Abstract: A method for correcting a robot is provided. The method includes: providing a correction device, wherein the correction device comprises a jig wafer; grabbing and/or transferring the jig wafer by using the robot to obtain collected data; determining, based on the collected data, whether the robot needs to be corrected; and in response to that the robot needs to be corrected, obtaining a compensation value according to the collected data, and correcting the robot based on the compensation value.

Abstract: A robot control device that controls a robot including a driving section configured to drive an arm based on an operation command value and a first encoder section configured to output a first encoder value, the robot control device including a first command-value comparing section, a first mutual monitoring section, a second command-value comparing section, a second mutual monitoring section, and a power interrupting section. The first-command value comparing section performs comparison processing for a command value and a first encoder value and outputs a first command value comparison result. The second command-value comparing section performs comparison processing for the command value and the first encoder value and outputs a second command value comparison result. The first mutual monitoring section and the second mutual monitoring section output an interruption signal based on the first command value comparison result and the second command value comparison result.

Abstract: A robot control method for controlling a robot is provided. The robot has a robot arm and a force detection unit detecting a force applied to the robot arm and grips a target object conveyed on a belt with an end effector provided at the robot arm. The method includes: a gripping step of executing an operation of gripping the target object with the end effector; and a determination step of determining whether the gripping of the target object is normally performed or not, based on a result of detection by the force detection unit in the gripping step.

Abstract: A soft joint gripper based on 4D printing comprises a palm body and five soft finger units connected with the palm body; each soft finger unit is provided with two soft finger joints and two finger bones; the finger bones are made of 3D printing resin; the soft finger joints are two symmetrical double-layer thin-film soft finger joint actuators; the double-layer thin-film soft finger joint actuator is made of a 4D printing liquid crystal elastomer and a polyimide electrothermal film, and the bending angle of each double-layer thin-film soft finger joint actuator is changed by energization or heating stimulation; and the double-layer film soft finger joint actuator is used to control the soft finger unit to perform reversible bending motion. Accurate control of the soft joint gripper can be realized.

Abstract: A robotic system for use with a payload includes a robot, a passive compliance mechanism, position sensors, and an electronic control unit (ECU). Actuated joints of the robot provide the robotic system with actuated degrees of freedom (DOF). The compliance mechanism is connected to the robot and payload, and has unactuated joints providing the robotic system with unactuated DOF. The sensors measure joint positions of the joints. The ECU has a trajectory generator block which generates a payload trajectory signal in response to dynamic control inputs, and an impedance control unit (ICU) applying damping and stiffness parameters to the payload trajectory signal to generate an initial velocity command. A stiction compensation block allows the robotic system to generate a velocity offset, and applies the velocity offset to the initial velocity command to produce a final velocity command for the robot.