Legged Self-Manipulation

Johnson, Aaron M.; Koditschek, Daniel E.

doi:10.1109/access.2013.2263192

Cited by 39 publications

(82 citation statements)

References 41 publications

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“…however, following [5,6], when the leg is unconstrained (in the air) we may drop it from the dynamics and use simply M b as the inertia tensor. The potential energy and actuator forces, [6,Eqns.…”

Section: B Self-manipulation Modelingmentioning

confidence: 99%

“…1 for Leap 1, focusing on contact mode 010 but also including some aspects of 000 and 011. We express these equations of motion by following [5,6], which we summarize here.…”

Section: B Self-manipulation Modelingmentioning

confidence: 99%

“…where λ are the constraint forces (e.g in mode 010, λ " " λt λn ‰ , normal and tangential toe forces), and N is the force due to the potential energy, V pqq, [6,Eqn. 31].…”

Section: B Self-manipulation Modelingmentioning

confidence: 99%

“…The first use of its simple 3-contact GRC, [1], Section II-A, is to achieve result (a), summarized above. Namely, the GRC organizes our analytical investigation of the "tailless" machine's (relatively) simple associated self-manipulation hybrid system [5,6] dynamics, Section II-B, leading up to the key formal conclusion of the paper (Prop. 1): a centered hip, rigid leg version of the mechanism cannot achieve a level leap with any control policy (Section II-C).…”

Section: Introductionmentioning

confidence: 99%

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Tail-assisted rigid and compliant legged leaping

Brill

Johnson

et al. 2015

2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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This paper explores the design space of simple legged robots capable of leaping culminating in new behaviors for the Penn Jerboa, an underactuated, dynamically dexterous robot. Using a combination of formal reasoning and physical intuition, we analyze and test successively more capable leaping behaviors through successively more complicated body mechanics. The final version of this machine studied here bounds up a ledge 1.5 times its hip height and crosses a gap 2 times its body length, exceeding in this last regard the mark set by the far more mature RHex hexapod. Theoretical contributions include a non-existence proof of a useful class of leaps for a stripped-down initial version of the new machine, setting in motion the sequence of improvements leading to the final resulting performance. Conceptual contributions include a growing understanding of the Ground Reaction Complex as an effective abstraction for classifying and generating transitional contact behaviors in robotics. Disciplines Electrical and Computer Engineering | Engineering | Systems EngineeringThis conference paper is available at ScholarlyCommons: http://repository.upenn.edu/ese_papers/789 Tail-Assisted Rigid and Compliant Legged LeapingAbstract-This paper explores the design space of simple legged robots capable of leaping culminating in new behaviors for the Penn Jerboa, an underactuated, dynamically dexterous robot. Using a combination of formal reasoning and physical intuition, we analyze and test successively more capable leaping behaviors through successively more complicated body mechanics. The final version of this machine studied here bounds up a ledge 1.5 times its hip height and crosses a gap 2 times its body length, exceeding in this last regard the mark set by the far more mature RHex hexapod. Theoretical contributions include a non-existence proof of a useful class of leaps for a stripped-down initial version of the new machine, setting in motion the sequence of improvements leading to the final resulting performance. Conceptual contributions include a growing understanding of the Ground Reaction Complex as an effective abstraction for classifying and generating transitional contact behaviors in robotics.

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Section: B Self-manipulation Modelingmentioning

confidence: 99%

“…1 for Leap 1, focusing on contact mode 010 but also including some aspects of 000 and 011. We express these equations of motion by following [5,6], which we summarize here.…”

Section: B Self-manipulation Modelingmentioning

confidence: 99%

“…where λ are the constraint forces (e.g in mode 010, λ " " λt λn ‰ , normal and tangential toe forces), and N is the force due to the potential energy, V pqq, [6,Eqn. 31].…”

Section: B Self-manipulation Modelingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Tail-assisted rigid and compliant legged leaping

Brill

Johnson

et al. 2015

2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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“…Additionally, using gearing in the spine allows an individual motor to provide the mass center a significantly higher amount of sustained, work-producing force than it can on a transmission-free leg, without affecting leg linkage transparency. We quantify both of these advantages and demonstrate them on a physical platform in a series of experiments involving leaping from level ground and an isolated foothold (an archetypal feature of unstructured terrain), a task requiring both large ground forces as well as a large workspace to facilitate balancing and self-manipulation [15].…”

Section: Introductionmentioning

confidence: 99%

Core Actuation Promotes Self-manipulability on a Direct-Drive Quadrupedal Robot

Duperret

Kramer

Koditschek

2017

Springer Proceedings in Advanced Robotics

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For direct-drive legged robots operating in unstructured environments, workspace volume and force generation are competing, scarce resources. In this paper we demonstrate that introducing geared core actuation (i.e., proximal to rather than distal from the mass center) increases workspace volume and can provide a disproportionate amount of work-producing force to the mass center without affecting leg linkage transparency. These effects are analytically quantifiable up to modest assumptions, and are demonstrated empirically on a spined quadruped performing a leap both on level ground and from an isolated foothold (an archetypal feature of unstructured terrain). Abstract. For direct-drive legged robots operating in unstructured environments, workspace volume and force generation are competing, scarce resources. Disciplines Electrical and Computer Engineering | Engineering | Systems EngineeringIn this paper we demonstrate that introducing geared core actuation (i.e., proximal to rather than distal from the mass center) increases workspace volume and can provide a disproportionate amount of work-producing-force to the mass center without affecting leg linkage transparency. These effects are analytically quantifiable up to modest assumptions, and are demonstrated empirically on a spined quadruped performing a leap both on level ground and from an isolated foothold (an archetypal feature of unstructured terrain).

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Composing Dynamical Systems to Realize Dynamic Robotic Dancing

Kolathaya

Ames

2015

Springer Tracts in Advanced Robotics

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Legged Self-Manipulation

Cited by 39 publications

References 41 publications

Tail-assisted rigid and compliant legged leaping

Tail-assisted rigid and compliant legged leaping

Core Actuation Promotes Self-manipulability on a Direct-Drive Quadrupedal Robot

Composing Dynamical Systems to Realize Dynamic Robotic Dancing

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