An effector system comprises: an effector assembly including: a first segment having a conduit between a proximal end and a distal end, an inner surface of the conduit having a conductive portion and a resistive portion; an output member slidable within the conduit, the output member having a conductive exterior contacting the inner surface; a first shape-memory transducer affixed between the proximal end and the output member; and a second shape-memory transducer affixed between the distal end and the output member; and a controller configured to: selectively energize: (i) the first shape-memory transducer to slide the output member in a first direction, (ii) the second shape-memory transducer to slide the output member in a second direction, or (iii) the resistive portion of the inner surface; and in response to energizing the resistive portion, determine a position of the output member.

An effector system includes: a plurality of effector assemblies configured to engage a target object; a base having a plurality of mounting surfaces for movably supporting the effector assemblies; a plurality of actuators coupled to the base, each actuator including: an actuator housing defining a conduit having a first end and a second end; an output member slidable within the conduit; a first shape-memory transducer affixed between the first end and the output member; a second shape-memory transducer affixed between the second end and the output member; an electrical subassembly configured to control each actuator to cause the output member to slide towards a selected one of the first end and the second end; and a plurality of linkages between respective output members and effector assemblies, each linkage configured to move a corresponding effector assembly relative to the base in response to sliding of the respective output member.

The present disclosure provide a controllably deformable tether to capture a target in a microgravity environment, the tether includes a core, wherein the core is a shape memory material; and a controllable node disposed along the length of the core, the controllable node including node including a node controller and a controllable heating source; wherein the node controller to receive a control signal and control the heating source to cause controllable deformation of the shape memory material in an area around the controllable node.

An insertion tool for performing an operation on equipment, the insertion tool including: a plurality of segments, each segment of the plurality of segments including a body comprising: a first hinge; and a second hinge, the first hinge of a first segment being coupled to the second hinge of a second segment adjacent to the first segment through an interface, wherein the interface comprises a powder gap, a multi-modal interface, a compliance feature, a displace-to-lock configuration, an interference fit, or any combination thereof, wherein the insertion tool is configured to be selectively rigidizable using a strength member interfacing with the plurality of segments.

An insertion tool for performing an operation on equipment, the insertion tool including: a plurality of segments, each segment of the plurality of segments including a body comprising: a first hinge; and a second hinge, the first hinge of a first segment being coupled to the second hinge of a second segment adjacent to the first segment through an interface, wherein the interface comprises a powder gap, a multi-modal interface, a compliance feature, a displace-to-lock configuration, an interference fit, or any combination thereof, wherein the insertion tool is configured to be selectively rigidizable using a strength member interfacing with the plurality of segments.

In a soft actuator having a cooler, a wearable robot having the soft actuator, a massage device having the soft actuator, and a method for controlling the soft actuator, the soft actuator includes a heat reaction member, a cooling part and a controller. The heat reaction member is configured to be contracted or relaxed according to a temperature change. The cooling part includes a cooling surface disposed at the heat reaction member, and a heating surface disposed opposite to the cooling surface. The controller is configured to control a power supply part so that a power is blocked to be supplied to the heat reaction member and the power is supplied to the cooling part, when the heat reaction member is changed to be a relaxation state.

The simultaneous enhancement of photo-thermal actuation, optical flexibility, and structural stability of a multi-layered polymeric structure made possible by the integration of an interfacial graphene nanogap layer (iGL) is presented. The present disclosure provides a geometric arrangement of a graphene layer at the interface between a conducting metal layer and optically transparent elastomer layer causing large strain mismatch owing to negative thermal expansion. As a result, rapid and significantly enhanced photo-actuation of the pore membrane/micro shutter structure is achieved, which is 100% larger and faster than conventional cases between 25 C. and 120 C. Furthermore, the iGL enables timely, structurally consistent, and durable actuation performances independent of the environmental parameters such as working phases or light illumination angles. Given these features, an actuator employing the iGL provides rapid and sensitive stimulus operation of light control.

An insertion tool for performing an operation on equipment, the insertion tool including: a plurality of segments, each segment of the plurality of segments including a body including: a first hinge; a second hinge, the first and second hinge members pivotally coupling adjacent segments of the plurality of segments together; and a cavity extending along the body of the segment, the cavity exiting the body at a plurality of exit locations, wherein at least one of the plurality of exit locations is disposed adjacent to the first hinge; and a selectively rigidizable strength member disposed within the cavity.

Disclosed are devices, systems, and methods for fabrication of moving, actuatable structures at micron scales that can be electronically controlled using low power and low voltages. Also disclosed are microscale robots having such microscale actuator structures to actuate the robots' movements as well as devices, systems, and methods for fabrication of microscale robots. The disclosed methods of fabrication are compatible with standard semiconductor technologies.