Sage Journals: Discover world-class research

Abstract

To address the follower’s state acquisition issue during communication intervals under weak underwater communication and improve formation accuracy, this paper introduces a virtual target to establish a dynamic coupling between the leader and the follower. The trajectory mapping characteristics of the virtual target are used to enable the follower to accurately track the desired formation in a nonlinear motion environment, which provides theoretical support and a technical path for complex formation control problems. A trajectory tracking controller is designed by using the filter backstepping method, aiming at the high-order derivative problem in the backstepping method, the virtual control quantity is taken as the input of the second-order filter, the virtual control quantity and its derivative are estimated through the second-order filter, and the estimated value is used as the actual control input of the UUV (underwater unmanned vehicle) and the derivative of the virtual control quantity is obtained by the integration method, which avoids the “differential explosion” phenomenon in the traditional method and reduces the computational complexity. The proposed method effectively resolves communication delays and cycle constraints by considering communication limitations, actuator dynamics, and input restrictions. Simulation results show the controller’s effectiveness and robustness.

Keywords

UUV formation control communication constraints virtual goals cooperative target tracking

Get full access to this article

View all access options for this article.

References

Alattas

Mofid

, et al. (2022) Adaptive nonsingular terminal sliding mode control for performance improvement of perturbed nonlinear systems. Mathematics 10(7): 1064.

Barbeau

Blouin

Traboulsi

(2024) Adaptable design for long range underwater communications. Wireless Networks 30(5): 4459–4475.

Chen

Zhao

, et al. (2022) Finite-time observer based tracking control of uncertain heterogeneous underwater vehicles using adaptive sliding mode approach. Neurocomputing 481: 322–332.

Ding

Wang

Zhang

, et al. (2024) Real-time trajectory planning and tracking control of bionic underwater robot in dynamic environment. Cyborg Bionic Systems 5: 0112.

Chai

Xiang

, et al. (2022) Cooperative localization of UUVs with decentralized method based on underwater weak communication. In: 13th China Satellite Navigation Conference (CSNC)—Digital Economy and Intelligent Navigation, Beijing, China. Singapore: Springer-Verlag.

Gong

, et al. (2023) Multi-agent perception via co-attentive communication mechanism. In: 6th Chinese Conference on Pattern Recognition and Computer Vision (PRCV), Xiamen University, Xiamen, China. Singapore: Springer-Verlag.

Guo

Wei

Zhang

, et al. (2025) Formation control of multiple marine vessels based on disturbance observer. Ships and Offshore Structures: 10.

Liang

Cao

(2021) Decentralized adaptive flocking control algorithm with avoiding collision and preserving connectivity for crowded UUV swarm with uncertainties and input saturation. Ocean Engineering 237: 109545.

Liang

Wang

Chen

, et al. (2022) Formation control for discrete-time heterogeneous multi-agent systems. International Journal of Robust and Nonlinear Control 32(10): 5848–5865.

10.

Menaka

Gauni

Manimegalai

, et al. (2022) Challenges and vision of wireless optical and acoustic communication in underwater environment. International Journal of Communication Systems 35(12): e5227.

11.

Pettersen

Egeland

(1999) Time-varying exponential stabilization of the position and attitude of an underactuated autonomous underwater vehicle. IEEE Transactions on Automatic Control 44(1): 112–115.

12.

Tao

Guan

, et al. (2018) The research of coordination control on distributed multi-agent. In: 33Rd Youth Academic Annual Conference of Chinese Association of Automation (YAC), Nanjing, China. New York: IEEE.

13.

Wang

Sun

, et al. (2024) Multi-agent dynamic formation interception control based on rigid graph. Complex & Intelligent Systems 10(4): 5585–5598.

14.

Wang

Dong

Chen

, et al. (2023) Formation control of non-holonomic mobile robots: Predictive data-driven fuzzy compensator. Mathematics 11(8): 1804.

15.

Wang

Liu

Zhang

, et al. (2022) Synchronization for mini-UAV-based high-resolution BiSAR systems: Lost direct signal estimation based on Hampel filtering. Electronics Letters 58(21): 807–809.

16.

Wen

Chen

Feng

, et al. (2017) Optimized multi-agent formation control based on an identifier–actor–critic reinforcement learning algorithm. IEEE Transactions on Fuzzy Systems 26(5): 2719–2731.

17.

Weng

Matsuda

Maki

, et al. (2023) Improving the quality of underwater wireless optical communications in uncertain ocean environments. In: IEEE International Symposium on Underwater Technology (UT), University of Tokyo, Komaba Campus, Tokyo, Japan. New York: IEEE.

18.

Luan

Jia

, et al. (2023) Cooperative obstacle avoidance method of multiple unmanned underwater vehicles based on improved artificial potential field method. In: 35th Chinese Control and Decision Conference (CCDC), Yichang, China. New York: IEEE.

19.

Yan

Yang

, et al. (2023) Formation control of multiple autonomous underwater vehicles: A review. Intelligence & Robotics 3(1): 1–22.

20.

Yan

Jiang

Lai

(2022) Adaptive formation control of unmanned underwater vehicles with collision avoidance under unknown disturbances. Journal of Marine Science and Engineering 10(4): 516.

21.

Yan

, et al. (2021) Underwater photon-inter-correlation optical communication. Photonics Research 9(12): 2360–2368.

22.

Yang

Xiao

(2021) A survey of autonomous underwater vehicle formation: Performance, formation control, and communication capability. IEEE Communications Surveys 23(2): 815–841.

23.

Zhu

Yan

Yang

(2022) Motion planning and tracking control of unmanned underwater vehicles: Technologies, challenges and prospects. Intelligence & Robotics 2(3): 220–222.

Research on formation control method of multi-underwater unmanned vehicle under weak communication conditions

Abstract

Keywords

Get full access to this article

References