Team THOR's Entry in the DARPA Robotics Challenge Finals 2015

McGill, Stephen G.; Yi, Seung‐Joon; Yi, Hak; Ahn, Min Sung; Cho, Sang Hyun; Liu, Kevin; Sun, Daniel; Lee, Bhoram; Jeong, Heejin; Huh, Jinwook; Hong, Dennis; Lee, Daniel D.

doi:10.1002/rob.21672

Cited by 14 publications

(5 citation statements)

References 33 publications

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“…Therefore, researchers began to study series parallel hybrid mechanisms to solve the problem of defects in a single mechanism, while combining the advantages of both to enable the feet to more realistically simulate the driving mode of various joint muscles in the human leg, thereby achieving the effect of steady walking. At present, the SAFFiR robot [ 5 ], THOR robot [ 6 ], and 7-degree of freedom hybrid mechanical legs have all simulated real walking situations well and have a high degree of bionics.…”

Section: Introductionmentioning

confidence: 99%

Research on Walking Gait Planning and Simulation of a Novel Hybrid Biped Robot

Sun

Mao

et al. 2023

Biomimetics

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A kinematics analysis of a new hybrid mechanical leg suitable for bipedal robots was carried out and the gait of the robot walking on flat ground was planned. Firstly, the kinematics of the hybrid mechanical leg were analyzed and the applicable relevant models were established. Secondly, based on the preliminary motion requirements, the inverted pendulum model was used to divide the robot walking into three stages for gait planning: mid-step, start and stop. In the three stages of robot walking, the forward and lateral robot centroid motion trajectories and the swinging leg joint trajectories were calculated. Finally, dynamic simulation software was used to simulate the virtual prototype of the robot, achieving its stable walking on flat ground in the virtual environment, and verifying the feasibility of the mechanism design and gait planning. This study provides a reference for the gait planning of hybrid mechanical legged bipedal robots and lays the foundation for further research on the robots involved in this thesis.

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Section: Introductionmentioning

confidence: 99%

Research on Walking Gait Planning and Simulation of a Novel Hybrid Biped Robot

Sun

Mao

et al. 2023

Biomimetics

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“…We implemented a simple motion control structure to test the basic capability of the system, which is based on our previous software framework that have been used for a number position controlled bipedal robots [24]. We plan to adopt advanced quadruped motion control methods in the future, such as real-time model predictive control and active ground reaction force control [25].…”

Section: Motion Controlmentioning

confidence: 99%

Design and Control of a Open-Source, Low Cost, 3D Printed Dynamic Quadruped Robot

et al. 2021

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In this paper, we present a new open source dynamic quadruped robot, PADWQ (pronounced pa-dook), which features 12 torque controlled quasi direct drive joints with high control bandwidth, as well as onboard depth sensor and GPU-equipped computer that allows for a highly dynamic locomotion over uncertain terrains. In contrast to other dynamic quadruped robots based on custom actuator and machined metal structural parts, the PADWQ is entirely built from off the shelf components and standard 3D printed plastic structural parts, which allows for a rapid distribution and duplication without the need for advanced machining process. To make sure that the plastic structural parts can withstand the stress of dynamic locomotion, we performed finite element analysis (FEA) on leg structural parts as well as a continuous walking test using the physical robot, both of which the robot has passed successfully. We hope this work to help a wide range of researchers and engineers that need an affordable, highly capable and easily customizable quadruped robot.

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“…The DARPA Robotics Challenge (DRC) was one such competition including navigation and manipulation in human environments, which thereby greatly accelerated academic research in humanoid robotics. Unfortunately, due to the inherent instability of upright humanoid robot platforms and the high risk of hardware damage in cases of falling, most teams have decided to take a very conservative approach of minimizing autonomy and mostly focused on motion planning and control during the development [17,18].…”

Section: Related Workmentioning

confidence: 99%

Unified Software Platform for Intelligent Home Service Robots

Kang

Song

et al. 2020

Applied Sciences

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Although the mobile manipulation capability is crucial for a service robot to perform physical work without human support, the long-term autonomous operation of such a mobile manipulation robot in a real environment is still a tremendously difficult task. In this paper, we present a modular, general purpose software framework for intelligent mobile manipulation robots that can interact with humans using complex human speech commands; navigate smoothly in tight indoor spaces; and finally detect and manipulate various household objects and pieces of furniture autonomously. The suggested software framework is designed to be easily transferred to different home service robots, which include the Toyota Human Support Robot (HSR) and our Modular Service Robot-1 (MSR-1) platforms. It has successfully been used to solve various home service tasks at the RoboCup@Home and World Robot Summit international service robot competitions with promising results.

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Team THOR's Entry in the DARPA Robotics Challenge Finals 2015

Cited by 14 publications

References 33 publications

Research on Walking Gait Planning and Simulation of a Novel Hybrid Biped Robot

Research on Walking Gait Planning and Simulation of a Novel Hybrid Biped Robot

Design and Control of a Open-Source, Low Cost, 3D Printed Dynamic Quadruped Robot

Unified Software Platform for Intelligent Home Service Robots

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