A carrying platform for moving a device within a conduit, the carrying platform comprising: a body configured to be moveable within the conduit; a number of clampers provided on the body and configured to releasably engage the conduit for immobilizing the carrying platform relative to the conduit; and a device engagement mechanism provided on the body and configured to releasably engage the device.

A carrying platform for moving a device within a conduit, the carrying platform comprising: a body configured to be moveable within the conduit; a number of clampers provided on the body and configured to releasably engage the conduit for immobilizing the carrying platform relative to the conduit; and a device engagement mechanism provided on the body and configured to releasably engage the device.

A novel deformation motion mechanism with precise motion precise motion and structural robustness is achieved. A deformation motion mechanism includes: an elastic ring member shaped symmetrically with respect to a center line, wherein one end of the elastic ring member is fixed and the other end is movable along the center line; a drive unit which is placed within the elastic ring member and is arranged to rotate a feed screw engaged with both ends of the elastic ring member along an operating line orthogonal to the center line, to press or stretch the elastic ring member along the center line; and a plurality of flexible arms which connects the drive unit to the elastic member in at least a direction of the center line.

A micro device transfer apparatus and a micro device transfer method are provided. The micro device transfer apparatus comprises a stage unit including a stage where a target substrate is to be disposed, a plurality of transfer head units disposed above the stage, and a transfer head unit moving part configured to move the plurality of transfer head units, wherein, the transfer head unit comprises a carrier substrate fastening part configured to fasten a carrier substrate where a plurality of micro devices are disposed, a mask unit disposed above the carrier substrate fastening part, the mask unit comprising a mask including an opening part and a shielding part, a light emitting part disposed on the mask unit, and a housing formed around the carrier substrate fastening part, the mask unit, and the light emitting part.

A system includes a computing device with circuitry and memory with instructions for execution by the circuitry. The instructions include monitoring signals indicative of a non-uniform distance between a transfer head and a receiving substrate, and, in response to the monitored signals, actuating one or more actuators towards the transfer head or the receiving substrate to deform the transfer head or the receiving substrate.

A system includes a computing device with circuitry and memory with instructions for execution by the circuitry. The instructions include monitoring signals indicative of a non-uniform distance between a transfer head and a receiving substrate, and, in response to the monitored signals, actuating one or more actuators towards the transfer head or the receiving substrate to deform the transfer head or the receiving substrate.

A microrobot is disclosed. The microrobot includes a magnet configured to provide a motive force when magnetic force of one or more electrical coils act upon the magnet, a support member coupled to the magnet, a thermo-responsive polymer member coupled to each end of the support member at a proximal end, the thermo-responsive polymer member configured to articulate when heated, wherein the thermo-responsive polymer members configured to receive light from a microrobot structured light system and convert the received light into heat.

A microrobot is disclosed. The microrobot includes a magnet configured to provide a motive force when magnetic force of one or more electrical coils act upon the magnet, a support member coupled to the magnet, a thermo-responsive polymer member coupled to each end of the support member at a proximal end, the thermo-responsive polymer member configured to articulate when heated, wherein the thermo-responsive polymer members configured to receive light from a microrobot structured light system and convert the received light into heat.

The present invention are methods for fabrication of micro- and/or nano-scale adhesive fibers and their use for movement and manipulation of objects. Further disclosed is a method of manipulating a part by providing a manipulation device with a plurality of fibers, where each fiber has a tip with a flat surface that is parallel to a backing layer, contacting the flat surfaces on an object, moving the object to a new location, then disengaging the tips from the object.

The present invention are methods for fabrication of micro- and/or nano-scale adhesive fibers and their use for movement and manipulation of objects. Further disclosed is a method of manipulating a part by providing a manipulation device with a plurality of fibers, where each fiber has a tip with a flat surface that is parallel to a backing layer, contacting the flat surfaces on an object, moving the object to a new location, then disengaging the tips from the object.