핵심 개념
The author introduces a novel optimization-based control framework, CAFE-MPC, that strategically relaxes planning constraints for computational efficiency while unifying whole-body MPC and whole-body QPs.
초록
The content introduces the CAFE-MPC framework, which combines whole-body dynamics with SRB dynamics in a cascaded-fidelity approach. It addresses complex dynamic maneuvers and gymnastic-style motions on legged robots by optimizing loco-motion control. The framework aims to achieve highly dynamic behaviors efficiently by transitioning between high-fidelity and low-fidelity models along the prediction horizon.
Key points include:
- Introduction of CAFE-MPC for complex dynamic maneuvers on legged robots.
- Utilization of whole-body dynamics and SRB dynamics in a cascaded-fidelity model predictive control approach.
- Focus on achieving highly dynamic behaviors efficiently through model transitions.
- Emphasis on relaxation of constraints for computational efficiency while maintaining performance.
- Integration of different models to optimize locomotion control for challenging tasks like gymnastic-style motions.
- Application of multiple-shooting iLQR solver tailored for hybrid systems in numerical optimization.
The content discusses the challenges in achieving biological-level mobility on legged robots and presents an innovative solution through the CAFE-MPC framework, showcasing advancements in robotics control techniques.
통계
The proposed integration time steps are dtw = 10 ms for whole-body dynamics and dts = 50 ms for SRB dynamics (Section IV).
The stabilization time constant α = 10 is used in Eq. (20) to mitigate non-slip constraint violations (Section IV).