A method of safety monitoring for a robot assembly with at least one robot that is configured with a linking function arrangement with at least one first linking function including a fixed and predetermined number of monitoring functions of a monitoring function arrangement. The monitoring functions are logically linked to one another such that the first linking function has a reaction state whenever all of the monitoring functions indicate the violated and/or error state. The first linking function does not have a reaction state whenever any monitoring function from the plurality of monitoring functions does not indicate the violated and/or error state. The reaction state is executed by the controller when all of the monitoring functions are in the violated and/or error state.

An abnormality detection method of an encoder includes an output step, a control step, an information acquisition step, and an abnormality determination step. The abnormality determination step compares command position information with detection position information of a motor calculated based on an output signal, and determines that the encoder is abnormal in a case where a difference between the command position information and the detection position information of the motor is equal to or more than a predetermined value.

An abnormality detection method of an encoder includes an output step, a control step, an information acquisition step, and an abnormality determination step. The abnormality determination step compares command position information with detection position information of a motor calculated based on an output signal, and determines that the encoder is abnormal in a case where a difference between the command position information and the detection position information of the motor is equal to or more than a predetermined value.

Examples are provided that describe a motion based light display for a robotic arm. In one example, a robotic device comprising one or more components configured to be actuated for movement. The robotic device also includes one or more processors are configured to determine a motion per path metric of the one or more components based on a motion plan associated with the robotic device. The one or more processors are configured to determine one or more feedback characteristics based on the motion per path metric. The one or more feedback characteristics include information indicative of an effect of motion associated with the one or more components. The robotic device also includes an indicator coupled to the one or more components and configured to provide feedback about the one or more components based on the feedback characteristics indicative of the effect of motion.

Examples are provided that describe a motion based light display for a robotic arm. In one example, a robotic device comprising one or more components configured to be actuated for movement. The robotic device also includes one or more processors are configured to determine a motion per path metric of the one or more components based on a motion plan associated with the robotic device. The one or more processors are configured to determine one or more feedback characteristics based on the motion per path metric. The one or more feedback characteristics include information indicative of an effect of motion associated with the one or more components. The robotic device also includes an indicator coupled to the one or more components and configured to provide feedback about the one or more components based on the feedback characteristics indicative of the effect of motion.

A system for promoting safety of a robotic appendage includes: a robot controller; and a robot controllable by the robot controller, the robot controller configured to compute an estimated power draw of a planned trajectory of the robot, the robot controller further configured to modify the planned trajectory to prevent the estimated power draw from exceeding a power limit; the robot comprising: an appendage; an appendage controller configured to control the appendage; and a breaker configured to limit power delivered to the appendage. A system for promoting safety of a robotic appendage includes a plurality of robots operably connected with each other, the robots configured to communicate with each other regarding estimated power draw characteristics.

A method estimates a position where an abnormality has occurred. The method for estimating a position where an abnormality has occurred in a robot includes an abnormality detection step of detecting occurrence of an abnormality, and a position detection step of detecting a position where the abnormality has occurred when the occurrence of the abnormality is detected in the abnormality detection step.

A method estimates a position where an abnormality has occurred. The method for estimating a position where an abnormality has occurred in a robot includes an abnormality detection step of detecting occurrence of an abnormality, and a position detection step of detecting a position where the abnormality has occurred when the occurrence of the abnormality is detected in the abnormality detection step.

The invention relates to a device and to a method for open-loop/closed-loop control of a robot manipulator (202), which comprises a sensor (203) for detecting an interaction with an environment. The proposed method is characterized in that a force-time curve of an external force (I) acting on the robot manipulator (202) is detected by the sensor (203), and, if the value of the detected force (II) is higher than a defined threshold value G1: (II)>G1, a safety mode of the robot manipulator (202) is activated, which open-loop controls a movement speed (III) and/or a movement direction (IV) depending on the detected force (I), wherein the movement speed (III) and/or the movement direction (IV) of the robot manipulator (202) is/are open-loop/closed-loop controlled depending on predetermined medical injury parameters before the safety mode is activated.

The invention relates to an automatic automated installation in which at least one robot (2) is used in at least one mode of operation in at least one work zone (3). The installation comprises a closed space (1) equipped with at least one door (4) offering access to at least one operator intervention work station (6) which is situated in said work zone (3) of said robot, and means (7) for detecting the presence of an element (25; 26) in said closed space (1) at said operator intervention work station (6). The detection means (7) are arranged in said closed space (1) to delimit at least two zones (8, 9, 10) and are also associated with means (21) for control of said at least one mode of operation of the robot (2), each zone (8, 9, 10) being associated with one mode of operation of the robot (2). The detection means (7) are positioned a predetermined height from a floor (18) of said space (1), said height being greater than the height of an empty pallet (12).