A position correcting system, method and tool for guiding a tool during its use based on its location relative to the material being worked on. Provided is a system and tool which uses its auto correcting technology to precisely rout or cut material. The invention provides a camera which is used to track the visual features of the surface of the material being cut to build a map and locate an image on that map used to reference the location of the tool for auto-correction of the cutting path.

The present disclosure provides an impedance control method for a biped robot as well as an apparatus and a biped robot using the same. The method includes: correcting an impact force on a landing leg in the two legs of the biped robot using a natural attenuation function, and taking the corrected impact force as an input of an impedance control; obtaining an impedance model of the biped robot; determining a transfer function of the impedance control based on the impedance model; calculating an output of the impedance control based on the input of the impedance control and the transfer function of the impedance control; determining a joint angle of each joint based on the output of the impedance control and a planned pose of the biped robot; and transmitting joint angle information of each joint to motor(s) of the joint to perform the impedance control.

A method for automatically ascertaining an input command for a robot, wherein the input command is entered by manually exerting an external force onto the robot. The input command is ascertained on the basis of the joint force component attempting to cause a movement of the robot in only one robot joint coordinate sub-space which is specific to the input command. The joint forces are imprinted with the external force.

A position correcting system, method and tool for guiding a tool during its use based on its location relative to the material being worked on. Provided is a system and tool which uses its auto correcting technology to precisely rout or cut material. The invention provides a camera which is used to track the visual features of the surface of the material being cut to build a map and locate an image on that map used to reference the location of the tool for auto-correction of the cutting path.

A position correcting system, method and tool for guiding a tool during its use based on its location relative to the material being worked on. Provided is a system and tool which uses its auto correcting technology to precisely rout or cut material. The invention provides a camera which is used to track the visual features of the surface of the material being cut to build a map and locate an image on that map used to reference the location of the tool for auto-correction of the cutting path.

Systems and methods of the present disclosure relate generally to facilitate performing a task on a surface such as woodworking or printing. More specifically, in some embodiments, the present disclosure relates to mapping the surface of the material and determining the precise location of a tool in reference to the surface of a material. Some embodiments relate to obtaining and relating a design with the map of the material or displaying the current position of the tool on a display device. In some embodiments, the present disclosure facilitates adjusting, moving or auto-correcting the tool along a predetermined path such as, e.g., a cutting or drawing path. In some embodiments, the reference location may correspond to a design or plan obtained from obtained via an online design store

A control device that controls a drive unit included by a production line includes: an obtaining unit that obtains physical information indicating a variation with time of a posture of a worker at work; a storage for storing physical information of the worker obtained when the worker works in a stable posture; a detection unit that detects a difference between a magnitude of the variation with time indicated by the physical information obtained and a magnitude of a variation with time indicated by the physical information stored in the storage; and a determination unit that determines from the detected difference whether to change an amount of controlling the drive unit.

The present disclosure provides an impedance control method for a biped robot as well as an apparatus and a biped robot using the same. The method includes: correcting an impact force on a landing leg in the two legs of the biped robot using a natural attenuation function, and taking the corrected impact force as an input of an impedance control; obtaining an impedance model of the biped robot; determining a transfer function of the impedance control based on the impedance model; calculating an output of the impedance control based on the input of the impedance control and the transfer function of the impedance control; determining a joint angle of each joint based on the output of the impedance control and a planned pose of the biped robot; and transmitting joint angle information of each joint to motor(s) of the joint to perform the impedance control.

A jointed mechanism includes a passive pendulum system attached to and suspended from the multi-axis robot. The system includes one or more position sensors configured to measure a joint angle on the pendulum system, at least one arm, and an end-effector attached to a distal end of the pendulum system. A controller implements a method to selectively control motion of the robot in a plurality of control modes. The control modes include a Cooperative Mode and an Autonomous Mode. The controller is configured to detect contact with the end-effector when operating in the Autonomous Mode, and to automatically initiate a control action in response to the contact. The pendulum system may be a parallelogram arrangement.

When a first condition that a time in which magnitude of a first detection force detected by a force detection unit is larger than a first force threshold value continued for a time longer than zero and shorter than a first time threshold value is satisfied in teaching, a movable unit is moved in a predetermined amount in a direction according to a direction of the first detection force. When a second condition that magnitude of a second detection force detected by the force detection unit is larger than a second force threshold value that is larger than the first force threshold value is satisfied during movement of an end effector, the movable unit is decelerated or stopped.