Systems and methods for human-machine interaction. An adaptive behavioral control system of a human-machine interaction system controls an interaction sub-system to perform a plurality of actions for a first action type in accordance with a computer-behavioral policy, each action being a different alternative action for the action type. The adaptive behavioral control system detects a human reaction of an interaction participant to the performance of each action of the first action type from data received from a human reaction detection sub-system. The adaptive behavioral control system stores information indicating each detected human reaction in association with information identifying the associated action. In a case where stored information indicating detected human reactions for the first action type satisfy an update condition, the adaptive behavioral control system updates the computer-behavioral policy for the first action type.

A system has a processor that may receive an order of an industrial device assembly having multiple industrial automation devices. The processor may also generate a first data file based on the order of the industrial device assembly. The first data file may have specification data associated with each industrial automation device and hierarchical information associated with each industrial automation device. Additionally, the processor may generate a second data file based on the first data file. The second data file has one or more control blocks of code associated with each industrial automation device. Further, the processor may transmit the second data file to a control system associated with the industrial device assembly. The control system is automatically programmed based on the second data file to control one or more operations of each industrial automation device in the industrial device assembly.

Disclosed is a system for monitoring and control of machinery. In embodiments, a maintenance sensor measures data from a machine and processes the data prior to its wireless transmission to a wireless zone kit, which, in turn, sends the data to a controller. Processing of measured data at a wireless maintenance sensor can include generating a digital energy model, that provides sufficient data to the control system to allow decisions and actions to be taken by an operator, while reducing power consumption and extending a lifetime of the sensor and/or a power source of the sensor. The processing elements may include Fourier analysis of the data. A method of operation of a system for monitoring and controlling a machine is also disclosed.

The invention relates to a smartwatch having a transmitter/receiver unit and a display unit, wherein the smartwatch is configured for receiving diagnosis notifications of a plurality of automation technology field devices by means of the transmitter/receiver unit, for analysing the received diagnosis notifications and classifying same in predefined device statuses, in particular in device statuses according to the NAMUR recommendation, as well as for displaying the classified device statuses of the field devices by means of the display unit. The invention also relates to a method for maintaining an automation technology system, in which a plurality of field devices are integrated, by means of a smartwatch according to the invention.

A controllable device, such as a set top box, responds to a transmission received from a one of a plurality of controlling devices of differing capabilities by entering into a one of a plurality of operating modes wherein the one of the plurality of operating modes entered into corresponds to the capabilities of the controlling device from which the transmission originated.

The invention enables a device type manager (DTM) to implement through a field device tool (FDT) frame application, field device management capabilities that are outside the defined operating capabilities of the FDT frame application. The enables controlling a field device, through a device type manager (DTM) configured to control a field device based on control instructions received from a field device tool (FDT) frame application. The FDT frame application and the DTM and/or a DTM wrapper within the DTM may be implemented based on a first runtime environment and a first set of specifications that defines a first set of operating capabilities for the FDT frame application. The DTM wrapper may be configured to communicate with the FDT frame application based on one or more messaging protocols defined by the first set of specifications and further to communicate through inter-process communication, with (i) a DTM framework controller configured to implement the communication and control instructions that enable the DTM to communicate with or control the field device, wherein the DTM framework controller is configured for implementation based on a second runtime environment that is different from the first runtime environment, and (ii) a DTM user interface controller configured to implement one or more user interface controls for controlling the field device.

The present disclosure is directed to systems, methods and devices for facilitating object-based cross-domain industrial automation control. An object library comprising a plurality of objects may be maintained. One or more of the objects may represent physical counterparts for use in an industrial automation process. Each object of the plurality of objects in the object library may have at least one property that an automated control device operation can be programmed to act on. Each object of the plurality of objects may also have at least one property that a human machine interface component can utilize in generating display elements corresponding to the objects for display on the human machine interface. When modifications to objects in the object library are received, those modifications may be automatically deployed and incorporated in controller logic and HMI graphics and control.

An irrigation controller is revealed. The irrigation controller includes a user interface presenting information to users, easily-operated by buttons and allowing users to program irrigation related information directly. The user interface is composed of a round display, a plurality of program keys, and a selective key. An indicator and programmable information zones are shown on the round display. There are at least six programmable information zones. The information zone is selected by a single selective key. The indicator is moved in one direction in a circular path.

A method includes determining a current situation to be present in a process controlled by an industrial process control and automation system (IPCS) that includes at least one process controller coupled to input output (I/O) modules coupled to field devices including sensors and actuators that are coupled to processing equipment. Responsive to the current situation, displaying a plurality of suggested actions each including at least one step in a selectable panel in a human machine interface (HMI) associated with an operator computing system for an operator that is coupled to the process controller. Responsive to the displaying, the operator selects in the selectable panel at least one of the plurality of suggested actions (selected action). The selecting of the selected action results in the IPCS automatically implementing at least in part the step(s) associated with the selected action.

Systems and methods for human-machine interaction. An adaptive behavioral control system of a human-machine interaction system controls an interaction sub-system to perform a plurality of actions for a first action type in accordance with a computer-behavioral policy, each action being a different alternative action for the action type. The adaptive behavioral control system detects a human reaction of an interaction participant to the performance of each action of the first action type from data received from a human reaction detection sub-system. The adaptive behavioral control system stores information indicating each detected human reaction in association with information identifying the associated action. In a case where stored information indicating detected human reactions for the first action type satisfy an update condition, the adaptive behavioral control system updates the computer-behavioral policy for the first action type.