A device including a housing configured to attach to a robot arm, and a multi-axis motion sensor provided within the housing. The multi-axis motion sensor is configured to detect movement of the housing, and is configured to communicate with a controller of the robot arm. The device further includes a user interface configured to operate in conjunction with the multi-axis motion sensor, and a connection port provided on the housing. The connection port is configured to connect to an external device.

A device including a housing configured to attach to a robot arm, and a multi-axis motion sensor provided within the housing. The multi-axis motion sensor is configured to detect movement of the housing, and is configured to communicate with a controller of the robot arm. The device further includes a user interface configured to operate in conjunction with the multi-axis motion sensor, and a connection port provided on the housing. The connection port is configured to connect to an external device.

A wearable apparatus for measuring position and action of an arm includes: a main frame worn on an upper body of a user; and an arm motion-measuring unit connected to a side of the main frame, having a plurality of joints, and worn on an arm of a user, in which at least any one of the joints of the arm motion-measuring unit has a straight-motional degree of freedom. Accordingly, an instructor can conveniently move both arms in the apparatus, can precisely instruct a two-arm robot in motions of the instructor's arms, can reduce learning time of the robot, and can make the robot quickly and accurately learn the motions.

The invention relates to a device (2, 6) for manually controlling a robot system, comprising an input device (2), which can be operated by means of at least two hands and has a sensor system (7, 10) for detecting control specifications of a first hand (12) and control specifications of a second hand (13). According to the invention, the control device (2, 6) comprises a first control unit (19), which performs a position control function in dependence on the control specifications of the first hand (12), and a second control unit (20), which performs a velocity control function or a position control function in dependence on the control specifications of the second hand (13).

The invention relates to a device (2, 6) for manually controlling a robot system, comprising an input device (2), which can be operated by means of at least two hands and has a sensor system (7, 10) for detecting control specifications of a first hand (12) and control specifications of a second hand (13). According to the invention, the control device (2, 6) comprises a first control unit (19), which performs a position control function in dependence on the control specifications of the first hand (12), and a second control unit (20), which performs a velocity control function or a position control function in dependence on the control specifications of the second hand (13).

A robotic navigation system includes a handheld navigation unit associated with a frame of reference. The handheld navigation unit is moveable with respect to a plurality of axes and is configured to send movement signals based on movement of the handheld navigation unit. A controller is configured to receive the movement signals from the handheld navigation unit and determine control signals for the robot. The control signals are configured to incrementally move the robot with respect to a point of interest removed from the robot. The point of interest is removed from a fixed point on the robot as defined by assigned coordinates. The controller is further configured to reassign the assigned coordinates following each incremental movement of the robot.

Disclosed herein is a method, system, and non-volatile storage medium for simplifying the automation of a process of flow. The method may include determining a machine-independent process model based on data representing a handling of a work tool for performing a process flow. The process flow may include a plurality of sub-processes and the process model may link a process activity with spatial information for each sub-process. The method may also include mapping the machine-independent process model to a machine-specific control model of a machine using a model of the machine. The machine-specific control model may define an operating point of the machine for each sub-process, and the operating point may correspond to the process activity and to the spatial information.

A robot system includes: a robot; a robot controller configured to control the robot based on sequential taught positions; and a teaching device communicative with the robot controller and configured to receive operations by an operator, wherein the robot controller includes circuitry configured to: generate, in response to determining that a target position is designated by the operator on the teaching device, a path from a current position of the robot to the target position by simulation of moving the robot based on surrounding environmental information of the robot; and move the robot toward the target position along the generated path.

A robot system includes: a robot; a robot controller configured to control the robot based on sequential taught positions; and a teaching device communicative with the robot controller and configured to receive operations by an operator, wherein the robot controller includes circuitry configured to: generate, in response to determining that a target position is designated by the operator on the teaching device, a path from a current position of the robot to the target position by simulation of moving the robot based on surrounding environmental information of the robot; and move the robot toward the target position along the generated path.