David Zarrouk scite author profile

Direct conversion of light into mechanical work, known as the photomechanical effect, is an emerging field of research, largely driven by the development of novel molecular and polymeric material systems. However, the fundamental impediment is that the previously explored materials and structures do not simultaneously offer fast and wavelength-selective response, reversible actuation, low-cost fabrication and large deflection. Here, we demonstrate highly versatile photoactuators, oscillators and motors based on polymer/single-walled carbon nanotube bilayers that meet all the above requirements. By utilizing nanotubes with different chirality distributions, chromatic actuators that are responsive to selected wavelength ranges are achieved. The bilayer structures are further configured as smart 'curtains' and light-driven motors, demonstrating two examples of envisioned applications.

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Dynamic turning of 13 cm robot comparing tail and differential drive

Pullin

Kohut

Zarrouk

et al. 2012

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Precise dynamic turning of a 10 cm legged robot on a low friction surface using a tail

Kohut

Pullin

Haldane

et al. 2013

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Abstract-For maximum maneuverability, terrestrial robots need to be able to turn precisely, quickly, and with a small radius. Previous efforts at turning in legged robots primarily have used leg force or velocity modulation. We developed a palm-sized legged robot, called TAYLRoACH. The tailed robot was able to make rapid, precise turns using only the actuation of a tail appendage. By rapidly rotating the tail as the robot runs forward, the robot was able to make sudden 90• turns at 360• s −1 . Unlike other robots, this is done with almost no change in its running speed. We have also modeled the dynamics of this maneuver, to examine how features, such as tail length and mass, affect the robot's turning ability. This approach has produced turns with a radius of 0.4 body lengths at 3.2 body lengths per second running speed. Using gyro feedback and bang-bang control, we achieve an accuracy of ± 5• for a 60• turn.

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Rising STAR: A Highly Reconfigurable Sprawl Tuned Robot

Zarrouk

Yehezkel

2018

IEEE Robot. Autom. Lett.

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Conditions for Worm-Robot Locomotion in a Flexible Environment: Theory and Experiments

Zarrouk

Sharf

Shoham

2012

IEEE Trans. Biomed. Eng.

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Biological vessels are characterized by their substantial compliance and low friction that present a major challenge for crawling robots for minimally invasive medical procedures. Quite a number of studies considered the design and construction of crawling robots; however, very few focused on the interaction between the robots and the flexible environment. In a previous study, we derived the analytical efficiency of worm locomotion as a function of the number of cells, friction coefficients, normal forces, and local (contact) tangential compliance. In this paper, we introduce the structural effects of environment compliance, generalize our previous analysis to include dynamic and static coefficients of friction, determine the conditions of locomotion as function of the external resisting forces, and experimentally validate our previous and newly obtained theoretical results. Our experimental setup consists of worm robot prototypes, flexible interfaces with known compliance and a Vicon motion capture system to measure the robot positioning. Separate experiments were conducted to measure the tangential compliance of the contact interface that is required for computing the analytical efficiency. The validation experiments were performed for both types of compliant conditions, local and structural, and the results are shown to be in clear match with the theoretical predictions. Specifically, the convergence of the tangential deflections to an arithmetic series and the partial and overall loss of locomotion verify the theoretical predictions.

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David Zarrouk

Photoactuators and motors based on carbon nanotubes with selective chirality distributions

Dynamic turning of 13 cm robot comparing tail and differential drive

Precise dynamic turning of a 10 cm legged robot on a low friction surface using a tail

Rising STAR: A Highly Reconfigurable Sprawl Tuned Robot

Conditions for Worm-Robot Locomotion in a Flexible Environment: Theory and Experiments

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