Estimating Dynamic Soft Continuum Robot States From Boundaries

Accurate state estimation is essential for effective control of robots. For soft robots, this task is particularly challenging because their states are inherently infinite-dimensional functions due to the robots' continuous deformability. Traditional sensing techniques, however, can only provide discrete measurements. Recently, a dynamic state estimation method known as a boundary observer was introduced, which leverages Cosserat rod theory to recover all infinite-dimensional states by measuring only the velocity twist at the robot's tip. In this work, we present a novel boundary observer that can also recover infinite-dimensional dynamic states, but instead relies on measuring the internal wrench at the robot's base. This design exploits the duality between the velocity twist at the tip and the internal wrench at the base, with both types of boundary observers being inspired by principles of energy dissipation. Despite the mathematical duality, the proposed approach offers a distinct advantage: it requires only a 6-axis force/torque sensor embedded at the base, eliminating the need for external sensing systems such as motion capture cameras. Moreover, combining both tip- and base-based techniques enhances energy dissipation, accelerates convergence, and improves estimation accuracy. We validate the proposed algorithms through both simulation studies and experiments based on tendon-driven continuum robots. Our results demonstrate that all boundary observers converge to the ground truth within 3 seconds, even with significantly deviated initial conditions. Furthermore, they recover from unknown perturbations and effectively track high-frequency vibrations. We also show that combining the dual techniques further improves convergence speed and accuracy. Finally, the computational efficiency of these algorithms indicates their feasibility for real-time state estimation.

@article{zheng2025_2505.04491,
  title={ Estimating Dynamic Soft Continuum Robot States From Boundaries },
  author={ Tongjia Zheng and Jessica Burgner-Kahrs },
  journal={arXiv preprint arXiv:2505.04491},
  year={ 2025 }
}