Learning-Based Dynamics Modeling and Robust Control for Tendon-Driven Continuum Robots
Ziqing Zou, Ke Qiu, Fei Wang, Haojian Lu, Rong Xiong + 1 more
TLDR
This paper presents a differentiable learning framework for robust control of tendon-driven continuum robots, overcoming complex nonlinearities.
Key contributions
- Developed a differentiable learning framework for TDCR dynamics and robust neural control.
- Introduced a GRU-based dynamics model with residual prediction to suppress compounding errors.
- Optimized an end-to-end neural control policy via backpropagation for nonlinearity compensation.
- Demonstrated accurate tracking and superior robustness on a physical TDCR, eliminating oscillations.
Why it matters
Complex nonlinearities make tendon-driven continuum robots difficult to control. This paper proposes a robust learning framework combining high-fidelity dynamics and neural control, significantly improving tracking accuracy and stability for reliable robot applications.
Original Abstract
Tendon-Driven Continuum Robots (TDCRs) pose significant modeling and control challenges due to complex nonlinearities, such as frictional hysteresis and transmission compliance. This paper proposes a differentiable learning framework that integrates high-fidelity dynamics modeling with robust neural control. We develop a GRU-based dynamics model featuring bidirectional multi-channel connectivity and residual prediction to effectively suppress compounding errors during long-horizon auto-regressive prediction. By treating this model as a gradient bridge, an end-to-end neural control policy is optimized through backpropagation, allowing it to implicitly internalize compensation for intricate nonlinearities. Experimental validation on a physical three-section TDCR demonstrates that our framework achieves accurate tracking and superior robustness against unseen payloads, outperforming Jacobian-based methods by eliminating self-excited oscillations.
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