Toward a Gecko-Inspired, Climbing Soft Robot

Schiller, Lars; Seibel, Arthur; Schlattmann, Josef

doi:10.3389/fnbot.2019.00106

Cited by 25 publications

(15 citation statements)

References 15 publications

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“…The aim of this work was position control of the gecko-inspired soft robot from Schiller et al ( 2019 ) in Cartesian space. The solution to this complex task is based on two major simplifications: (i) the formulation of a gait law to reduce the state space of the robot from nine to two dimensions and (ii) the approximation of the direct kinematics to allow a fast evaluation.…”

Section: Discussionmentioning

confidence: 99%

“…However, the same principles are also valid for mobile soft robots. Most mobile soft robots, such as in Shepherd et al ( 2011 ), Godage et al ( 2012 ), Tolley et al ( 2014 ), Qin et al ( 2019 ), and Schiller et al ( 2019 ), are feed forward-controlled with predefined gait patterns. In order to enable such robots to move autonomously even in unknown terrain, a locomotion controller is needed that can generate any gait path.…”

Section: Introductionmentioning

confidence: 99%

“…Hence, for locomotion control of a robotic platform, a robot-specific motion strategy must be known. This paper analytically derives a robot-specific mapping of desired motion (forward and rotational speed) to joint coordinates for the gecko-inspired robot from Schiller et al ( 2019 ), which is briefly described in section 2. The mapping function is referred to as “gait law” and is presented in section 3.…”

Section: Introductionmentioning

confidence: 99%

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A Gait Pattern Generator for Closed-Loop Position Control of a Soft Walking Robot

2020

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This paper presents an approach to control the position of a gecko-inspired soft robot in Cartesian space. By formulating constraints under the assumption of constant curvature, the joint space of the robot is reduced in its dimension from nine to two. The remaining two generalized coordinates describe respectively the walking speed and the rotational speed of the robot and define the so-called velocity space. By means of simulations and experimental validation, the direct kinematics of the entire velocity space (mapping in Cartesian task space) is approximated by a bivariate polynomial. Based on this, an optimization problem is formulated that recursively generates the optimal references to reach a given target position in task space. Finally, we show in simulation and experiment that the robot can master arbitrary obstacle courses by making use of this gait pattern generator.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Gait Pattern Generator for Closed-Loop Position Control of a Soft Walking Robot

2020

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“…The goal of this protocol is to provide a method to manufacture, control, and evaluate the performance of a gecko-inspired, climbing soft robot 9 . Its design is based on the use of fast pneunet soft bending actuators 10 made of elastomer.…”

Section: Introductionmentioning

confidence: 99%

“…The literature offers a wide range of different designs of soft actuators 11 and suitable materials 12 . The presented manufacturing method is similar to existing methods 13 but includes some modifications that result in increased repeatability and robustness, at least in the case of the soft climbing robot 9 . The method is valid for fast pneunet bending actuators in general and might, therefore, be interesting for newcomers to the field of actuator manufacturing.…”

Section: Introductionmentioning

confidence: 99%

Manufacturing, Control, and Performance Evaluation of a Gecko-Inspired Soft Robot

Schiller

Seibel

Schlattmann

2020

JoVE

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This protocol presents a method for manufacturing, control, and evaluation of the performance of a soft robot that can climb inclined flat surfaces with slopes of up to 84°. The manufacturing method is valid for the fast pneunet bending actuators in general and might, therefore, be interesting for newcomers to the field of actuator manufacturing. The control of the robot is achieved by means of a pneumatic control box that can provide arbitrary pressures and can be built by only using purchased components, a laser cutter, and a soldering iron. For the walking performance of the robot, the pressure-angle calibration plays a crucial role. Therefore, a semi-automated method for the pressure-angle calibration is presented. At high inclines (> 70°), the robot can no longer reliably fix itself to the walking plane. Therefore, the gait pattern is modified to ensure that the feet can be fixed on the walking plane.

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From Bioinspiration to Computer Generation: Developments in Autonomous Soft Robot Design

Pinskier

Howard

2021

Advanced Intelligent Systems

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The emerging field of soft robotics presents a new paradigm for robot design in which “precision through rigidity” is replaced by “cognition through compliance.” Lightweight and flexible, soft robots have vast potential to interact with fragile objects and navigate unstructured environments. Like octopuses and worms in nature, soft robots’ flexible bodies conform to hard objects and reconfigure for different tasks, delegating the burden of control from brain to body through embodied cognition. However, because of the lack of efficient modeling and simulation tools, soft robots are primarily designed by hand. Typically, hard components from rigid robots or living creatures are heuristically substituted for comparable soft ones. Autonomous design and manufacturing methodologies are urgently required to produce bespoke, high‐performing robots. Currently, design methodologies exist between simple but realistic parametric optimizations, and evolutionary algorithms which simulate morphology and control coevolution. To find high‐performing designs, novel high‐fidelity simulators and high‐throughput manufacturing and testing processes are required to explore the complex soft material, morphology and control landscape, blending simulation, and experimental data. This article reviews the state of the art in autonomous soft robotic design. Existing manual and automated designs are surveyed and future directions to automate soft robot design and manufacturing are presented.

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Toward a Gecko-Inspired, Climbing Soft Robot

Cited by 25 publications

References 15 publications

A Gait Pattern Generator for Closed-Loop Position Control of a Soft Walking Robot

A Gait Pattern Generator for Closed-Loop Position Control of a Soft Walking Robot

Manufacturing, Control, and Performance Evaluation of a Gecko-Inspired Soft Robot

From Bioinspiration to Computer Generation: Developments in Autonomous Soft Robot Design

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