A manufacturing apparatus includes a manufacturing unit; a cover that includes a see-through portion; an input unit that occupies a predetermined area on a surface of the see-through portion and detects a contact to the predetermined area and outputs information regarding the detection; a display that displays a predetermined image at a position of the cover; and a controller that in response to a predetermined input to the input unit, controls the display to display the predetermined image at or near a position where the predetermined input is detected, controls the display to display a predetermined operation panel image as the predetermined image at or near a position on the cover that overlaps the input unit; and controls the manufacturing unit based on a detection position of the predetermined input on the predetermined operation panel image.

Various embodiments include a method for automatic programming. The method may include: receiving a user's request to create a first global parameter of a specific type by detecting the user's dragging a control corresponding to the specific type from a first user interface and dropping the control on a second user interface; displaying a first popup window for editing the first global parameter on the second user interface; receiving the user's editing operations on the first global parameter in the first popup window; creating the first global parameter according to the user's editing operations; and displaying a new added first card of the first global parameter in a list of global parameters on a third user interface.

A smartphone or other mobile computer device, general purpose or specialized, wherein the smartphone device is configured to actively control the configuration of one or more bladders, compartments, chambers or internal sipes and one or more sensors located in either one or both of a sole or a removable inner sole insert of the footwear of the user and/or located in an apparatus worn or carried by the user, glued unto the user, or implanted in the user. The one or more bladders, compartments, chambers, or sipes, and one or more sensors are configured for computer control. A sole and/or a removable inner sole insert for footwear, including one or more bladders, compartments, chambers, internal sipes and sensors in the sole and/or in a removable insert; or on an insole; all being configured for control by a smartphone or other mobile computer device, general purpose or specialized.

An industrial IDE supports development of control programming using an industrial domain-specific language (DSL) that allows control programming to be written using a scripted programming language having features catered to the industrial domain. The industrial DSL can simplify and streamline development of industrial control code relative to using conventional graphics-based control programming formats such as ladder logic, since a script-based industrial DSL can be used to write programming code using fewer mouse clicks relative to traditional control programming environments. Editing tools inherent to the industrial DSL can provide dynamic programming feedback that guides the developer through the process of developing control code. A development interface of the industrial IDE can comprises two editing windows that render the control program in a graphical format and in a text-based format simultaneously, allowing the user to edit the program in either format on the same interface.

A combination of electronic hardware, a microprocessor (embodied, e.g., in a personal-style computer (“PC”)), and control software blended together with unique systems integration techniques. When stationed at a machine tool, the result is an grated, interactive and intuitive machine tool or workstation capable of computer aided design (CAD), optional reverse engineering parts via coordinate measurement machining (CMM), toolpath generation computer aided manufacturing (CAM), and direct machine tool control (Direct CNC) by one person at one work station with a common human machine interface (HMI) and common file formats.

Techniques for configuring and presenting multiple languages at a user interface executing in an operating environment of a process plant include configuring, in a configuration environment, a multi-language interface object to indicate a plurality of languages that may be presented at the user interface. The multi-language interface object includes a parameter whose value is changeable, within the operating environment, to indicate a desired language that is to be presented on the user interface. A configuration of the graphical display view that references the configured multi-language interface object is downloaded into the operating environment. Thus, during runtime, changes in the language utilized at the user interface are implemented without any additional downloads from or communications with the configuration environment. Independently selectable user controls may be provided to independently control the language utilized by fixtures of the user interface and the language in which graphical display view content is presented.

The invention relates to a production machine with a control program for visualizing stations and/or machine components, highlighting the speed-determining station and/or the speed-determining machine component in order to optimize the process time. The invention also relates to a method of optimizing the process time for a production machine with such a control program and to a data carrier with such a control program.

To reduce the disadvantage caused by low communication quality. A control system includes a controller configured to control an industrial machine, and a terminal device configured to communicate with the controller. The control system includes a communication quality measurement unit configured to measure as index indicating communication quality between the controller and the terminal device, a communication quality determination unit configured to determine the communication quality between the controller and the terminal device on the basis of the index measured by the communication quality measurement unit, a display unit configured to display an operation screen image for the controller, and a display control unit configured to control a display item of the operation screen image to be displayed on the display unit on the basis of result determined by the communication quality determination part.

A control apparatus for performing control processing and user period processing within a control period for an industrial machine includes processing circuitry that sets content of the control processing, and sets an upper limit of the user period processing. The user period processing is different from the control processing.

A method (400) for configuring an industrial automation system (1) for internet-of-things accessibility involves a computing device (101) which a) receives (410) a first user input indicative of a functional object (70) representing one or more low-level devices (10) and/or automation devices (20) and/or supervising and production control devices (30). The computing device (101) also b) receives (420) a second user input indicative of a cloud object (72) representing a cloud service provider (3) being external to the industrial automation system (1). The computing device (101) further c) receives (430) a third user input indicative of a user terminal object (74) representing a user terminal device (4) being external to the industrial automation system (1). The computing device (101) then d) causes (440) the cloud service provider (3) to enable communication between the user terminal device (4) and at least one (2) of the devices (10, 20, 30) in the industrial automation system (1) as represented by the functional object (70) via the cloud service provider (3).