A deadlock avoidance motion planning technique for a multi-robot system. The technique includes online calculation of swept volumes for upcoming robot motion segments, and uses the swept volumes to compute one or more overlap zones, which are published to all robot controllers. Swept volume calculation is based on actual upcoming tool path, including adaptive conditions such as jumps and offsets. Robot controllers check at each time step whether an overlap zone will be entered and whether another robot is already in the zone. When a robot determines that it is about to enter a zone that is occupied, the robot holds position until the zone is vacated. Robots publish zone entry and exit for other robots’ awareness. Additional logic is added to establish priority for automatically resolving a deadlock condition, and for prioritizing completion of motion segments for a robot which is performing a continuous processing operation.

A packaging technique for applying an insulating pack to the housing of a battery cell. The insulating pack is formed from a self-adhesive cutout of insulating material by folding the cutout onto the sides of the housing that are to be covered. The packaging technique involves a packaging method for automatically applying an insulating pack, a battery cell including an insulating pack, a packaging station for carrying out the method, and a preparation device for preparing one or more cutouts of insulating material.

An example medical device may include a first component including an interface, a light feature surrounding at least part of the interface, and a controller coupled to the light feature and including a memory in which are stored instructions for the controller causing a first illumination state of the light a feature corresponding to a first state of the interface, and the controller causing a second illumination state of the Sight feature corresponding to a second state of the interface.

A cover for an automated robot includes elastic sheets that are adhered to each other in a geometry. The geometry is configured to allow the elastic sheets to expand and contract while the automated robot moves within its range of motion. The elastic sheets are attached to the automated robot by elasticity of the elastic sheets. A first group of the elastic sheets forms an elastic collar configured to grip the automated robot at a distal end and a proximal end of the cover in a non-breakable manner such that during operation of the robot, the elastic sheets hold their elasticity and integrity without breaking.

Disclosed herein are a method of identifying a dynamic obstacle and a robot implementing the same, wherein the robot configured to identify a dynamic obstacle may change mechanisms for identifying an obstacle in an image captured by a camera sensor in a first direction and for sensing the obstacle on the basis of a velocity of movement of the identified obstacle, a degree of congestion based on distribution of the obstacle and a velocity of movement of the robot, to generate a moving path of the robot.

A functional safety system performs safety analysis on three-dimensional point cloud data measured by a time-of-flight (TOF) sensor that monitors a hazardous industrial area that includes an automation system. To reduce the amount of point cloud data to be analyzed for hazardous conditions, the safety system executes a real-time emulation of the automation system using a digital twin and live controller data read from an industrial controller that monitors and controls the automation system. The safety system generates simulated, or shadow, point cloud data based on the emulation and subtracts this simulate point cloud data from the measured point cloud data received from the TOF sensor. This removes portions of the point cloud data corresponding to known or expected elements within the monitored area. Any remaining entities detected in the reduced point cloud data can be further analyzed for safety concerns.

A collision avoidance method according to the present invention avoids collision of a robot arm 120 including an upper arm part 122 and a forearm part 124 connected to each other via an elbow part 134 with an obstacle. Movable areas of the upper arm part 122 and the forearm part 124 in a state in which positions of both ends of the robot arm 120 have been fixed are calculated. Intersections of the movable areas with a first line on a boundary surface of an obstacle area including the obstacle are calculated. A collision avoidance range in which the robot arm 120 does not collide against the obstacle area in the movable areas is determined based on the intersections that have been calculated.

A robotic device includes a kinematic chain of a plurality of components, movable relative to each other; a sensor device configured to capture a force and/or moment exerted on at least one of the mobile components; a control device configured to control a movement of the at least one of the mobile components, in the direction of the force that is exerted, as a function of the force captured by the control device and/or of the moment captured by the control device; and a first capture device coupled to the control device and provided for the purpose of contactlessly capturing an operating action of an operator. In a normal operating mode, the control device is configured to specify a mobility of at least one of the mobile components as a function of the captured operating action, improving accuracy and reliability of the device in interaction with a human operator.

A human cooperation robot system includes: an external force detecting unit that detects an external force acting on a robot; a retreat operation commanding unit that commands a retreat operation for causing the robot to be moved in a direction such that the external force is decreased when the external force detected by the external force detecting unit is greater than a first threshold value; and an external force variation monitoring unit that stops the retreat operation when a variation width of the external force at a predetermined time after the retreat operation is commanded by the retreat operation commanding unit is smaller than a second threshold value.

Systems and methods for operating robotic equipment in a controlled zone are presented. The system comprises one or more self-driving material-transport vehicles having at least one sensor, non-transitory computer-readable media, and a processor in communication with the at least one sensor and media. The media stores computer instructions that configure the processor to move the vehicle towards the controlled zone in a normal mode of operation, capture environmental data associated with the controlled zone using the at least one sensor, determine environmental-change data based on comparing the captured environmental data with known-good environmental data, and operating the vehicle in a safe mode of operation based on the environmental-change data.