Task-specific Self-body Controller Acquisition by Musculoskeletal Humanoids: Application to Pedal Control in Autonomous Driving (2412.08270v1)

Abstract: The musculoskeletal humanoid has many benefits that human beings have, but the modeling of its complex flexible body is difficult. Although we have developed an online acquisition method of the nonlinear relationship between joints and muscles, we could not completely match the actual robot and its self-body image. When realizing a certain task, the direct relationship between the control input and task state needs to be learned. So, we construct a neural network representing the time-series relationship between the control input and task state, and realize the intended task state by applying the network to a real-time control. In this research, we conduct accelerator pedal control experiments as one application, and verify the effectiveness of this study.

• The paper introduces DDC-Net, a novel neural network to model the time-series relationship between control inputs and states in musculoskeletal humanoids.
• The paper validates its approach through accelerator pedal control experiments, demonstrating quicker convergence to target velocities compared to traditional PID controllers.
• The paper highlights the potential of task-specific self-body controllers in improving nuanced, human-like control dynamics for autonomous driving applications.

Task-specific Self-body Controller Acquisition for Musculoskeletal Humanoids

The paper proposes a method for task-specific self-body controller acquisition in musculoskeletal humanoids, specifically applied to pedal control in autonomous driving scenarios. The research addresses the challenge of modeling and control in complex musculoskeletal robots, focusing on improving their task realization capabilities by developing specialized self-body controllers.

Overview of Research Contributions

1. Control Input and State Relationship: The paper examines the intricate relationship between control input and state within musculoskeletal humanoids, emphasizing the complexities arising from under-actuated systems featuring highly flexible mechanical structures. This necessitates the development of specialized control strategies distinct from those used in traditional axis-driven humanoids.
2. DDC-Net (Dynamic Direct Control Network): A novel neural network architecture, DDC-Net, is introduced to model the time-series relationship between control inputs and task states. DDC-Net facilitates real-time task-specific control, enhancing the system's ability to solve the intermediary error issues present in complex control hierarchies.
3. Accelerator Pedal Control Experimentation: The paper applies the developed method to the autonomous driving task using the musculoskeletal humanoid Musashi. Through these experiments, the method's efficacy is validated, displaying quicker convergence to desired velocity targets compared to conventional PID-based approaches.

Methodological Insights

The methodology involves establishing DDC-Net as a function that predicts future task states based on the initial state and a sequence of control inputs. Through supervised learning using motion data gathered from random control inputs, DDC-Net enables fine-tuning and enhancement of control strategies without requiring manual adjustments of controller parameters like PID gains. The two-phased training and optimization process ensures the reduction of intermediate errors arising from layered control architectures.

Experimental Results and Implications

The results indicate that the proposed approach — marked by the use of random data to train DDC-Net — leads to significantly reduced convergence times to target velocities in autonomous driving scenarios. This improvement is evaluated against more traditional control approaches, illustrating how this task-specific control strategy could facilitate nuanced and human-like control dynamics in robotics applications.

Future Directions

The paper suggests several avenues for future research, including exploring the stability of neural network-based controllers in real-world autonomous driving conditions and extending the approach to more complex, multi-DOF tasks. Moreover, the incorporation of techniques like muscle synergy and AutoEncoder could help manage the increased complexity in high-dimensional control input spaces, enabling broader applicability across different robotic systems and tasks.

In conclusion, this paper provides compelling evidence towards the feasibility of task-specific self-body controller acquisition in musculoskeletal robots, potentially paving the way for more sophisticated robotics applications that demand intricate, human-like interaction with their environments. The advancement of this methodology could lead to significant strides in autonomous robotics, particularly in tasks requiring high degrees of flexibility and adaptability.