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.

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.

The robot controller includes an operation command part configured to output an operation command so as to perform a first operation of conveying a workpiece from an initial position to a first position adjacent to the machine tool, a time prediction part configured to predict processing completion time of the workpiece based on a processing start signal output from a machine tool controller, a time length prediction part configured to predict time length necessary for the first operation, and a time determination part configured to determine start time of the first operation so that the first operation is completed at the processing completion time on the basis of the predicted processing completion time and time length necessary for the first operation.

In a production system general-purpose cell for general-purpose use in processing and transportation of a received workpiece in a production system of processing and delivering the workpiece, the production system general-purpose cell includes a base unit having a planar shape of quadrangle and supporting at least a robot for use in transportation of the workpiece such that the robot is movable on the planar area of quadrangle, a parts supply unit for supplying parts of the workpiece to the robot supported by the base unit, and a processing area extending outside the base unit. The robot supported by the base unit having a motion range set in a range from inside to outside the base unit in a form including at least part of the processing area.

Provided is a cell controller for controlling an operation of a machining cell including two or more machines and one or more robots as work resources, the cell controller being configured to control the operation of the machining cell based on a production program recorded with one or more processes to be executed at the time of producing only one article of a corresponding item in the machining cell among production programs prepared corresponding to one or more items produced in the machining cell.

Method carried out by a control unit of a collaborative work cell of managing the collaborative work cell comprising at least one work plane, a tool store, a user interface connected to the control unit, and an automatic operating device connected to the control unit, wherein the method comprises the following steps: receiving a first input comprising an indication on a type of operation to execute, wherein the first input is entered by an operator on the user interface; controlling the automatic operating device to execute an operation on the basis of the indication on the type of operation to execute comprised in the first input.

A robot management system (RMS) includes a plurality of service robots deployed within an operations venue that includes a plurality of gaming devices, an operator terminal presenting a graphical user interface (GUI) to an operator, and a robot management system server (RMS server) configured in networked communication with the plurality of service robots. The RMS server is configured to: identify location data for the service robots; create an interactive overlay map of the operations venue that includes a static map of the operations venue, overlay data showing the location data of the plurality of service robots over the static map, and an interactive icon for each service robot of the plurality of service robots; display, via the GUI, the overlay map; receive a first input indicating a selection of a first interactive icon associated with a first service robot; and display current status information associated with the first service robot.

A manufacturing matrix can include a plurality of work cells. The manufacturing matrix can include a plurality of robotic arms disposed in the plurality of work cells to produce a construction product. The manufacturing matrix can include a storage location to store inventory including at least one of the material, the tool, the subassembly of the construction product, or a completed construction product. The manufacturing matrix can include a transportation system to move the inventory within the manufacturing matrix. The manufacturing matrix can include a data processing system communicably coupled with the plurality of robotic arms and the transportation system. The data processing system can provide a first instruction to a first robotic arm cell and a second instruction to a second robotic arm of the second work cell.

A cell controller controls a machining cell including a plurality of work resources. The plurality of work resources include at least one processing machine and at least one robot. The cell controller includes a PLC and a management device. The PLC controls operation of the work resources in accordance with an instruction from the management device, and acquires conditions of a plurality of work elements including the work resources and a workpiece. The management device, in response to occurrence of abnormal stop of the machining cell, specifies a recoverable condition of each work element, and presents to an operator a guide to a recovery procedure that enables each work element to transition to the recoverable condition.