A robot programming device is provided with: a robot model movement unit that moves a prescribed movable part of a robot model from a first position to a second position in accordance with instruction content; an arm inversion detection unit that detects whether or not a prescribed state has occurred in which, when the prescribed movable part of the robot model is moved to the second position, any axis constituting the robot model is rotated 180°±a first prescribed value from a rotation angle serving as a reference; and an arm inversion correction unit that, when occurrence of the prescribed state has been detected for any axis constituting the robot model, corrects the posture of the robot model when the prescribed movable part is in the second position so that said axis is not in the prescribed state.

According to an aspect of the present disclosure, a computer-implemented includes creating a plurality of basic skill functions for a controllable physical device of an autonomous system. Each basic skill function includes a functional description for using the controllable physical device to interact with a physical environment to perform a defined objective. The method further includes selecting one or more basic skill functions to configure the controllable physical device to perform a defined task. The method also includes determining a decorator skill function specifying at least one constraint. The decorator skill function is configured to impose, at run-time, the at least one constraint, on the one or more basic skill functions. The method further includes generating executable code by applying the decorator skill function to the one or more basic skill functions, and actuating the controllable physical device using the executable code.

Provided is a programming device capable of reducing the load of an operator that creates a control program including a command corresponding to a function of an imaging device. Provided is a programming device for programming industrial machinery, the programming device including: a command generation unit that acquires information regarding an imaging device connected to a control device of the industrial machinery and that, on the basis of the acquired information, generates an icon or command statement expressing a command using an image acquired by the imaging device; and a command display unit that displays the generated icon or command statement on a display screen.

A display part of a mobile terminal displays an operation program. The operation program includes an operation icon indicating an operation of a robot or an operation tool, and an auxiliary icon having a shape sandwiching the operation icon. The auxiliary icon indicates control of adding an operation of the robot apparatus. The display part is configured to display a screen configured to set setting information related to the operation of the robot apparatus in such a manner that as operator is enabled to set the setting information. The display part displays the operation icon and the auxiliary icon so as to align the operation icon and the auxiliary icon in order of the operations of the robot apparatus.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium that distributes skill bundles that can guide robot execution. One of the methods includes receiving data for a skill bundle from a skill developer. The data can include a definition of one or more preconditions for a robotic system to execute a skill; one or more effects to an operating environment after the robotic system has executed the skill; and a software module implementing the skill. The software module can define a state machine of subtasks. A skill bundle can be generated from the data received from the skill developer. Data identifying the generated skill bundle can be added to a skill registry. The skill bundle can be provided to the execution robot system for installation on the robot execution system.

A control device includes: a processor that is configured to execute computer-executable instructions so as to control a robot, wherein the processor is configured to: display a first edit screen on which an operation sequence of the robot can be edited by selecting images representing one or more operations among images representing a plurality of operations and arranging the images on a screen, and a second edit screen on which the operation sequence expressed in a programming language, which is obtained by converting the operation sequence edited via the first edit screen is displayed and the operation sequence expressed in the programming language can be edited, on a display; and control the robot based on the operation sequence edited via at least one of the first edit screen and the second edit screen.

An improved method, system, and apparatus is provided to implement a general architecture for robot systems. A mode execution module is provided to universally execute execution modes on different robotic system. A system includes an execution module that receives software instructions in a normalized programming language. The system also includes an interface having a translation layer that converts the software instructions from the normalized language into robot-specific instructions that operate in a particular robotic system. The system further includes a controller that is communicatively coupled to the interface, wherein the controller receives the robot-specific instructions. Moreover, the system includes a robotic device that is operatively controlled by the controller by execution of the robot-specific instructions.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for a composability framework that supports the coordination of the low-level actions of multiple subsystems. One of the methods comprises receiving a multi-device application definition for a real-time robotic control system configured to perform operations comprising controlling a robotic execution environment having multiple robotic components, wherein the application definition comprises: one or more custom high-level software modules for each robotic component of the multiple robotic components; respective module interface definitions for each of the custom high-level software modules, wherein a module interface definition of a custom high-level software module specifies one or more asynchronous or real-time communication channels; and respective device interface definitions for each of the multiple robotic components; and processing the application definition to generate output programs to be executed respectively by the multiple robotic components.

A method for programming a robot for carrying out an activity, wherein the robot is equipped with a programmable control unit and the robot programs are created using a standard program generator, wherein the program generator converts one or more sequences of keywords into valid program code for the programmable control unit so the program generator, when converting the keywords in the respective sequence, retrieves information in a programming rulebook, from which the generator receives the program code appropriate for the respective robot type in the predefined syntax, and wherein the program generator combines the received program code sections to form a complete program code.

The robot control system includes a first control device and a second control device network-connected to the first control device to control a robot. The first control device includes a selection unit configured to enable any one of a plurality of sources that provide information about generation of a command instructing behavior of the robot, and a first communication unit configured to transmit a command generated according to the information from the enabled source in the plurality of sources to the second control device. The second control device includes a second communication unit configured to receive the command transmitted from the first control device, and a command value generation unit configured to sequentially generate a command value for driving each axis of the robot so as to provide the behavior instructed by the command from the first control device.