Simulation of the Landing Buffer of a Three-Legged Jumping Robot

Yan, Yilin; Smith, Katherine; Macario-Rojas, A.; Zhang, Hongbo

doi:10.3390/machines10050299

Cited by 2 publications

References 26 publications

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Overview of star catalog detection robots

Zhao,

Liu,

Wang

et al. 2024

First Aerospace Frontiers Conference (AFC 2024)

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With the rapid advancement of aerospace technology, interstellar exploration emerges as the next frontier in expanding human activities beyond Earth. The development of interstellar exploration robots stands as an essential and pioneering technological pursuit in this endeavor. Given the intricate topography and inhospitable conditions of extraterrestrial bodies, interstellar exploration robots encounter formidable challenges related to action, survival, durability, and more, thereby demanding elevated standards in robotic technology. This article provides a comprehensive overview of the current research landscape concerning interstellar exploration robots, both domestically and internationally. It systematically examines the present state of technology research, encompassing aspects such as basic configuration, overall structure, control technology, navigation, environmental sensing technology, and thermal control technology. By delineating the existing research status worldwide, the article aims to highlight the strengths and weaknesses of current technological approaches. Building upon this analysis, the article extrapolates future prospects for interstellar exploration robots. It assesses the technical advantages, drawbacks, and challenges encountered in current research, subsequently outlining prospective research directions and key areas of focus for the advancement of interstellar exploration robot technologies.

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Overview of star catalog detection robots

Zhao,

Liu,

Wang

et al. 2024

First Aerospace Frontiers Conference (AFC 2024)

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CLOVER Robot: A Minimally Actuated Jumping Robotic Platform

et al. 2022

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Robots have been critical instruments to exploration of extreme environments by providing access to environments beyond human limitations. Jumping robot concepts are attractive solutions to negotiate complex and cluttered terrain. However, among the engineering challenges that need to be addressed to enable sustained operation of jumping robot concepts in extreme environments, the reduction of mechanical failure modes is one of the most fundamental. This study sets out to develop a jumping robot design, with a focus on a minimal actuation to support reduced mechanism maintenance and thus limit the number of mechanical failure modes. We present the synthesis of a Sarrus-style linkage to constrain the system to a single translational degree of freedom thus removing the need for synchronising gears, which exhibit high failure rates in dusty environments. We have restricted the present research to vertical solid jumps to assess the performance of the fundamental main-drive linkage. A laboratory demonstrator assists the transfer of theoretical concepts and approaches to practical implementation. The laboratory demonstrator performs jumps with 63% potential-to-kinetic energy conversion efficiency, with a theoretical maximum of 73%. Satisfactory operation opens up design optimisation and directional jump capability towards the development of a jumping robotic platform for extreme environments exploration.

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Simulation of the Landing Buffer of a Three-Legged Jumping Robot

Cited by 2 publications

References 26 publications

Overview of star catalog detection robots

Overview of star catalog detection robots

CLOVER Robot: A Minimally Actuated Jumping Robotic Platform

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