Projects per year
Abstract
Nonlinear systems, such as robotic systems, play an increasingly important role in our modern daily life and have become more dominant in many industries; however, robotic control still faces various challenges due to diverse and unstructured work environments. This article proposes a double-loop recurrent neural network (DLRNN) with the support of a Type-2 fuzzy system and a self-organizing mechanism for improved performance in nonlinear dynamic robot control. The proposed network has a double-loop recurrent structure, which enables better dynamic mapping. In addition, the network combines a Type-2 fuzzy system with a double-loop recurrent structure to improve the ability to deal with uncertain environments. To achieve an efficient system response, a self-organizing mechanism is proposed to adaptively adjust the number of layers in a DLRNN. This work integrates the proposed network into a conventional sliding mode control (SMC) system to theoretically and empirically prove its stability. The proposed system is applied to a three-joint robot manipulator, leading to a comparative study that considers several existing control approaches. The experimental results confirm the superiority of the proposed system and its effectiveness and robustness in response to various external system disturbances.
Original language | English |
---|---|
Number of pages | 15 |
Journal | IEEE Transactions on Neural Networks and Learning Systems |
Early online date | 14 May 2024 |
DOIs | |
Publication status | E-pub ahead of print - 14 May 2024 |
Keywords
- Biological neural networks
- Control systems
- Double-loop recurrent neural network (DLRNN)
- Fuzzy logic
- Fuzzy sets
- neural network controller
- Recurrent neural networks
- Robots
- self-organizing neural network
- Type-2 fuzzy sets
- Vectors
Fingerprint
Dive into the research topics of 'Self-Organizing Type-2 Fuzzy Double Loop Recurrent Neural Network for Uncertain Nonlinear System Control'. Together they form a unique fingerprint.Projects
- 1 Active
-
Newton International Fellowship: Motion PLanning & Autonomous control for unmanned ariel manipulating
Shang, C. (PI)
15 Dec 2022 → 14 Dec 2024
Project: Externally funded research
Press/Media
-
Research Conducted at Xiamen University Has Provided New Information about Robotics (Self-organizing Type-2 Fuzzy Double Loop Recurrent Neural Network for Uncertain Nonlinear System Control)
17 Jun 2024
1 item of Media coverage
Press/Media: Media coverage