A robotic cleaning apparatus for cleaning a dirty object includes a cleaning head and an articulated body. The articulated body is coupled to the cleaning head and mountable to the dirty object. The body has one or more actuators that collectively move the cleaning head into contact with surfaces of the dirty object. The one or more actuators, when activated, collectively rotate the cleaning head relative to the dirty object about first and second axes, and translate the cleaning head relative to the dirty object along an extension axis. A method of robotically cleaning is also disclosed.

A method for robotic inspection of a part, includes the steps of: supporting the part with a robot mechanism; obtaining part-related sensor input with a sensor positioned to inspect the part supported by the robot mechanism; and controlling movement of the robot mechanism relative to the sensor, wherein the controlling is done by a feedback control unit which receives the sensor input, and the feedback control unit is configured to control the robot mechanism based upon the sensor input.

An example method may include i) detecting a disturbance to a gait of a robot, where the gait includes a swing state and a step down state, the swing state including a target swing trajectory for a foot of the robot, and where the target swing trajectory includes a beginning and an end; and ii) based on the detected disturbance, causing the foot of the robot to enter the step down state before the foot reaches the end of the target swing trajectory.

A robot arm comprising a joint mechanism for articulating one limb (310) of the arm relative to another limb (311) of the arm about two non-parallel rotation axes (20, 21), the mechanism comprising: an intermediate carrier (28) attached to a first one of the limbs by a first revolute joint having a first rotation axis and to a second one of the limbs by a second revolute joint having a second rotation axis; a first drive gear (33) disposed about the first rotation axis and fast with the carrier, whereby rotation of the carrier relative to the first limb about the first rotation axis can be driven; a second drive gear (37) disposed about the second rotation axis and fast with the second one of the limbs, whereby rotation of the second one of the limbs about the second rotation axis relative to the carrier can be driven; at least one of the first and second drive gears being a sector gear.

A joint assembly for a robot, comprising a housing connected with an output part. The housing comprising a housing wall and a strain wave gearing system. The strain wave gearing system comprising a wave generator, a flexspline, and a circular spline connected to the output part. The wave generator is rotated by a rotor shaft. The rotor shaft is driven by an electric motor comprising a rotor magnet and a stator. The rotor magnet being affixed to the rotor shaft. The joint assembly further comprises one or more sensors comprising one or more magnetic field sensors and one or more pole rings arranged to measure a position of the output part in relation to the housing.

The systems and methods disclosed herein include a path integration system that calculates optic flow, infers angular velocity from the flow field, and incorporates this velocity estimate into heading calculations. The resulting system fuses heading estimates from accelerometers, 5 gyroscopes, engine torques, and optic flow to determine self-localization. The system also includes a motivational system that implements a reward drive, both positive and negative, into the system. In some implementations, the drives can include: a) a curiosity drive that encourages exploration of new areas, b) a resource drive that attracts the agent towards the recharging base when the battery is low, and c) a mineral reward drive that attracts the agent 10 towards previously explored scientific targets.

A remote control robot system includes a slave arm, a master main body imitating the shape of an object handled by the slave arm, a manipulation receiving device configured to receive manipulation of an operator based on the position and posture of the master main body, and a control device configured to control operation of the slave arm based on the manipulation received by the manipulation receiving device so that behavior of the object corresponds to behavior of the master main body.

A remote-control manipulator system includes a manipulator configured to receive a manipulating instruction from an operator, a slave arm configured to perform a series of works comprised of a plurality of processes, a camera configured to image operation of the slave arm, a display device configured to display an image captured by the camera, a storage device configured to store information related to environment in a workspace as an environment model, and a control device. The control device is configured, while operating the slave arm manually or hybridly, to acquire circumference information that is information related to a circumference area of an area imaged by the camera based on the environment model stored in the storage device, and display on the display device so that the image captured by the camera and the circumference information are interlocked.

Generally, a sterile adapter for use in robotic surgery may include a frame configured to be interposed between a tool driver and a surgical tool, a plate assembly coupled to the frame, and at least one rotatable coupler supported by the plate assembly and configured to communicate torque from an output drive of the tool driver to an input drive of the surgical tool.

A walking support robot of the present disclosure is a walking support robot that moves in accordance with a handle force while supporting walking of a user. The walking support robot includes a body, a handle that is on the body and is held by the user, a sensor that senses a force applied to the handle, and a moving device that includes a rotating member and moves the walking support robot by controlling rotation of the rotating member in accordance with the force sensed by the sensor. The walking support robot estimates a leg position of the user on a basis of a change of the force sensed by the sensor, and sets a load to be applied to the user on a basis of the leg position.