Основні поняття
This paper introduces a novel control framework that leverages Nonlinear Model Predictive Control (NMPC) and Exponential Control Barrier Functions (ECBF) to achieve safe and efficient dynamic motion planning in vision-based human-robot collaboration tasks.
Анотація
Bibliographic Information:
Zhang, D., Van, M., Sopasakis, P., & McLoone, S. (2024). An NMPC-ECBF Framework for Dynamic Motion Planning and Execution in Vision-based Human-Robot Collaboration. IEEE. (Submitted for publication)
Research Objective:
This paper addresses the challenge of ensuring safe and efficient human-robot collaboration (HRC) in dynamic environments, particularly focusing on integrating human motion prediction with real-time collision avoidance.
Methodology:
The researchers propose a two-level control framework:
- High-Level Controller: Employs NMPC to generate a collision-free trajectory for the robot to reach a predicted interactive position with the human, minimizing a cost function that considers tracking error and control effort.
- Low-Level Controller: Implements an ECBF-based safety filter to refine the NMPC-generated trajectory, guaranteeing collision avoidance even with potential prediction errors or disturbances.
The framework utilizes a vision system for human pose estimation and action recognition, feeding the data to a pre-trained motion prediction module. The GJK algorithm calculates minimum distances between the robot and predicted human poses for collision avoidance. The researchers validate their approach through simulations of a screw-driver usage task in CoppeliaSim, involving a 7-DOF Baxter robot and an OptiTrack motion capture system.
Key Findings:
- The proposed NMPC-ECBF framework successfully integrates human motion prediction into the robot control loop, enabling proactive and efficient collaboration.
- The ECBF safety filter effectively mitigates potential collisions arising from NMPC inaccuracies or unexpected human movements, ensuring operator safety.
- Simulations demonstrate a 23.2% reduction in task execution time compared to a non-predictive approach, highlighting the efficiency gains from incorporating human motion prediction.
Main Conclusions:
The research demonstrates the effectiveness of the NMPC-ECBF framework in achieving safe and efficient dynamic motion planning for HRC in realistic scenarios. The integration of human motion prediction significantly improves collaboration efficiency while maintaining safety compliance with ISO standards.
Significance:
This work contributes to the advancement of HRC by addressing the crucial aspect of safety in dynamic environments. The proposed framework has the potential to enable closer and more intuitive collaboration between humans and robots in various applications, including manufacturing, healthcare, and domestic assistance.
Limitations and Future Research:
- The current implementation focuses on a single human and a structured task. Future work could explore multi-human, multi-robot scenarios and more complex collaborative tasks.
- The study relies on a pre-trained motion prediction model. Investigating online adaptation and learning of human motion models could further enhance the framework's robustness and adaptability.
Статистика
The simulations demonstrate a 23.2% reduction in execution time for the HRC task when compared to an implementation without human motion prediction.
The capture space evaluated was based on typical use and had an extent of 2.5m × 3.5m × 2m = 17.5m3.
The human skeleton model generated has 32 joints, with joint data recorded at a sampling interval of 50 ms (i.e., 20 frames per second).
In this work, 4372 frames are used for training the vision module, while 1287 frames are used for testing.
Цитати
"To enable safe and effective human-robot collaboration (HRC) in smart manufacturing, seamless integration of sensing, cognition, and prediction into the robot controller is critical for real-time awareness, response, and communication inside a heterogeneous environment (robots, humans, and equipment)."
"This makes the approach applicable to real-world manufacturing."
"In this work, we not only perform path planning based on the predicted human motion but also develop a safety filter following the NMPC path planner to enhance the safety of human operators and ensure satisfaction with the ISO safety regulation."