A settings information generation device, for reducing the number of settings steps pertaining to a device in a superordinate device that communicates with a slave device to which the device is connected, includes: a selection unit for accepting a selection of a device to be connected; an acquisition unit for acquiring operational settings information including the input/output data length of the selected device; and a generation unit for generating, on the basis of the operational settings information, superordinate device settings information for setting a storage region for storing data exchanged with the device by a controller via a device management unit.

A method for operating a real-time control system comprising a first system configured to generate an information signal and a second system configured to use the information signal, wherein the second system comprises a first buffer for storing a previously received information signal. The method comprising: transmitting, by the first system, a first communication packet comprising the first information signal and generating, by the second system, a predicted first information signal for use in the first time slot. The predicted first information signal being generated by: retrieving the previously received information signal from the first buffer; generating a first prediction using a short-term predictor; and concurrently generating a second prediction using a long-term predictor; and setting the predicted first information signal equal to the first prediction unless the second prediction is available. The method further comprising using the predicted first information signal in response to determining that the first information signal was not received by the second system in the first time slot.

An operating terminal includes: a connected-device information transmitting unit transmitting first connected-device information to another operating terminal, the first connected-device information being information on a facility device connected to the operating terminal; a connected-device information obtaining unit obtaining second connected-device information from the another operating terminal, the second connected-device information being information on a facility device connected to the another operating terminal; an operation receiving unit receiving an operation for being performed on a facility device connected to the operating terminal and a facility device connected to the another operating terminal; and an air conditioning control command transmitting unit determining, from the first connected-device information and the second connected-device information, a destination of a control command and transmitting the control command to the destination, the control command representing content of an operation received by the operation receiving unit.

A control system includes a control apparatus functioning as a master, and plural slaves which are network-connected to the control apparatus. The slaves each have identification information. The control apparatus includes executes a first instruction to set specified identification information to each of one or more specified slaves. The control apparatus outputs first error information indicating which slave that the setting of the identification information to which is failed, among the one or more specified slaves.

A second action is identified by the edged device. The second action is associated with a second networked device of the plurality of networked devices in the environment. The second networked device is unrelated to the first networked device. A relationship is detected between the first networked device and the second networked device by the edge device. A network device bubble is generated by the edge device. The network device bubble is based on the relationship that is detected.

The present disclosure is directed to systems and methods for economically optimal control of an electrical system. Some embodiments employ generalized multivariable constrained continuous optimization techniques to determine an optimal control sequence over a future time domain in the presence of any number of costs, savings opportunities (value streams), and constraints. Some embodiments also include control methods that enable infrequent recalculation of the optimal setpoints. Some embodiments may include a battery degradation model that, working in conjunction with the economic optimizer, enables the most economical use of any type of battery. Some embodiments include techniques for load and generation learning and prediction. Some embodiments include consideration of external data, such as weather.

A method can include receiving scheduled tasks associated with subsystems of a wellsite system wherein the scheduled tasks are associated with achievement of desired states of the wellsite system; transmitting task information for at least a portion of the scheduled tasks to computing devices associated with the subsystems; receiving state information via the wellsite system; assessing the state information with respect to one or more of the desired states; based at least in part on the assessing, scheduling a task; and transmitting task information for the task to one or more of the computing devices associated with the subsystems.

There is provided a substrate processing system, including: a plurality of substrate processing apparatuses; a first control part installed in each of the plurality of substrate processing apparatuses and configured to transmit a first apparatus data from each of the plurality of substrate processing apparatuses; a second control part configured to receive the first apparatus data from each of the plurality of substrate processing apparatuses, generate a priority data of each of the plurality of substrate processing apparatuses based on the first apparatus data, and transmit the priority data to the first control part; and a display part configured to display the priority data thereon.

System and method for designing and deploying a building-related service in a building automation management system (BAMS) based on a software-defined master system (SDMS) architecture. The master system of the BAMS comprising a plurality of building automation systems (BASs) receives a request to create a building-related service involving dynamic coordination between at least two BASs. The request may include a workflow comprising a set of actions and configurations defining the building-related service. The master system uses system description data generated from the workflow to instantiate a blueprint that defines data exchanges with the at least two BASs, information about target hosts, and any dependencies to be resolved. Upon parsing the blueprint to resolve any dependencies, the master system builds a deployment plan that includes a sequence of steps and configurations for implementing the building-related service. The master system

A control device includes at least two processors comprising at least a first processor and a second processor. The control device controls at least one autonomous motion mechanism on the basis of a recognition result received from a recognition device. A storage device of the control device stores upper-level software, middle-level software, and lower-level software. The upper-level software derives a feature amount representing a feature of the recognition result. The middle-level software generates a motion plan of the autonomous motion mechanism on the basis of the feature amount. The lower-level software outputs a command value for controlling the autonomous motion mechanism on the basis of the motion plan. The first processor executes at least the upper-level software, the second processor executes at least the lower-level software, and at least one processor included in the control device executes the middle-level software.