conference contribution
AN - SCOPUS:85052581608
SN - 9781538654286
T3 - Proceedings of the American Control Conference
SP - 5528
EP - 5535
BT - 2018 Annual American Control Conference, ACC 2018
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2018 Annual American Control Conference, ACC 2018
Y2 - 27 June 2018 through 29 June 2018
ER -