Adaptive Path Tracking Control of X-Rudder AUV Under Roll Constraints

Збережено в:

Бібліографічні деталі
Опубліковано в::	Journal of Marine Science and Engineering vol. 13, no. 9 (2025), p. 1778-1800
Автор:	Zhong Yaopeng
Інші автори:	Yuan Jianping, Wan, Lei, Zhou Zheyuan, Chen Qingdong
Опубліковано:	MDPI AG
Предмети:	Kinematics Accuracy Gravity Sea currents Ocean currents Mathematical models Roll Ecosystem disturbance Navigation Path tracking Tracking Line of sight Tracking problem State observers Autonomous underwater vehicles Rolling motion Linear quadratic regulator Lateral control Control algorithms Disturbances Tracking control Experiments Pitch (inclination) Controllers Effectiveness Deviation Underwater vehicles Rudders Stability Errors Constraints Environmental
Онлайн доступ:	Citation/Abstract Full Text + Graphics Full Text - PDF
Теги:	Додати тег Немає тегів, Будьте першим, хто поставить тег для цього запису!

MARC


LEADER	00000nab a2200000uu 4500
001	3254558463
003	UK-CbPIL
022			\|a 2077-1312
024	7		\|a 10.3390/jmse13091778 \|2 doi
035			\|a 3254558463
045	2		\|b d20250101 \|b d20251231
084			\|a 231479 \|2 nlm
100	1		\|a Zhong Yaopeng \|u Naval Architecture and Shipping College, Guangdong Ocean University, Zhanjiang 524088, China; yunechung86@163.com (Y.Z.);
245	1		\|a Adaptive Path Tracking Control of X-Rudder AUV Under Roll Constraints
260			\|b MDPI AG \|c 2025
513			\|a Journal Article
520	3		\|a This paper addresses the spatial path tracking problem of the X-rudder autonomous underwater vehicle (AUV) under random sea current disturbances. An adaptive line-of-sight guidance-linear quadratic regulator (ALOS-LQR) control strategy with roll constraints is proposed to enhance the tracking control accuracy and stability of the X-rudder AUV in such environments. First, to mitigate the roll-instability-induced depth and heading coupling deviations caused by unknown environmental disturbances, a roll-constrained linear quadratic regulator (LQR) heading-pitch control strategy is designed. Second, to handle random disturbances and model uncertainties, a nonlinear extended state observer (ESO) is employed to estimate dynamic disturbances. At the kinematic level, an adaptive line-of-sight guidance method (ALOS) is utilized to transform the path tracking problem into a heading and pitch tracking problem, while compensating in real time for kinematic deviations caused by time-varying sea currents. Finally, the effectiveness of the proposed control scheme is validated through simulation experiments and lake trials. The results confirm the effectiveness of the proposed method. Specifically, the roll-constrained ESO-LQR reduces lateral and longitudinal errors by 77.73% and 80.61%, respectively, compared to the roll-constrained LQR. ALOS navigation reduced lateral and longitudinal errors by 85.89% and 94.87%, respectively, compared to LOS control, while exhibiting faster convergence than ILOS. In physical experiences, roll control reduced roll angle by 50.52% and depth error by 33.3%. Results demonstrate that the proposed control strategy significantly improves the control accuracy and interference resistance of the X-rudder AUV, exhibiting excellent accuracy and stability.
653			\|a Kinematics
653			\|a Accuracy
653			\|a Gravity
653			\|a Sea currents
653			\|a Ocean currents
653			\|a Mathematical models
653			\|a Roll
653			\|a Ecosystem disturbance
653			\|a Navigation
653			\|a Path tracking
653			\|a Tracking
653			\|a Line of sight
653			\|a Tracking problem
653			\|a State observers
653			\|a Autonomous underwater vehicles
653			\|a Rolling motion
653			\|a Linear quadratic regulator
653			\|a Lateral control
653			\|a Control algorithms
653			\|a Disturbances
653			\|a Tracking control
653			\|a Experiments
653			\|a Pitch (inclination)
653			\|a Controllers
653			\|a Effectiveness
653			\|a Deviation
653			\|a Underwater vehicles
653			\|a Rudders
653			\|a Stability
653			\|a Errors
653			\|a Constraints
653			\|a Environmental
700	1		\|a Yuan Jianping \|u Naval Architecture and Shipping College, Guangdong Ocean University, Zhanjiang 524088, China; yunechung86@163.com (Y.Z.);
700	1		\|a Wan, Lei \|u College of Shipbuilding Engineering, Harbin Engineering University, Harbin 150001, China
700	1		\|a Zhou Zheyuan \|u Hangzhou Applied Acoustics Research Institute, Hangzhou 310000, China
700	1		\|a Chen Qingdong \|u Naval Architecture and Shipping College, Guangdong Ocean University, Zhanjiang 524088, China; yunechung86@163.com (Y.Z.);
773	0		\|t Journal of Marine Science and Engineering \|g vol. 13, no. 9 (2025), p. 1778-1800
786	0		\|d ProQuest \|t Engineering Database
856	4	1	\|3 Citation/Abstract \|u https://www.proquest.com/docview/3254558463/abstract/embedded/H09TXR3UUZB2ISDL?source=fedsrch
856	4	0	\|3 Full Text + Graphics \|u https://www.proquest.com/docview/3254558463/fulltextwithgraphics/embedded/H09TXR3UUZB2ISDL?source=fedsrch
856	4	0	\|3 Full Text - PDF \|u https://www.proquest.com/docview/3254558463/fulltextPDF/embedded/H09TXR3UUZB2ISDL?source=fedsrch