An actuation system for actuating concentric tubes of a concentric-tube robot. The actuation system is configured to actuate the concentric tubes from radially to one side of the concentric tubes.

A tensegrity robot includes multiple tensile members connected to multiple structural members to form a spatially defined structure. Each structural member is connected to one or more other structural members by tensile members therebetween. The robot further includes multiple actuators operatively connected to the tensile members and the structural members, and multiple controllers configured to communicate with each of the actuators. The controllers direct control of at least one of tension or length of the tensile members by the actuators to cause a change in at least one of the size, shape or center of gravity of the spatially defined structure to effect robotic actions. At least two tensile members are connected to an actuator such that at least one of tension or length in both of the tensile members are changed in coordination by the actuator.

In a soft actuator, a soft actuator assembly having the soft actuator, and a wearable robot having the soft actuator or the soft actuator assembly, the soft actuator includes a first spring bundle, a first conductive pad and a second conductive pad. The first spring bundle has a plurality of fine wires, and is configured to be capable of being changed between a contraction state and a relaxation state according to a change of temperature. The first conductive pad has a first connector electrically connected to a first end of the first spring bundle. The second conductive pad has a second connector electrically connected to a second end of the first spring bundle. The first connector is fixed between the first conductive pad and the first spring bundle, and the second connector is fixed between the second conductive pad and the first spring bundle.

Methods, systems, and methods of manufacture for soft robotic actuators are described herein. In one aspect, a soft robotic actuator can include an elastomeric material defining a cavity; a volume of liquid metal (LM) positioned within the cavity; and an energy source coupled to the LM, where the energy source is adapted or configured to alter a temperature of the volume of LM, whereby altering the temperature of the volume of LM initiates an actuation of the elastomeric material.

Provided is a bending structure and a joint function part, capable of ensuring sufficient flexibility and rigidity in an axial direction. The bending structure is provided with an outer coiled part formed of a wire wound in a coiled shape and an inner coiled part formed of a wire wound in a coiled shape and arranged in the outer coiled part, wherein the outer coiled part has a plurality of gaps to distance adjacent coils, and coils of the inner coiled part are provided so as to correspond to the gaps of the outer coiled part and fit between the adjacent coils while being in contact with the adjacent coils of the outer coiled part.

A method of manufacturing an electrode assembly includes positioning a layer stack comprising an electrode positioned between an electrode insulator and a support polymer in a vacuum bag, removing air from the vacuum bag thereby vacuum coupling the electrode to the electrode insulator, and removing the layer stack from the vacuum bag, where upon removal of the layer stack from the vacuum bag, the electrode remains vacuum coupled to the electrode insulator and the electrode insulator is in direct contact with the electrode, thereby forming an electrode assembly.

A system and method for controlling a device, such as a virtual reality (VR) and/or a prosthetic limb are provided. A biomimetic controller of the system comprises a signal processor and a musculoskeletal model. The signal processor processes M biological signals received from a residual limb to transform the M biological signals into N activation signals, where M and N are integers and M is less than N. The musculoskeletal model transforms the N activation signals into intended motion signals. A prosthesis controller transforms the intended motion signals into three or more control signals that are outputted from an output port of the prosthesis controller. A controlled device receives the control signals and performs one or more tasks in accordance with the control signals.

A soft structure fiber reinforcement and actuation technology is provided. In an example embodiment, the tendon-driven, fiber-reinforced elastomer membrane comprises an elastomer matrix material and a fiber array embedded within the elastomer matrix material. The one or more tendons are not mechanically bonded to the elastomer matrix material, such that the one or more embedded tendons are able to move through the elastomer matrix material. One or more apparatuses may employ one or more such tendon-driven, fiber-reinforced elastomer membranes for use in a variety of applications.

Provided is an artificial muscle device, including a plurality of heat transfer modules including a thermal conductive body in which a plurality of tunnels parallel to each other and a thermoelectric element contacting an outer surface of the thermal conductive body, a connection member connecting a first heat transfer module to a second heat transfer module, the connection member being folded or unfolded according to a distance between the first heat transfer module and the second heat transfer module, a thermal reaction driving member passing through each of the tunnels, the thermal reaction driving member being stretched or contracted in a longitudinal direction of the tunnel according to a temperature of the thermal reaction driving member, and a power transmission part connected to an end of the thermal reaction driving member.

The invention relates to exoskeletons and artificial muscles for soft exoskeletons (1). The muscle (21, 22, 23, 24) comprises a first (211, 221, 231, 241) and second (212, 222, 232, 242) tendon, each comprising an attachment means (227) for attachment of said muscle to a muscle connector (32) of the exoskeleton (1), and a muscle core (223) made of a deformable material extending between said first (211, 221, 231, 241) and second (212, 222, 232, 242) tendon, the muscle core (223) preferably comprising an outer sleeve (225); wherein each of the first (211, 221, 231, 241) and second tendon (212, 222, 232, 242) is adapted for receiving a respective end of said muscle core (223); wherein the first tendon (211, 221, 231, 241) preferably comprises an actuation interface (229) for connection of said muscle core (223) to an actuator for generating an actuation; wherein the muscle core (223) is adapted to undergo a change in length when being actuated, thereby causing the first (211, 221, 231, 241) and second (212, 222, 232, 242) tendon to move towards each other when said actuation received via the actuation interface is on or increased, and to move away from each other when said actuation is off or reduced.