Traversing Steep and Granular Martian Analog Slopes With a Dynamic Quadrupedal Robot

Kolvenbach, Hendrik; Arm, Philip; Hampp, Elias; Dietsche, Alexander; Bickel, Valentin Tertius; Sun, Benjamin; Meyer, Christoph; Hutter, Marco

doi:10.48550/arxiv.2106.01974

Cited by 3 publications

(3 citation statements)

References 33 publications

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“…Hendrik [46] explored a 22 kg quadruped robot exploits lunar gravity conditions to perform energy-efficient jumps. The robot achieves repetitive, vertical jumps of more than 0.9 m and powerful single leaps of up to 1.3 m. Kolvenbach [47] presented experimental work on traversing steep, granular slopes with the dynamically walking quadrupedal robot.…”

Section: Legged Type Ugv Platformmentioning

confidence: 99%

State of the art and future trends in obstacle-surmounting unmanned ground vehicle configuration and dynamics

Yue

Zheng

et al. 2023

Robotica

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This article presents a review of the platform configuration and dynamic of obstacle-surmounting unmanned ground vehicles (UGVs). For now, unmanned systems have emerged as a result of the rapid advancement of artificial intelligence and modern manufacturing techniques both domestically and internationally. The research on unmanned systems has been improved a lot. The UGV platform can execute transportation, recurring, and military tasks independently. For the high-level self-control, adaption, and maneuverability abilities, the UGV platform has been applied in the military, industry, and other special fields widely. The UGV platform usually performs tasks in an unstructured environment, so the all-terrain performance becomes a key factor restricting their operating efficiency and reliability. A brief literature review of the UGV platform is carried out in this article.

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Section: Legged Type Ugv Platformmentioning

confidence: 99%

State of the art and future trends in obstacle-surmounting unmanned ground vehicle configuration and dynamics

Yue

Zheng

et al. 2023

Robotica

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“…Because a large portion of the terrestrial surface is covered by nonrigid substrates, such as sand, soil, and vegetation, locomotion on soft terrains is a necessary skill for many applications of legged robots. At the same time, traversing such terrain is more suited to legged locomotion as opposed to wheeled mobility, which often encounters sinkage and slippages (1). Because soft earthy substrates might yield even under a small load, legged robots should be able to adapt to different terrain characteristics as they feel the terrain, as animals do (2)(3)(4).…”

Section: Introductionmentioning

confidence: 99%

Learning quadrupedal locomotion on deformable terrain

Choi

Park

et al. 2023

Sci. Robot.

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Simulation-based reinforcement learning approaches are leading the next innovations in legged robot control. However, the resulting control policies are still not applicable on soft and deformable terrains, especially at high speed. The primary reason is that reinforcement learning approaches, in general, are not effective beyond the data distribution: The agent cannot perform well in environments that it has not experienced. To this end, we introduce a versatile and computationally efficient granular media model for reinforcement learning. Our model can be parameterized to represent diverse types of terrain from very soft beach sand to hard asphalt. In addition, we introduce an adaptive control architecture that can implicitly identify the terrain properties as the robot feels the terrain. The identified parameters are then used to boost the locomotion performance of the legged robot. We applied our techniques to the Raibo robot, a dynamic quadrupedal robot developed in-house. The trained networks demonstrated high-speed locomotion capabilities on deformable terrains: The robot was able to run on soft beach sand at 3.03 meters per second although the feet were completely buried in the sand during the stance phase. We also demonstrate its ability to generalize to different terrains by presenting running experiments on vinyl tile flooring, athletic track, grass, and a soft air mattress.

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“…However, its reliance on NVIDIA's GPU-accelerated physics simulation may pose challenges for researchers lacking access to compatible hardware with sufficient GPU compute power. This limitation can hinder the training and testing of RL-based locomotion strategies within Isaac Sim, especially for resource-constrained environments.1.2 Sim-to-Real Transfer for RL-based StrategiesSim-to-Real transfer in the context of RL-based locomotion strategies represents a critical frontier in robotics research, aiming to bridge the gap between simulated environments and real-world deployment[31] [18]. The ability to develop locomotion controllers in simulation and transfer them seamlessly to physical robots is of paramount importance for practical applications in challenging terrains and dynamic environments.…”

mentioning

confidence: 99%

Reinforcement learning-based model matching in COBRA, a slithering snake robot

Nallaguntla

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Thesis ixI am deeply thankful to Dr. Alireza Ramezani, my advisor, for his unwavering support and guidance throughout the completion of this thesis. I would also like to extend my gratitude to Dr. Gunar Schirner, my co-advisor, whose invaluable insights were crucial in shaping this work. I also express my appreciation to my fellow lab mates, including Adarsh, Kruthika, Aditya, and others, for their invaluable assistance in conducting physical testing, handling hardware components, and contributing to the formulation of solutions to challenges. Finally, I express my gratitude for my family, whose unwavering belief in me has been the primary source of motivation throughout my journey marked by diligence and commitment.

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Traversing Steep and Granular Martian Analog Slopes With a Dynamic Quadrupedal Robot

Cited by 3 publications

References 33 publications

State of the art and future trends in obstacle-surmounting unmanned ground vehicle configuration and dynamics

State of the art and future trends in obstacle-surmounting unmanned ground vehicle configuration and dynamics

Learning quadrupedal locomotion on deformable terrain

Reinforcement learning-based model matching in COBRA, a slithering snake robot

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