Quadrupedal Walking over Complex Terrain with a Quasi-Direct Drive Actuated Robot

Griffin, Robert; McCrory, Stephen; Bertrand, Sylvain; Calvert, Duncan; Lee, Inho; Stephen, Doug; Jasper, Jay; Karumanchi, Sisir; Kourchians, Ara; Emanuel, Blair; Holmes, Emma; Hegeman, Rachel; Pusey, Jason; Pratt, Jerry

doi:10.55417/fr.2022013

Cited by 2 publications

(3 citation statements)

References 45 publications

(69 reference statements)

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“…To this end, a custom control system that models the environment then plans and executes specific footholds was designed. This system is described very briefly here, and more completely in a companion paper (Griffin et al, 2021). The deliberative control system first models the environment by extracting planar regions from a lidar point cloud.…”

Section: Extended Autonomy Architecture For Deliberative Navigationmentioning

confidence: 99%

“…Left: Image of a rock field set up at Camp Lejeune. Right: Using the deliberative controller detailed in a companion paper(Griffin et al, 2021), the robot used lidar data to create a simplified model of the environment, then planned each footstep to traverse the obstacles using an A* planner. The robot then successfully walked over the blocks, up the curb, and onto the inclined concrete slope on the other side.…”

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confidence: 99%

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Lessons Learned from two iterations of LLAMA, an Electrically Powered, Dynamic Quadruped Robot

Jasper¹,

Kourchians²,

Gonzalez³

et al. 2022

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This paper presents the design, control, and initial performance from two iterations of human-scale (∼75 kg) quadrupedal robots built under the U.S. Army Research Laboratory (ARL) Robotics Collaborative Technology Alliance (RCTA) LLAMA (Legged Locomotion and Movement Adaptation) project. These all-electric, quadruped robots are designed with custom quasi-directdrive actuators powering 3-DOF, serial-parallel legs. To our knowledge, this is the first all-electric quadruped robot of this mass scale. The centralized energy management system uses a capacitor bank to supply burst loads and buffer regenerated energy. A hierarchical control scheme enables rapid motions (up to 1.8 m/s) over a variety of terrains. The onboard sensing suite enables deliberate, autonomous operation across rubble fields. In addition, we report on practical observations, lessons learned from field testing of two generations of the platform, and current drawbacks, such as low absolute payload (9 kg) and battery life (35 minutes). These lessons include strategies to address secondary effects at larger scales and parameters with the most impact to improve future designs.

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Section: Extended Autonomy Architecture For Deliberative Navigationmentioning

confidence: 99%

mentioning

confidence: 99%

Lessons Learned from two iterations of LLAMA, an Electrically Powered, Dynamic Quadruped Robot

Jasper¹,

Kourchians²,

Gonzalez³

et al. 2022

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“…The strategy described in this paper is founded on an implementation and adaptation of a DCM-based control architecture. The DCM concept has been applied to various types of robots, including bipeds [9][10][11][12][13][14], quadrupeds [15,16], and exoskeletons [17,18], and has been shown to be effective in achieving stable and dynamic locomotion. It has also been used in applications such as prosthetics and rehabilitation robotics, where maintaining balance and stability are critical for safe and effective movement.…”

Section: Introductionmentioning

confidence: 99%

Enhancement of humanoid robot locomotion on slippery floors using an adaptive controller

Almeida,

Santos,

Ferreira

2024

Robotica

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This paper presents a comprehensive strategy to improve the locomotion performance of humanoid robots on various slippery floors. The strategy involves the implementation and adaptation of a divergent component of motion (DCM) based control architecture for the humanoid NAO, and the introduction of an embedded yaw controller (EYC), which is based on a proportional-integral-derivative (PID) control algorithm. The EYC is designed not only to address the slip behavior of the robot on low-friction floors but also to tackle the issue of non-straight walking patterns that we observed in this humanoid, even on non-slippery floors. To fine-tune the PID gains for the EYC, a systematic trial-and-error approach is employed. We iteratively adjusted the P (Proportional), I (Integral), and D (Derivative) parameters while keeping the others fixed. This process allowed us to optimize the PID controller’s response to different walking conditions and floor types. A series of locomotion experiments are conducted in a simulated environment, where the humanoid step frequency and PID gains are varied for each type of floor. The effectiveness of the strategy is evaluated using metrics such as robot stability, energy consumption, and task duration. The results of the study demonstrate that the proposed approach significantly improves humanoid locomotion on different slippery floors, by enhancing stability and reducing energy consumption. The study has practical implications for designing more versatile and effective solutions for humanoid locomotion on challenging surfaces and highlights the adaptability of the existing controller for different humanoid robots.

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Quadrupedal Walking over Complex Terrain with a Quasi-Direct Drive Actuated Robot

Cited by 2 publications

References 45 publications

Lessons Learned from two iterations of LLAMA, an Electrically Powered, Dynamic Quadruped Robot

Lessons Learned from two iterations of LLAMA, an Electrically Powered, Dynamic Quadruped Robot

Enhancement of humanoid robot locomotion on slippery floors using an adaptive controller

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