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Abstract

The electric braking system is one of the most critical subsystems for more electric aircraft. Compared to traditional hydraulic brakes, the electric brake responds faster. However, this can cause large oscillations in the deceleration rate. Such variations may result in an unpleasant experience for passengers. In this paper, motion sickness is modeled for deceleration planning with a focus on passengers’ comfort. The proposed planning method consists of two components: an offline planner based on optimization and an online planner that incorporates motion sickness incidence prediction feedforward. Furthermore, a comprehensive aircraft anti-skid braking control strategy is presented, which includes reference wheel slip rate control, braking pressure control using sliding mode-active disturbance rejection, and electric actuator servo control. Simulations are conducted to evaluate braking safety and passenger comfort under nonlinear factors and parameter uncertainties. The proposed algorithm demonstrates rapid tracking of the reference slip ratio and achieves a significant reduction in motion sickness incidence compared to traditional control methods, with up to a 74.3% reduction in motion sickness.

Keywords

Electric braking motion sickness subjective vertical conflict SM-ADRC ride comfort

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References

Allred

Torin

(2024) A computational model of motion sickness dynamics during passive self-motion in the dark. Experimental Brain Research 242(5): 1127–1148.

Asua

Gutiérrez-Zaballa

Mata-Carballeira

, et al. (2022) Analysis of the motion sickness and the lack of comfort in car passengers. Applied Sciences 12(8): 3717.

Bock

Oman

(1982) Dynamics of subjective discomfort in motion sickness as measured with a magnitude estimation method. Aviation Space & Environmental Medicine 53(8): 773–777.

Bos

Bles

(1998) Modelling motion sickness and subjective vertical mismatch detailed for vertical motions. Brain Research Bulletin 47(5): 537–542.

Buchheit

Schneider

Alayan

, et al. (2022) Motion sickness prediction in self-driving cars using the 6DOF-SVC model. IEEE Transactions on Intelligent Transportation Systems 23(8): 13582–13591.

Chen

Y-C

Duann

J-R

Shang-Wen

, et al. (2010) Spatial and temporal EEG dynamics of motion sickness. NeuroImage 49(3): 2862–2870.

Chen

Liang

, et al. (2021) MSD-based NMPC aircraft anti-skid brake control method considering runway variation. IEEE Access 9: 51793–51804.

Gowan

Griffith

(2001) Low-Speed Antiskid Control for Multigain Hydraulic Valve Brake System. Mountain View: Google Patents.

Grantham

Nguyen

Deal

(1974) Simulation of Decelerating Landing Approaches on an Externally Blown Flap STOL Transport Airplane. Washington, D.C.: NASA, Vol. 51, 13–15.

10.

Griffin

Mills

(2002) Effect of frequency and direction of horizontal oscillation on motion sickness. Aviation Space & Environmental Medicine 73(6): 537–543.

11.

Han

(1998) Auto disturbance rejection controller and it’s applications. Control and Decision 13(1): 19–23.

12.

Jia

Jiao

Sun

, et al. (2018) Aircraft anti-skid braking active disturbance rejection control based on optimal slip ratio. In: CSAA/IET International Conference on Aircraft Utility Systems (AUS 2018). New York City: IEEE, 1–6.

13.

Jiang

Mao

Wang

, et al. (2024) Improved antiskid braking control algorithm and system design for unmanned aerial vehicle. In: 2024 China Automation Congress (CAC). Qingdao, China: IEEE, 6284–6289.

14.

Jiao

Wang

Dong

, et al. (2021) A novel aircraft anti-skid brake control method based on runway maximum friction tracking algorithm. Aerospace Science and Technology 110: 106482.

15.

Jiao

Bai

Dong

, et al. (2023) Aircraft anti-skid braking control based on reinforcement learning. IEEE Transactions on Aerospace and Electronic Systems 59(6): 9219–9232.

16.

Kamiji

Kurata

Wada

Shun’ichi Doi (2007) Modeling and validation of carsickness mechanism. In: SICE Annual Conference 2007. New York City: IEEE, 1138–1143.

17.

Pacejka

Bakker

(1992) The magic formula tyre model. Vehicle System Dynamics 21(S1): 1–18.

18.

Qiao

Liu

Shi

, et al. (2018) A review of electromechanical actuators for more/all electric aircraft systems. Proceedings of the Institution of Mechanical Engineers - Part C: Journal of Mechanical Engineering Science 232(22): 4128–4151.

19.

Shao

Zheng

Tang

, et al. (2022) Barrier function based adaptive sliding mode control for uncertain systems with input saturation. IEEE 27(6): 4258–4268.

20.

Ukita

Okafuji

Wada

(2020) A simulation study on lane-change control of automated vehicles to reduce motion sickness based on a computational mode. In: 2020 IEEE International Conference on Systems, Man, and Cybernetics (SMC). New York City: IEEE, 1745–1750.

21.

Zhang

Wang

(2023) Implementation of three loop control for high-performance servo motor control using digital signal processors. Third International Conference on Control and Intelligent Robotics (ICCIR 2023) SPIE 12940: 53–60.

22.

Zhu

Huang

Zhao

(2023) Slipping analysis on the braking process of a commercial aircraft with the electric brake actuator. In: International Conference on Mechanical System Dynamics. Berlin: Springer, 4179–4190.

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Anti-skid braking control considering motion sickness for an aircraft with electric actuator

Abstract

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