A motor control wizard implements a simple workflow for creating an application-specific program for operation of a motor control system. The wizard prompts for selection of an application area, which sensitizes the system to tune certain motor control parameters in accordance with the demands of the selected application area. The wizard also prompts for selection of a target devices, such as a particular type of motor with a set of basic operating parameters. With the target device and application area known, the wizard runs an automatic adaptation step without requiring additional user-settable parameters. The adaptation step yields an adapted motor control program based characteristics of the motor control system obtained via the adaptation step. The wizard then confirms operation of the motor using the adapted program. Additional features allow the user to fine tune parameters beyond this set of initial configuration parameters.

The disclosed hot cutover box creates an electronic virtual bypass around a terminal strip to which existing control system, new control system, and final control element connections may be made, thereby allowing migration from an existing to a new control system to take place. Sensors allow measurement of a current signal without disrupting electrical continuity and connectors allow the hot cutover box to be introduced to the circuit with no disruption to the controller output. Once the hot cutover box is in place, wiring connections can be removed from the terminal strip as the hot cutover box effectively provides a parallel current pathway around the terminal strip.

This disclosure describes systems and methods for remotely operating machine tools that include a stationary operating device that can operate in a control mode for controlling the machine tool or in a mode without control authorization. The methods include activating a first communication connection between a mobile communication device and the stationary operating device. The methods also include configuring the stationary operating device to operate in a mode without control authorization. The methods further include transferring control authorization from the stationary operating device to the mobile communication device by configuring the mobile communication device to operate in a remote control mode for controlling the machine tool based on transferred control authorization. The control authorization is transferred to the mobile communication device simultaneously or after the stationary operating device is configured to operate in the mode without control authorization based on information that is accessible only locally at the machine tool.

Described herein are several embodiments relating to modular irrigation controllers. In many implementations, the irrigation controllers are modular in that various functional components of the irrigation controller are implemented in removable modules that when inserted into position within the controller, expand the capabilities of the controller. Also described are various different types of expansion modules that may be coupled to the modular controller, having as variety of functions and features, as well as related methods of use and configuration of these modules in the controller. In one implementation, an expansion module is provided that includes a microcontroller capable of sending and receiving data communications to and from a main microcontroller of the controller that executed irrigation programs, the data communications relating to an irrigation program.

A control panel is used to control and/or monitor an automation system. The control panel may be removed from a mounted location to repair or replace the control panel. Replacement may be performed by a different provider of automation systems, potentially without prior notice to the current provider of the automation system. To alert the provider of the replacement, the control panel may use an anti-tamper switch to detect removal from the mounted location. A signal may be sent to a remote service system indicating the removal. If the control panel also loses AC power, or if the control panel loses all power, the remote service system may assume that the control panel is being replaced. In response, the remote service center may request that a customer service representative contact the customer to potentially retain the customer, recover equipment, or resolve any concerns about the automation system equipment.

An LED lighting device, and a smart home control system and method are provided. A smart terminal is configured to send a control instruction to an LED lighting device and to receive at least one sound pulse signal from the LED lighting device to remotely control one or more household electrical appliances that have an infrared remote control function. The LED lighting device includes a Wi-Fi module, an infrared remote control module and a sound pulse detection module. The Wi-Fi module receives the control instruction and transmits the control instruction to the infrared remote control module. The infrared remote control module converts the control instruction to an infrared control signal. The sound pulse detection module detects a prompt tone when the one or more household electrical appliances are turned on remotely, converts the prompt tone to a sound pulse signal, and sends the sound pulse signal to the smart terminal.

A display and control module of a field device, comprising a housing, a display unit arranged in the housing which is visible from the outside, and an electronics unit, wherein an exchangeable energy storage unit is arranged in the housing for at least partially supplying energy to the display and control module, and alternate embodiments thereof.

The invention relates to an operator panel (1) having one or more applications (121, 122) for operating at least one production system (2). A configuration data memory (13) is set up to store configuration data that are provided for configuring the one or more applications (121, 122) of the operator panel (1). A synchronization module (14) is set up to access configuration data stored in the configuration data memory (13) and to synchronize these data via a communications interface (11) of the operator panel (1) with configuration data that are stored in a configuration data memory (13, 13) of a remotely disposed operator panel (1, 1). A configuration access module (15) is set up to receive from at least one application (121, 122) of the operator panel (1) a read request for stored configuration data, to access stored configuration data, and to read the stored configuration data corresponding to the read request and to deliver the read configuration data for configuring the at least one application (121, 122) to the at least one application (121, 122).

A motor control wizard implements a simple workflow for creating an application-specific program for operation of a motor control system. The wizard prompts for selection of an application area, which sensitizes the system to tune certain motor control parameters in accordance with the demands of the selected application area. The wizard also prompts for selection of a target devices, such as a particular type of motor with a set of basic operating parameters. With the target device and application area known, the wizard runs an automatic adaptation step without requiring additional user-settable parameters. The adaptation step yields an adapted motor control program based characteristics of the motor control system obtained via the adaptation step. The wizard then confirms operation of the motor using the adapted program. Additional features allow the user to fine tune parameters beyond this set of initial configuration parameters.

A process calibrator is formed with a user interface, which guides to choose the right connection arrangements of the process calibrator according to the function of the process calibrator. The user interface shows in the display of the process calibrator the connection arrangements of the process calibrator and indicates the place of the connection arrangement assigned to the selected function visually compared to other connection arrangements. The connection arrangements shown by the user interface in the display are placed similarly to the physical connection arrangements of the process calibrator. As the user interface indicates the connection arrangement that is assigned to the selected function of the process calibrator, it is easy for the user to make the right connection.