An apparatus including a robot drive having motors and coaxial drive shafts connected to the motors; and a robot arm connected to the robot drive. The robot arm includes two upper arms, a first set of forearms connected to a first one of the upper arms, a second set of forearms connected to a second one of the upper arms and end effectors connected to respective ones of the forearms. The first and second upper arms are connected to respective first and second ones of the coaxial drive shafts. The first set of the forearms is mounted on the first upper arm and connected to a third one of the coaxial drive shafts by respective first and second drive belt assemblies. The second set of the forearms is mounted to the second upper arm and connected to a fourth one of the coaxial drive shafts by respective third and fourth drive belt assemblies.

A parallel robot is equipped with: a base plate that is provided so as to be capable of sliding movement; three link mechanisms disposed radially when viewed from the normal direction of the base plate; and three lower motors with reduction gears that are disposed on the base plate and are connected separately to the base ends of the three link mechanisms. A plurality of parallel robots are disposed so that the respective orientations of the three link mechanisms alternate.

A robotic surgical system comprising a surgical instrument. The surgical instrument includes an elongate, hollow shaft having a proximal end, a distal end, and a flexible section. The surgical instrument also includes a sensor apparatus comprising an electromagnetic sensor. The robotic surgical system also includes a force transmission mechanism coupled to the proximal end of the shaft and a processor communicatively coupled to at least the sensor apparatus. The processor is configured to receive sensor data from the sensor apparatus and to use the sensor data with mechanical property data for the surgical instrument and material property data for the surgical instrument to determine external force information for the surgical instrument.

A bending apparatus in one aspect of the present disclosure comprises a robot, a chuck mechanism, and a plurality of bending mechanisms. The plurality of bending mechanisms are each provided as a separate component from the robot and the chuck mechanism, and are arranged in a space reachable by a workpiece held by the chuck mechanism.

Medical, surgical, and/or robotic devices and systems often including offset remote center parallelogram manipulator linkage assemblies which constrains a position of a surgical instrument during minimally invasive robotic surgery are disclosed. The improved remote center manipulator linkage assembly advantageously enhances the range of instrument motion while at the same time reduces the overall complexity, size, and physical weight of the robotic surgical system.

A substrate transport apparatus including a frame, a drive section connected to the frame and including at least one independently controllable motor, at least two substrate transport arms connected to the frame and comprising arm links arranged for supporting and transporting substrates, and a mechanical motion switch coupled to the at least one independently controllable motor and the at least two substrate transport arms for effecting the extension and retraction of one of the at least two substrate transport arms while the other one of the at least two substrate transport arms remains in a substantially retracted configuration.

A surgical system comprising: a surgical mechanical arm comprising a plurality of surgical arm sections sequentially coupled by surgical arm joints; an input arm comprising: a plurality of input arm sections sequentially coupled by input arm joints; and an elongate handle: sized and shaped to be held between a human adult's thumb and one or more finger, coupled to a distal end of said input arm by a flexion joint; and extending proximally with respect to a most distal input arm section so a user grasping said handle bends said flexion joint to hold said handle above other portions of the input arm; at least one sensor configured to measure movement of one or more of said sections; and circuitry configured to receive a measurement signal from said at least one sensor and to generate a control signal, based on said measurement signal for control of movement of said surgical mechanical arm.

The composite work apparatus includes: two link actuation devices that support two working bodies such that postures of the working bodies can be individually changed; and three or more linear motion actuators that move the two link actuation devices and two or more work objects relative to each other. In each link actuation device, a distal end side link hub is connected to a proximal end side link hub via three or more link mechanisms such that a posture of the distal end side link hub can be changed relative to the proximal end side link hub, and a posture control actuator that arbitrarily changes the posture of the distal end side link hub relative to the proximal end side link hub is provided to each of two or more link mechanisms of the three or more link mechanisms.

A robot has a first member, an optical wire placed in the first member, a power line placed in the first member, a photoelectric conversion unit placed in the first member, and an encoder placed in the first member, wherein the optical wire is connected to be optically communicable with the photoelectric conversion unit, the power line is connected to be conductive to the encoder and the photoelectric conversion unit, and a current flowing in the power line is distributed to the encoder and the photoelectric conversion unit.

A substrate transport apparatus including a frame, a drive section connected to the frame and including at least one independently controllable motor, at least two substrate transport arms connected to the frame and comprising arm links arranged for supporting and transporting substrates, and a mechanical motion switch coupled to the at least one independently controllable motor and the at least two substrate transport arms for effecting the extension and retraction of one of the at least two substrate transport arms while the other one of the at least two substrate transport arms remains in a substantially retracted configuration.