An artificial muscle includes an electrode pair including a first electrode and a second electrode. One or both of the first electrode and the second electrode includes a central opening. The first electrode and the second electrode each include two or more fan portions and two or more bridge portions. Each fan portion includes a first end having an inner length, a second end having an outer length, a first side edge extending from the second end, and a second side edge extending from the second end. The outer length is greater than the inner length. Each bridge portion interconnecting adjacent fan portions at the first end.

A multi-fingered robot includes a plurality of finger mechanisms that each of which has a first wire for driving, a plurality of driving parts for bending that independently drives the first wire of each finger mechanism so as to bend each of the finger mechanisms, a connecting member that connects between at least one set of the first wires among a plurality of the first wires, and a driving controller that controls driving of the first wire of each of the finger mechanisms by the driving parts for bending. The driving controller causes the driving part for bending that drives the first wire of the second finger mechanism to assist the bending operation of the first finger mechanism via the extended connecting member if a difference between a first posture of the first finger mechanism and a second posture of the second finger mechanism is larger than a predetermined difference.

An artificial muscle that includes a first end plate opposite a second end plate, a flexible enclosure extending from the first end plate to the second end plate and housing a dielectric fluid, and a reciprocating electrode stack housed within the flexible enclosure and coupled to and extending between the first end plate and the second end plate. The reciprocating electrode stack includes one or more electrode pairs, each electrode pair having a positive electrode and a negative electrode physically coupled to one another along a first edge portion of the positive electrode and the negative electrode. The artificial muscle also includes a plurality of electrode leads electrically coupled to the reciprocating electrode stack. Each individual electrode lead of the plurality of electrode leads extends from an individual electrode of the reciprocating electrode stack to the first end plate or the second end plate.

Simulated motion of the papillary muscles in a heart simulator is provided that simulates natural motion of the papillary muscles. This improves heart valve simulation. This can be done with a six degree of freedom robotic actuator (e.g., a Stewart platform or the like) appropriately driven by a controller. This can also be done with a robotic actuator that provides constrained motion of its effector by including a mechanical linkage, as long as the resulting simulated papillary muscle motion includes time-varying position and orientation of the papillary muscle.

High strain hydraulically amplified self-healing electrostatic transducers having increased maximum theoretical and practical strains are disclosed. In particular, the actuators include electrode configurations having a zipping front created by the attraction of the electrodes that is configured orthogonally to a strain axis along which the actuators. This configuration produces increased strains. In turn, various form factors for the actuator configuration are presented including an artificial circular muscle and a strain amplifying pulley system. Other actuator configurations are contemplated that include independent and opposed electrode pairs to create cyclic activation, hybrid electrode configurations, and use of strain limiting layers for controlled deflection of the actuator.

Systems and methods for providing flexible robotic actuators are disclosed. Some embodiments of the disclosed subject matter include a soft robot capable of providing a radial deflection motions; a soft tentacle actuator capable of providing a variety of motions and providing transportation means for various types of materials; and a hybrid robotic system that retains desirable characteristics of both soft robots and hard robots. Some embodiments of the disclosed subject matter also include methods for operating the disclosed robotic systems.

A tendon-driven robotic gripper is disclosed for performing fingertip and enveloping grasps. One embodiment comprises two fingers, each with two links, and is actuated using a single active tendon. During unobstructed closing, the distal links remain parallel, creating exact fingertip grasps. Conversely, if the proximal links are stopped by contact with an object, the distal links start flexing, creating a stable enveloping grasp. The route of the active tendon and the parameters of the springs providing passive extension forces are optimized in order to achieve this behavior. An additional passive tendon is disclosed that may be used as a constraint preventing the gripper from entering undesirable parts of the joint workspace. A method for optimizing the dimensions of the links in order to achieve enveloping grasps of a large range of objects is disclosed and applied to a set of common household objects.

A shear force actuator is described, including: two substantially parallel first structural components disposed along a first axis; a plurality of substantially parallel second structural components disposed between and bridging the two first structural components; a plurality of joint sections each joining the second structural component with the first structural components at an oblique angle of between 0 and 90 degrees to define a plurality of cells, each capable of being connected with a fluid inflation or deflation source; an elastic surface covering the remaining surfaces of the cells in a fluid-tight manner, wherein at least one of the joint section, the first structural components, and the second structural components is elastic so that cell collapses upon removal of fluid from the cell to generate a linear force along the first axis.

Certain exemplary embodiments can provide a system, machine, device, and/or manufacture configured for and/or resulting from, and/or a method for, activities that can comprise and/or relate to, an air beam configured to be dynamically moved, the air beam having an inflatable gas bladder, a first tube substantially surrounding the gas bladder, and one or more axial reinforcements.

A robotic surgery assembly includes a medical instrument having a frame, a jointed device having a degree of freedom with respect of the frame, and at least one tendon made of polymer fibers configured for actuating the degree of freedom. The tendon includes a tendon endpoint connected to the medical instrument to exert a tensile load for actuating the degree of freedom.