Affiliation:
1. College of IoT Engineering, Jiangsu Key Lab. of Power Transmission and Distribution Equipment Technology, Hohai University, Changzhou 213022, China
2. College of Mechanical and Electrical Engineering, Hohai University, Changzhou 213022, China
Abstract
This paper proposes a non-singular fast terminal sliding mode control (NFTSMC) method for micro gyroscopes with unknown uncertainty based on gated recurrent fuzzy neural networks (GRFNNs). First, taking advantage of non-singular fast terminal sliding control, a sliding hyperplane is designed with a nonlinear function to ensure that the tracking error of the system converges to zero within a specified finite time. Then, the unknown model parameters of the micro gyroscope are estimated using a GRFNN. Since the GRFNN can adaptively adjust the base width, center vector, gated recurrent unit parameters, and outer gains, it can achieve accurate approximation to unknown models, enhancing the robustness and accuracy. In addition, due to the introduction of gated recurrent units, The GRFNN can effectively utilize the previous data and avoid the problem of gradient disappearance. The comparison of the simulation results with traditional neural sliding mode control shows that the proposed method can achieve better tracking performance and more accurate estimation of unknown models.
Funder
the National Science Foundation of China
Subject
General Mathematics,Engineering (miscellaneous),Computer Science (miscellaneous)
Reference33 articles.
1. Adaptive control schemes applied to a control moment gyroscope of 2 degrees of freedom;Montoya;Mechatronics,2019
2. Fractional sliding mode control for micro gyroscope based on multilayer recurrent fuzzy neural network;Fei;IEEE Trans. Fuzzy Syst.,2022
3. Neural adaptive control for MEMS gyroscope with full-state constraints and quantized input;Shao;IEEE Trans. Ind. Inform.,2020
4. Harmonic disturbance observer-based sliding mode control of MEMS gyroscopes;Zhang;Sci. China Inf. Sci.,2022
5. Control of z-axis MEMS gyroscope using adaptive fractional order dynamic sliding mode approach;Wang;IEEE Access,2019