A teaching device generating an operation program for executing an operation of a robot having a base and a robot arm including a proximal arm coupled to the base and a distal arm coupled to a side opposite to the base of the proximal arm is provided. The teaching device includes: a display unit displaying a first operation unit accepting an operation of designating the proximal arm of the robot arm and changing an attitude of the robot arm and a second operation unit accepting an operation of designating a position of a control point set for the robot arm and changing the attitude of the robot arm; and an operation program generation unit generating the operation program, based on the attitude designated at the first operation unit or the second operation unit.

A teaching device includes: a display unit displaying a first icon showing a first attitude of a robot arm, a second icon showing a second attitude of the robot arm, and a first operation unit for performing an operation of designating a third attitude of the robot arm, the first attitude being a state where an angle formed by a first arm and a second arm of the robot arm is a first angle, the second attitude being a state where the angle formed by the first arm and the second arm is a second angle that is different from the first angle, the third attitude being a state where the angle formed by the first arm and the second arm is a third angle equal to or greater than the first angle and equal to or smaller than the second angle; and an operation program generation unit generating the operation program, based on the third attitude designated at the first operation unit.

A user interface (UI) mapper for robotic process automation (RPA) is disclosed. The UI mapper may initially capture UI elements to fetch UI elements faster for later use and allow an RPA developer to “map” the UI elements for automating an application. This may enable subsequent developers who potentially do not have programming knowledge to build RPA workflows using these predefined “target” UI elements.

A robot control device configured to control a robot includes a first memory part configured to store work data, a second memory part configured to store restoring data, a calculating part configured to perform an operation instructing process configured to read the work data and generate an operating instruction to the robot, and a data evacuation process configured to determine whether the operation instructing process operates normally, and when the calculating part determines that the operation instructing process does not operate normally, coincide the restoring data with the work data, and an operation controlling part configured to control operation of the robot based on the operating instruction.

Disclosed are various embodiments of a three-dimensional perception and object manipulation robot gripper configured for connection to and operation in conjunction with a robot arm. In some embodiments, the gripper comprises a palm, a plurality of motors or actuators operably connected to the palm, a mechanical manipulation system operably connected to the palm, a plurality of fingers operably connected to the motors or actuators and configured to manipulate one or more objects located within a workspace or target volume that can be accessed by the fingers. A depth camera system is also operably connected to the palm. One or more computing devices are operably connected to the depth camera and are configured and programmed to process images provided by the depth camera system to determine the location and orientation of the one or more objects within a workspace, and in accordance therewith, provide as outputs therefrom control signals or instructions configured to be employed by the motors or actuators to control movement and operation of the plurality of fingers so as to permit the fingers to manipulate the one or more objects located within the workspace or target volume. The gripper can also be configured to vary controllably at least one of a force, a torque, a stiffness, and a compliance applied by one or more of the plurality of fingers to the one or more objects.

In a method for operating a computer having a user interface, e.g., a graphical and/or interactive user interface, a robot, which has members, e.g., arms, rotatable relative to each other and a tool and/or a load, are displayed graphically. One of the members is selectable from an indicated set of members, and a value of an inertial characteristic, e.g., a value of the mass, of this member is able to be inputted. The value of the mass of the member, the position of the center of mass of the member, and both the magnitude and the direction of each of the principal axes of inertia of the selected member are displayed graphically.

A robotic process automation system includes a server processor that performs an automation task to process a work item, by initiating a java virtual machine on a second device. A first user session that employs credentials of a first user for managing execution of the automation task is also initiated on the second device. The server processor loads into the java virtual machine, with a platform class loader, one or more modules, such as logging and security, that perform functions common to the sets of task processing instructions. A first class loader a first set of task processing instructions is also loaded. Then each instruction in the first set of task processing instructions is loaded with a separate class loader. The server processor causes execution, under control of the first user session, on the second device, the task processing instructions that correspond to the work item.

A method of programming an industrial robot includes: providing the robot, the robot having a robot arm with an end-effector mounted thereto which is controlled by a robot control unit to manipulate a workpiece which is arranged in a workplace of the robot; associating a target coordinate system with the workplace; taking an image of the workplace and the workpiece by an image capturing device; transmitting the image to a computing device having a human-machine-interface to generate control code for controlling the robot, which is transmitted to the robot control unit; capturing an image of the workplace and the workpiece to be manipulated by the robot; transferring the captured image to the computing device and displaying the captured image on a display associated with the computing device; and displaying the workpiece on the display; marking the workpiece with a marker-object on the display.

A robot system including at least one robot arm and a control unit which is designed such that it can pre-set at least one pre-defined operation carried out by the robot system. The robot system also includes a display device and at least one input device applied to the robot arm, which is designed such that the sequence of operations of the robot system is set and/or the pre-defined operations of the robot system is parameterized by means of the input device, and which is also designed such that it allows the user to control, on a graphic user interface, represented by the control unit on the display device, the setting of the pre-defined operations of the robot system, the setting of the sequence of operations and/or the parameterization of the pre-defined operations for the robot system.

To generate an easy-to-understand program for a robot in a simple way. A robot programming device performs programming using an operation unit block. The robot programming device includes a display control unit that displays a programming region and an advanced setting region on a display unit. The programming region is a region for programming for running the robot by setting an operation unit block defined for each operation unit of the robot. The advanced setting region is a region for making setting relating to the operation unit block.