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Andy Ruina

Mechanical Engineering · Cornell University  high

🏠 教授主页iD ORCID

研究方向

方向提炼待补(distill 阶段生成)。

该校申请信息 · Cornell University

ME deadline(legacy)
申请费

近三年论文 · 4 篇 (点击展开摘要,时间倒序)

Descriptive Model-based Learning and Control for Bipedal Locomotion
arXiv (Cornell University) · 2025 · cited 0 · doi.org/10.48550/arxiv.2511.00512
Bipedal balance is challenging due to its multi-phase, hybrid nature and high-dimensional state space. Traditional balance control approaches for bipedal robots rely on low-dimensional models for locomotion planning and reactive control, constraining the full robot to behave like these simplified models. This involves tracking preset reference paths for the Center of Mass and upper body obtained through low-dimensional models, often resulting in inefficient walking patterns with bent knees. However, we observe that bipedal balance is inherently low-dimensional and can be effectively described with simple state and action descriptors in a low-dimensional state space. This allows the robot's motion to evolve freely in its high-dimensional state space, only constraining its projection in the low-dimensional state space. In this work, we propose a novel control approach that avoids prescribing a low-dimensional model to the full model. Instead, our control framework uses a descriptive model with the minimum degrees of freedom necessary to maintain balance, allowing the remaining degrees of freedom to evolve freely in the high-dimensional space. This results in an efficient human-like walking gait and improved robustness.
Author response for "Toothpicks and toy football players: frictional jamming causes locomotion of vertically-shaken asymmetrical objects"
Author response for "Toothpicks and toy football players: frictional jamming causes locomotion of vertically-shaken asymmetrical objects"
Toothpicks and toy football players: frictional jamming causes locomotion of vertically-shaken assymetrical objects
Soft Matter · 2025 · cited 0 · doi.org/10.1039/d4sm01408a
Frictional jamming enables vertically shaken asymmetrical objects to move. The circular motion of toothpicks in a jar under vertical shakes clearly demonstrates this concept.