A trajectory information generating unit is included, the trajectory information generating unit generating trajectory information that defines a trajectory for which a picking hand picks one of one or more works stored in one supply container included in one or more supply containers and arranges the work in one arrangement container included in one or more arrangement containers. After performing a process of generating trajectory information representing a first work included in the one or more works and before a movement of the first work is completed, the trajectory information generating unit may generate trajectory information representing a second work included in the one or more work and different from the first work by using an operation result in the process of generating the trajectory information regarding the first work.

A robot controller for controlling motion of a robot includes a motion control unit configured to control the motion of the robot in accordance with an operation program, a motion path storage unit configured to store a motion path of a predetermined movable part of the robot when the robot operates in accordance with the operation program, a restricted motion area generation unit configured to generate restricted motion area data representing a restricted motion area for restricting the motion of the robot based on the stored motion path, and a motion restriction unit configured to restrict the motion of the robot in the restricted motion area based on the restricted motion area data.

The embodiments relate to a method for operating a medical robotic device with an end effector for performing a diagnostic and/or therapeutic measure, involving predetermining at least one position to be reached by the end effector, evaluating at least two movement sequences of the medical robotic device, by which the end effector reaches the respectively predetermined at least one position, using an optimization criterion to select the movement sequence with the best evaluation result as the optimum movement sequence and implementing the optimum movement sequence, so that the respective predetermined position is reached by the end effector, in order to improve the reaching of the predetermined position.

A method is presented. A tool path having planar parallel alternating paths connected by a plurality of curved transitions is generated. A forming tool is driven along the planar parallel alternating paths and the plurality of curved transitions to shape a material into a workpiece.

A disclosed robot system enables an operator of an articulating arm used in fabricating window or door frames to recover the position of the tools during the cleaning process with minimal knowledge or training on a robot. The disclosed robot system also gives the operator the ability to edit a tool cleaning path with simple commands from an operator interface (e.g., HMI) to bring flexibility in customizing the use of the articulating arm.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for controlling a robot to perform a custom real-time action that uses streaming inputs. One of the methods comprises receiving a definition of a custom real-time streaming control function that defines a custom streaming action, wherein the custom streaming action specifies a goal state for a robot in an operating environment; providing a command to initiate the custom streaming action; and repeatedly providing updated goal states for the custom streaming action, wherein the control layer of the framework is configured to execute the custom streaming action including driving the robot toward a most recent goal state at each tick of a real-time robotics control cycle.

A coordination system for a handling device including a plurality of kinematic chains is provided. Each of the kinematic chains being movable in a workspace. At least two of the workspaces having an overlap, the kinematic chains being designed to carry out a work movement based on a work command. The coordination system includes a trajectory planning module and a control module. The control module is designed to activate the kinematic chains to carry out the work movement based on trajectory data. The trajectory planning module is designed to determine the trajectory data to carry out the work movement and to provide the trajectory data to the control module. The trajectory planning module is designed, if a further work command is provided while the work movement is being carried out, to replan the trajectory data into replanned trajectory data and provide these data to the control module.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for controlling a robot to perform a custom real-time action that uses a callback function. One of the methods comprises receiving a definition of a custom real-time control function that specifies a custom callback function, an action, and a custom reaction that references the custom callback function; providing a command to initiate the action; repeatedly executing, by the control layer of the real-time robotics control framework, the custom real-time control function at each tick of a real-time robotics system driving one or more physical robots, including: obtaining current values of one or more state variables, evaluating the custom reaction specified by the custom real-time control function according to the current values of the one or more state variables, and whenever the one or more conditions of the custom reaction are satisfied, invoking the custom callback function.

The invention includes systems and methods for determining movement of a robot. A computing system of the robot receives information comprising a reference behavior specification, a current state of the robot, and a characteristic of a massive body coupled to or expected to be coupled to the robot. The computing system determines, based on the information, a set of movement parameters for the robot, the set of movement parameters reflecting a goal trajectory for the robot. The computing system instructs the robot to move consistent with the set of movement parameters.

A method of coordinating automated systems, the method includes providing a first automated system that is programmed with a set of predetermined operating instructions that correspond with automated system processing requirements, monitoring an operational status of the first automated system with a second automated system, automatically generating a second system action, with the second automated system, that is complementary to a first system action of the first automated system, where the first system action corresponds to the set of predetermined operating instructions and the second system action depends on the operational status of the first automated system, and performing the second system action with the second automated system so that the second automated system cooperates with the first automated system to perform a predetermined operation.