High‐speed mobility on planetary surfaces: A technical review

Rodríguez-Martínez, David; Winnendael, M. van; Yoshida, Kazuya

doi:10.1002/rob.21912

Cited by 23 publications

(10 citation statements)

References 65 publications

(116 reference statements)

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“…Evaluating the performance of foot designs on soil is a daunting task due to the complexity of the physical effects at play. In the past, several semi-empirical wheel-soil interaction models have been developed, such as the famous Bekker model and its derivatives [Bekker, 1956, Bekker, 1960, Rodriguez-Martinez et al, 2019. While those methods have been applied to planetary exploration systems with certain success, the modeling of leg-foot-soil interaction, in comparison, is more diverse and dynamic and has only become a subject of study recently [Ding et al, 2013].…”

Section: Foot Development and Test Setupmentioning

confidence: 99%

“…The traction coefficient µ t was determined by taking the distance l 1 (from the foot attachment to spring attachment) and l 2 (from foot attachment to contact point) into account (Equation 11). We chose the foot's bottom plate as a contact point, similar to the performance evaluation of wheel-soil interaction [Rodriguez-Martinez et al, 2019]. On the bedrock's hard surface, we used the distance from the foot mounting to the studs' tip.…”

Section: Foot Development and Test Setupmentioning

confidence: 99%

See 1 more Smart Citation

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

Kolvenbach¹,

Arm²,

Hampp³

et al. 2022

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Celestial bodies, such as the Moon and Mars are mainly covered by loose, granular soil, which is a notoriously challenging terrain to traverse with wheeled robots. Here, we present experimental work on traversing steep, granular slopes with the dynamically-walking quadrupedal robot SpaceBok. To adapt to the challenging environment, we developed passive-adaptive, planar feet and optimized studs to reduce sinkage and increase traction. Single-foot experiments revealed that a surface area of 110 cm2 per foot reduces sinkage to an acceptable level for the 22 kg robot, even on highly collapsible soil. Implementing several 12 mm studs increases traction by 22% to 66% on granular media compared to stud-less designs. Together with a terrain-adapting walking controller, we validate — for the first time — static and dynamic locomotion on Mars analog slopes of up to 25°(the maximum of the testbed). We evaluated the performance between point- and planar feet and static and dynamic gaits for safety, velocity, and energy consumption. We show that dynamic gaits are energetically more efficient than static ones, but are riskier on steep slopes. Our tests also revealed that energy consumption with planar feet increases drastically as slope inclination approaches the soil’s angle of repose. Point feet are less affected by slippage due to their excessive sinkage but, in turn, are prone to instabilities and tripping. Based on our findings, we present safe and energy-efficient, global, path-planning strategies for negotiating steep Martian topography.

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Section: Foot Development and Test Setupmentioning

confidence: 99%

Section: Foot Development and Test Setupmentioning

confidence: 99%

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

Kolvenbach¹,

Arm²,

Hampp³

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Wheeled robots are the most common conventional mechanism for locomotion over flat and smooth terrains or structured environments. Wheeled robots have high mobility over these surfaces as compared to other mobile robots [54]. A wheeled robot structure has a set of wheels connected to the main body by linkages and joints.…”

Section: B Wheeled and Tracked Amphibious Locomotion 1) Wheeled Amphmentioning

confidence: 99%

Locomotion Strategies for Amphibious Robots-A Review

et al. 2021

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In the past two decades, unmanned amphibious robots have proven the most promising and efficient systems ranging from scientific, military, and commercial applications. The applications like monitoring, surveillance, reconnaissance, and military combat operations require platforms to maneuver on challenging, complex, rugged terrains and diverse environments. The recent technological advancements and development in aquatic robotics and mobile robotics have facilitated a more agile, robust, and efficient amphibious robots maneuvering in multiple environments and various terrain profiles. Amphibious robot locomotion inspired by nature, such as amphibians, offers augmented flexibility, improved adaptability, and higher mobility over terrestrial, aquatic, and aerial mediums. In this review, amphibious robots' locomotion mechanism designed and developed previously are consolidated, systematically The review also analyzes the literature on amphibious robot highlighting the limitations, open research areas, recent key development in this research field. Further development and contributions to amphibious robot locomotion, actuation, and control can be utilized to perform specific missions in sophisticated environments, where tasks are unsafe or hardly feasible for the divers or traditional aquatic and terrestrial robots.

show abstract

Section: Foot Development and Test Setupmentioning

confidence: 99%

Section: Foot Development and Test Setupmentioning

confidence: 99%

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

Kolvenbach¹,

Arm²,

Hampp³

et al. 2021

Preprint

View full text Add to dashboard Cite

Celestial bodies such as the Moon and Mars are mainly covered by loose, granular soil, a notoriously challenging terrain to traverse with (wheeled) robotic systems. Here, we present experimental work on traversing steep, granular slopes with the dynamically walking quadrupedal robot SpaceBok. To adapt to the challenging environment, we developed passive-adaptive planar feet and optimized grouser pads to reduce sinkage and increase traction on planar and inclined granular soil. Single-foot experiments revealed that a large surface area of 110 cm 2 per foot reduces sinkage to an acceptable level even on highly collapsible soil (ES-1). Implementing several 12 mm grouser blades increases traction by 22% to 66% on granular media compared to grouser-less designs. Together with a terrainadapting walking controller, we validate -for the first time -static and dynamic locomotion on Mars analog slopes of up to 25°(the maximum of the testbed). We evaluated the performance between point-and planar feet and static and dynamic gaits regarding stability (safety), velocity, and energy consumption. We show that dynamic gaits are energetically more efficient than static gaits but are riskier on steep slopes. Our tests also revealed that planar feet's energy consumption drastically increases when the slope inclination approaches the soil's angle of internal friction due to shearing. Point feet are less affected by slippage due to their excessive sinkage, but in turn, are prone to instabilities and tripping. We present and discuss safe and energy-efficient global path-planning strategies for accessing steep topography on Mars based on our findings.

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High‐speed mobility on planetary surfaces: A technical review

Cited by 23 publications

References 65 publications

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

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

Locomotion Strategies for Amphibious Robots-A Review

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

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