A rotary-type series elastic actuator (SEA) for use in robotic applications. The SEA including a motor, gear transmission assembly, spring assembly, and sensors. In one example, a robotic joint may include the SEA as well as two links coupled with each other at the joint assembly. The two links may be designated as input and output links. Each link may have a joint housing body which may be concentrically connected via a joint bearing so that they freely rotate against each other. The housing frame of the SEA may be fixed at the joint housing body of the input link while the output mount of the spring assembly of the SEA may be concentrically coupled with the joint housing body of the output link. The rotation of the motor rotor causes the rotation of the output link with respect to the input link plus spring deflection of the spring assembly. When an external force or torque are applied between the two links, a control action of a control loop may cause a rotation and motive force of the motor that lead to the deflection of the spring assembly to balance with the external force/torque and inertial force from body masses moving together with the links.

A robot control device (10) includes an attribute determination unit (71) that determines an attribute of an object person (T) around a robot (1); and a decision unit (74) that decides a notification action of notifying, by the robot (1), the object person (T) of presence of the robot (1), on the basis of the attribute determined by the attribute determination unit (71) and a risk of harm that may be caused to the object person (T) by the robot (1).

A deterioration determination apparatus according to one or more embodiments may include: an information obtainment unit configured to obtain information on deformation of a suction portion that is configured to hold an object by suction with negative pressure and elastically deforms by the negative pressure; and a deterioration determination unit configured to determine whether or not the suction portion has deteriorated, depending on the deformation of the suction portion occurring when the suction portion holds the object by suction.

A deterioration determination apparatus according to one or more embodiments may include: an information obtainment unit configured to obtain information on deformation of a suction portion that is configured to hold an object by suction with negative pressure and elastically deforms by the negative pressure; and a deterioration determination unit configured to determine whether or not the suction portion has deteriorated, depending on the deformation of the suction portion occurring when the suction portion holds the object by suction.

A method for maintaining, commissioning and checking systems in warehouses, where a service technician has a view of the respective system and makes wireless contact with the controller of the system via a mobile computer in order to take over control thereof, where the taking over of control by the mobile computer is permitted by a central controller only if the service technician can have visual contact with the corresponding system, for which purpose the determination of the position and/or the orientation of the mobile computer of the service technician with respect to the respective system is effected via optical and/or acoustic recognition of a fingerprint of the system.

Systems and methods for determining safe and unsafe zones in a workspace—where safe actions are calculated in real time based on all relevant objects (e.g., some observed by sensors and others computationally generated based on analysis of the sensed workspace) and on the current state of the machinery (e.g., a robot) in the workspace—may utilize a variety of workspace-monitoring approaches as well as dynamic modeling of the robot geometry. The future trajectory of the robot(s) and/or the human(s) may be forecast using, e.g., a model of human movement and other forms of control. Modeling and forecasting of the robot may, in some embodiments, make use of data provided by the robot controller that may or may not include safety guarantees.

Systems and methods for determining safe and unsafe zones in a workspace—where safe actions are calculated in real time based on all relevant objects (e.g., some observed by sensors and others computationally generated based on analysis of the sensed workspace) and on the current state of the machinery (e.g., a robot) in the workspace—may utilize a variety of workspace-monitoring approaches as well as dynamic modeling of the robot geometry. The future trajectory of the robot(s) and/or the human(s) may be forecast using, e.g., a model of human movement and other forms of control. Modeling and forecasting of the robot may, in some embodiments, make use of data provided by the robot controller that may or may not include safety guarantees.

A method for monitoring a robot arrangement, which robot arrangement has at least one robot includes capturing optical signals from a plurality of signal sources at least one sensor, wherein the signal sources and/or the sensor is/are positioned on the robot arrangement and triggering a monitoring reaction if a deviation of an actual arrangement of the captured optical signals from a desired arrangement of these signals exceeds a limit value. In one aspect, a reaction may be triggered if at least a predefined minimum number of signals from the desired arrangement is not present in the actual arrangement of the captured optical signals.

A method for operating a robotic arm using a first visualization device includes visually indicating, on the robotic arm and/or in the workspace of the robotic arm and/or on a work surface below the robotic arm, an imminent adjustment of at least one axis of the robotic arm, in particular of at least one axis closest to the robotic arm base.

A method for operating a robotic arm using a first visualization device includes visually indicating, on the robotic arm and/or in the workspace of the robotic arm and/or on a work surface below the robotic arm, an imminent adjustment of at least one axis of the robotic arm, in particular of at least one axis closest to the robotic arm base.