BLSTM-Based Adaptive Finite-Time Output-Constrained Control for a Class of AUSs with Dynamic Disturbances and Actuator Faults

Huang, Shiyi; Rong, Lulu; Chang, Xiaofei; Wang, Zheng; Zhang, Yuwei; Wei, Caisheng

doi:10.1155/2021/2221495

Cited by 4 publications

(1 citation statement)

References 58 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although the FBLS demonstrates good effectiveness and low computational cost, a major drawback is that its inherent feed-forward network structure limits its application to static problems. To enable dynamic mapping capabilities, Du et al (2021), Huang et al (2021) and Wang et al (2022) proposed a broad long short-term memory network and Hsu et al (2022) proposed a broad-learning recurrent Hermite neural network to enhance the learning process for modeling complex systems while maintaining the same width design as the BLS and FBLS.…”

Section: Introductionmentioning

confidence: 99%

Hermite broad-learning recurrent neural control with adaptive learning rate for nonlinear systems

Hsu,

Chen

2023

Soft Comput

View full text Add to dashboard Cite

Although conventional control systems are simple and widely used, they may not be effective for complex and uncertain systems. This study proposes a Hermite broad-learning recurrent neural network (HBRNN) to address such challenges. The HBRNN has a wide network structure and incorporates an internal feedback loop that enables fast learning and dynamic mapping. Furthermore, a Hermite broad-learning recurrent neural control (HBRNC) with the HBRNN as the main controller is proposed. All the network parameters of the HBRNN are updated online according to parameter learning laws through the gradient descent approach. To prevent network parameter overtraining of the HBRNN, an adaptive learning rate (ALR) is established using a discrete-type Lyapunov function to determine the least upper bound for the learning rate. The ALR can dynamically adjust the learning rates within specified ranges during the training process, thus achieving an appropriate balance between convergence speed and system stability. Finally, the HBRNC system with ALR is applied to a chaotic circuit and a reaction wheel pendulum, and its effectiveness is validated through simulation and experimentation.

show abstract

Section: Introductionmentioning

confidence: 99%