At least three spherical surface sliding bearings provided between a first member and a second member and disposed at mutually different positions when seen in the height direction, are provided. Each of the at least three spherical surface sliding bearings has an inner ring and an outer ring, either one of the inner ring and the outer ring is attached to the first member, and the other is attached to the second member. In at least two of the at least three spherical surface sliding bearings, the height adjustment mechanism intervenes, at least either one of between one of the inner ring and the outer ring, and the first member, and between the other and the second member.

A control method of a gimbal includes in response to the gimbal being in a sleeping mode and receiving a push-pull operation on a frame of the gimbal, obtaining a current target joint angle according to an actual joint angle of a motor arranged at the frame and configured to rotate the frame and controlling the motor according to the current target joint angle. The actual joint angle corresponds to a position where the push-pull operation reaches.

The present invention discloses a stiffness-variable joint actuator with motor-reducer integration, and belongs to the field of robots. The stiffness-variable joint actuator includes: a torque motor, which includes a casing, a stator, a rotor, pin gears, and pin gear rollers; and a reducer core, which includes cycloidal gears, a planetary carrier, and an eccentric shaft. The motor is connected to a cycloidal-pin gear reducer, thereby achieving the technical effect of enhancing the impact resistance and reverse actuation capability of the actuator. The rotor is disposed outside the stator, the eccentric shaft is connected to the rotor, and the reducer is disposed inside the motor, thereby achieving the technical effect of integrating the motor and the reducer and reducing the axial dimension of the actuator. The cycloidal gears are provided with round holes and special-shaped holes, and the planetary carrier is provided with round dowel pins and special-shaped dowel pins; under a rated load, the round holes are in contact with the round dowel pins, and the special-shaped holes are not in contact with the special-shaped dowel pins; and under a load above the rated load, the round holes and the round dowel pins extrude each other to achieve an allowable deformation, and the special-shaped holes are in contact with the special-shaped dowel pins, thereby achieving the technical effect of changing the stiffness of the actuator.

A robot system and a method for driving a robot capable of moving the position of the center of gravity of the robot while minimizing the increase in the footprint thereof are provided. A robot system according to an aspect of the present disclosure includes a robot. The robot includes a movable moving part, an upper body part disposed above the moving part, and a driving mechanism for tilting the upper body part and moving a lower end of the upper body part in a direction in which the upper body part is tilted.

A supernumerary robotic limb (SRL) system can include a plurality of rigid links, a joint that connects one rigid link to another rigid link in the plurality of rigid arms, and two variable stiffness actuators (VSAs) configured to drive the plurality of rigid links in order to complete at least one task. The VSAs can exhibit infinite rotation and infinite stiffness. The VSAs can include an output link. Additionally, the VSAs can include a set of elastic elements mounted on the output link. The VSAs can include an input link configured to provide kinetic energy for the output link. The VSAs can include a dynamic chassis configured to connect with the input link. Additionally, the VSAs can include a stiffness adjustor included in the dynamic chassis and configured to adjust an elastic transmission between at least one elastic element of the set of elastic elements and the output link.

An apparatus includes a spindle platform; a traversing platform configured to move in a first direction; a lift system connected to the spindle platform and the traversing platform, the lift system configured to move the spindle platform in a second direction perpendicular to the first direction; a movable arm connected to the spindle platform, the movable arm including a first link connected to the spindle platform, a second link connected to the first link, and a third link connected to the second link, and a first actuator connected to the spindle platform and configured to cause a rotation of the first link, and a second actuator in the movable arm and configured to cause a rotation of the second link. The first actuator extends from the spindle platform into the first link to occupy a combined thickness of the spindle platform and the first link.