Incorporating frictional anisotropy in the design of a robotic snake through the exploitation of scales

Serrano, Miguel M.; Chang, Alexander H.; Zhang, Guangcong; Vela, Patricio A.

doi:10.1109/icra.2015.7139717

Cited by 16 publications

(8 citation statements)

References 15 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This makes our solution simple and cheap. Our approach is also different from other developments which require complex motion control or/and special robot structures (e.g., active scales) to achieve frictional anisotropy for efficient locomotion263738.…”

Section: Discussionmentioning

confidence: 98%

Enhanced Locomotion Efficiency of a Bio-inspired Walking Robot using Contact Surfaces with Frictional Anisotropy

Manoonpong

Petersen

Kovalev

et al. 2016

Sci Rep

View full text Add to dashboard Cite

Based on the principles of morphological computation, we propose a novel approach that exploits the interaction between a passive anisotropic scale-like material (e.g., shark skin) and a non-smooth substrate to enhance locomotion efficiency of a robot walking on inclines. Real robot experiments show that passive tribologically-enhanced surfaces of the robot belly or foot allow the robot to grip on specific surfaces and move effectively with reduced energy consumption. Supplementing the robot experiments, we investigated tribological properties of the shark skin as well as its mechanical stability. It shows high frictional anisotropy due to an array of sloped denticles. The orientation of the denticles to the underlying collagenous material also strongly influences their mechanical interlocking with the substrate. This study not only opens up a new way of achieving energy-efficient legged robot locomotion but also provides a better understanding of the functionalities and mechanical properties of anisotropic surfaces. That understanding will assist developing new types of material for other real-world applications.

show abstract

Section: Discussionmentioning

confidence: 98%

Enhanced Locomotion Efficiency of a Bio-inspired Walking Robot using Contact Surfaces with Frictional Anisotropy

Manoonpong

Petersen

Kovalev

et al. 2016

Sci Rep

View full text Add to dashboard Cite

show abstract

“…Marvi et al, studied active control of scales in corn snakes and developed the two-link inchworm robot ScalyBot, to study the effects of actively adjusted scales on locomotion, on flat and inclined planes [24]. Grooves, static scales, and friction skins have also been widely used to incorporate the desired friction characteristics directly into the construction of a snake robot's outer shell, as in the 3D printed scales employed by the Scaled Snake Robot, or the bristle-covered fabric used in the MMIR robot [25], [26].…”

Section: Work On Snake Robots Was Initiated By S Hirose's Developmenmentioning

confidence: 99%

Design and Control of a Cable-Driven Articulated Modular Snake Robot

Racioppo

Ben-Tzvi

2019

IEEE/ASME Trans. Mechatron.

View full text Add to dashboard Cite

This thesis presents the design and control of a cable-actuated mobile snake robot. The goal of this research is to reduce the size of snake robots and improve their locomotive efficiency by simultaneously actuating groups of links to fit optimized curvature profiles. The basic functional unit of the snake is a four-link, single degree of freedom module that bends using an antagonistic cable-routing scheme. Elastic elements in series with the cables and the coupled nature of the mechanism allow each module to detect and automatically respond to obstacles. The mechanical and electrical designs of the bending module are presented, with emphasis on the cable-routing scheme, key optimizations, and the use of series elastic actuation. An approximate expression for the propulsive force generated by a Design and Control of a Cable-Driven Articulated Modular Snake Robot

show abstract

“…The robotic snake employed in these experiments extends its predecessor. 37 It has 12 serially connected modules, each consisting of a motor, an aluminum link connecting to the next module and a fabricated plastic chassis encasing both. The chassis exterior is lined with artificial scales on all but one side.…”

Section: Scale-augmented Robotic Platformmentioning

confidence: 99%

“…Discrete approximation of the continuous gait shapes was accomplished using a methodology similar to refs. [37,45]. For each body wave component, a forward march from the caudal to rostral ends was performed whereby the tail, each interior joint and the head were sequentially positioned coincident with the planar body wave component.…”

Section: Body Curve Fittingmentioning

confidence: 99%

Evaluation of Bio-Inspired Scales on Locomotion Performance of Snake-Like Robots

Chang

Vela

2019

Robotica

Self Cite

View full text Add to dashboard Cite

SummaryThe unique frictional properties conferred by snake ventral scales inspired the engineering and fabrication of surrogate mechanisms for a robotic snake. These artificial, biologically inspired scales produce anisotropic body-ground forcing patterns with various locomotion surfaces. The benefits they confer to robotic snake-like locomotion were evaluated in experimental trials employing rectilinear, lateral undulation, and sidewinding gaits over several distinct surface types: carpet, inhomogeneous concrete and homogeneous concrete. Enhanced locomotive performance, with respect to net displacement and heading stability, was consistently measured in scenarios that utilized the engineered scales, over equivalent scenarios where the anisotropic effects of scales were absent.

show abstract

Incorporating frictional anisotropy in the design of a robotic snake through the exploitation of scales

Cited by 16 publications

References 15 publications

Enhanced Locomotion Efficiency of a Bio-inspired Walking Robot using Contact Surfaces with Frictional Anisotropy

Enhanced Locomotion Efficiency of a Bio-inspired Walking Robot using Contact Surfaces with Frictional Anisotropy

Design and Control of a Cable-Driven Articulated Modular Snake Robot

Evaluation of Bio-Inspired Scales on Locomotion Performance of Snake-Like Robots

Contact Info

Product

Resources

About