Multigait soft robot

Abstract: This manuscript describes a unique class of locomotive robot: A soft robot, composed exclusively of soft materials (elastomeric polymers), which is inspired by animals (e.g., squid, starfish, worms) that do not have hard internal skeletons. Soft lithography was used to fabricate a pneumatically actuated robot capable of sophisticated locomotion (e.g., fluid movement of limbs and multiple gaits). This robot is quadrupedal; it uses no sensors, only five actuators, and a simple pneumatic valving system that opera… Show more

“…Research on synthetic auto-chemotaxing particles is still in its infancy, but recent advances 2,3 point to promising efforts in the creation of mechanically compliant materials that appear to communicate and effectively collaborate. Separate advances in automated responses for self-healing polymeric structures 31,32 and actuating structures 33 have achieved impressive macroscopic motion with nonfunctional polymers, which may eventually be augmented by use of functional, autochemotactic materials. Thus, these advances in responsive gels can pave the way for the design of the next generation of responsive, interactive ''soft robots.''…”

Chemo-responsive, self-oscillating gels that undergo biomimetic communication

“…Research on synthetic auto-chemotaxing particles is still in its infancy, but recent advances 2,3 point to promising efforts in the creation of mechanically compliant materials that appear to communicate and effectively collaborate. Separate advances in automated responses for self-healing polymeric structures 31,32 and actuating structures 33 have achieved impressive macroscopic motion with nonfunctional polymers, which may eventually be augmented by use of functional, autochemotactic materials. Thus, these advances in responsive gels can pave the way for the design of the next generation of responsive, interactive ''soft robots.''…”

Chemo-responsive, self-oscillating gels that undergo biomimetic communication

“…[6][7][8] The flexibility of soft actuators offers potentially useful approaches to problems in robotics, and to the design of actuators, grippers, and other soft machines. They can also take advantage of often highly non-linear responses to actuation to accomplish, relatively simply, types of complex motions and tasks that are more difficult to accomplish using hard machines and conventional controllers.…”

“…[6,9] The mobility of the soft robotic structures with which we have worked-structures actuated by the expansion of elastomeric pneumatic networks-have been limited to a single bending mode in the direction defined by the anisotropy of the pneumatic expansion. [6,7] We wished to improve the motion capabilities of these systems, and specifically to fabricate entirely soft robotic actuators with three-dimensional (3D) motion, low cost, and simplicity of control.…”

“…[17,18] Our previous work in soft robotics has demonstrated the use of pneumatic networks (PneuNets)-fabricated in elastomeric materials using soft lithographic techniques highly developed in microfluidics-to serve as soft robotic actuators. [6,7] Here we use these systems to generate new types of elastomeric soft actuators that allow 3D motion. This type of actuator is simple to fabricate, flexible in its operation, and inexpensive.…”

Robotic Tentacles with Three‐Dimensional Mobility Based on Flexible Elastomers

“…In the last decade, soft robotics has been rising up as an emerging research topic,1 with some remarkable achievements such as: universal jamming gripper,2 multigait soft robot,3 worm robot,4 octopus robot,5 fully integrated soft octobot,6 growth robot,7 soft multilocomotion microrobot,8 and so on. Building on intrinsically soft materials or compliant mechanisms, soft robots are rapidly opening new possibilities for typical robotic tasks (e.g., grasping, dexterous manipulation, and locomotion), and also adding new robotic abilities that were unthinkable before,9 like morphing and self‐healing.…”

Toward Perceptive Soft Robots: Progress and Challenges