Abstract: An industrial automation component may receive design information associated with an arrangement of one or more industrial automation components in an industrial automation system and identify a first portion of the industrial automation components in the industrial automation system that is unable to interface with a second portion of industrial automation components based on the design information. The industrial automation component may then generate a list of industrial automation components based on the first portion of the industrial automation components and the second portion of industrial automation components, wherein each of the list of industrial automation components is configured to translate a first set of data associated with the first portion of the industrial automation components to a second set of data configured to be at least partly interpretable by the second portion of industrial automation components.

Abstract: This disclosure relates to an apparatus and method for analyzing an influence variable on membrane fouling of a seawater desalination system, wherein influence variables other than variables having a low degree of influence, among variables affecting the membrane, are selected, and the influence thereof on membrane fouling is used to derive an equation. The apparatus includes a variable storage unit configured to store variables affecting membrane fouling of a seawater desalination system, a dominant variable selection unit configured to select at least one dominant variable among the variables through at least one algorithm, and an equation derivation unit configured to derive a specific equation based on a correlation between the selected dominant variable and the membrane fouling.

Abstract: A process control device that includes a process control valve, an actuator, a digital valve controller (“DVC”), and a processor. The actuator is coupled to the process control valve and is configured to control a position of the process control valve. The DVC is communicatively coupled to the process control valve and the actuator. The DVC is configured to obtain first data and second data, the first data associated with a fluid flow through the actuator or the DVC at a first point in time, and the second data associated with the fluid flow through the actuator or the DVC at a second point in time different from the first point in time. The processor is configured to aggregate the first data and the second data, and perform diagnostic and/or prognostic techniques based on the aggregated data.

Abstract: Automated behaviors in an environment can be implemented based on aggregation of individual user routines. For example, mobile devices used by users in the environment can provide information about the users' behavior patterns to a coordinator device that can be located in the environment. The coordinator device can analyze the information to detect an aggregate pattern that involves multiple mobile devices and/or multiple users. Based on a detected aggregate patterns, the coordinator can identify behaviors to automate.

Abstract: The present disclosure relates to a distributed electric power generation system including a plurality of electric power distribution stations; a power transmission grid network connected to the plurality of electric power distribution stations and a plurality of demand loads; and a control station including a processor configured to execute computer instructions to: calculate a period during which electric power supply is needed, acquire an amount of power supply demand to be supplied via the power transmission grid network during the calculated period and select a least costly combination of the electric power distribution stations for the plurality of demand loads based upon a start and stop cost and a running cost of each of the electric power distribution stations in accordance with the calculated period and the amount of power supply demand.

Abstract: A home automation system may include addressable devices and device scene controller. The controller may obtain a first desired scene including a first trigger action and responsive event and present a first user-selectable list of addressable devices capable of implementing the first desired scene. The controller may determine the first user-selected addressable devices, and, upon the first trigger event, perform the first responsive event using the first user-selected addressable devices. The controller may obtain from the cloud a second desired scene including a second trigger action and responsive event, present a second user-selectable list of corresponding addressable devices capable of implementing the second desired scene, determine the second user-selected addressable devices, and upon the second trigger event, perform the second responsive event using the second user-selected addressable devices.

Abstract: A system for comfort based management of thermal systems, including residential and commercial buildings with active cooling and/or heating, is described. The system can operate without commissioning information, and with minimal occupant interactions, and can learn heat transfer and thermal comfort characteristics of the thermal systems so as to control the temperature thereof while minimizing energy consumption and maintaining comfort.

Abstract: A heating system comprising an air circulation fan, a heating unit, a memory that is operable to store a temperature map, and a microprocessor. The microprocessor is configured to operate the air circulation fan at a first speed and the heating unit in a first configuration. When the heating unit is in the first configuration, the heating unit is configured to achieve a first temperature and such that less than all of the burners are active. The microprocessor is also configured to receive a temperature set point and to determine a second speed for the air circulation fan using the temperature set point and the temperature map in response to receiving the temperature set point. Further, the microprocessor is configured to transition the air circulation fan from the first speed to the second speed in response to determining the second speed.

Abstract: A heating control system including an air circulation fan, a heating unit, a memory, and a microprocessor. The microprocessor is configured to operate the air circulation fan at a first speed and the heating unit in a first configuration where less than all of the burners are active. The microprocessor is further configured to determine a first temperature difference, compare the first temperature difference to a first temperature difference threshold, and transition the air circulation fan from the first speed to a second speed when the first temperature difference is less than the first temperature difference threshold. The microprocessor is further configured to determine a second temperature difference, compare the second temperature difference to a second temperature difference threshold, and transition the air circulation fan from the second speed to a third speed when the second temperature difference is less than the second temperature difference threshold.

Abstract: Methods for control of post-design free form deposition processes or joining processes are described that utilize machine learning algorithms to improve fabrication outcomes. The machine learning algorithms use real-time object property data from one or more sensors as input, and are trained using training data sets that comprise: i) past process simulation data, past process characterization data, past in-process physical inspection data, or past post-build physical inspection data, for a plurality of objects that comprise at least one object that is different from the object to be fabricated; and ii) training data generated through a repetitive process of randomly choosing values for each of one or more input process control parameters and scoring adjustments to process control parameters as leading to either undesirable or desirable outcomes, the outcomes based respectively on the presence or absence of defects detected in a fabricated object arising from the process control parameter adjustments.

Abstract: An output module comprises two management units each of which calculates the current demand for the module independently from one another. One management unit controls an output current, controller whilst the other unit monitors the current produced by the output current controller against an independently calculated demand. The output module has multiple output modules. In normal operation, each module provides a portion of the required output current, the total output current being equal to the sum of the currents output by each module. in the event of failure on one of the, modules, the other module or modules switch to providing the total current required and the failed module is switched to a fail safe mode by using an isolation circuit to switch off the output current from that module.

Abstract: A key switch on a machine control panel is provided with two contacts such that the machine control panel can include two independent communication circuits. Signals from a double-contact key switch are received by the two communication circuits, and safety-related signals are transmitted from the communication circuits to a numerical controller through a bus. The signals received by the numerical controller are compared with each other so that they can be made to comply with the safety standards by monitoring the integrity of the safety function.

Abstract: Example implementations relate to punch-in transitions to smoothly transition operation of parts of a robotic system from control tracks to real-time input, such as to smoothly transition a control track rotating a knob at a handheld controller to real-time input received at the handheld controller. Similarly, example implementations relate to punch-out transitions to smoothly transition operation of parts of a robotic system from real-time input to control tracks, such as to smoothly transition from the real-time input received at a handheld controller to a control track rotating a knob at a handheld controller. In particular, an example system may include a handheld haptic controller, a control system, and a robotic component.

Abstract: The present invention relates to a system and method of HVAC (Heating, Ventilating, Air Conditioning) energy management system. More specially, the present invention provides a system and method that can provide automatic optimized control mechanism for HVAC system to save energy.

Abstract: An industrial machine management system includes a maintenance-use portable terminal and a cloud server. The maintenance-use portable terminal includes a data communication unit for transmitting management information for a user, which is set in accordance with an input from the user in regard to an industrial machine to be managed. The cloud server includes a data communication unit for receiving the management information for the user transmitted by the data communication unit, and a machine information storage for storing the management information for the user received by the data communication unit in association with individual identification information on the industrial machine to be managed.

Abstract: A servomotor control device includes a servomotor; a driven body configured to be driven by the servomotor; a connection mechanism configured to connect the servomotor and driven body, and transmit power of the servomotor to the driven body; a position command generation unit configured to generate a position command value; a motor control unit configured to control the servomotor using the position command value; a position command compensation unit including a force estimation part configured to estimate a drive force acting on the driven body at the connection mechanism, and a compensation amount generation part configured to generate a compensation amount for compensating the position command value based on the estimated drive force; and a restriction part configured to restricting updating of the compensation amount when a command acceleration or a command velocity of the position command value is no more than a desired value.

Abstract: A package generation system allows a user to add an ornamental structure to a package flat by receiving a package design file containing data representing package characteristics. The system uses the package design file to identify a two-dimensional layout of the package. The system identifies: (i) a first area of a substrate that will form a two-dimensional flat of a package; (ii) an unused area of the substrate that will not form part of the package; and (iii) an ornamental structure that is attachable to a facet of the package and which fits within a portion of the unused area adjacent to the facet. The system then outputs a representation of the ornamental structure to a user. Examples of ornamental structures include a ribbon, a detachable coupon, or an ornamental face. The system may create the package after the user selects an offered ornamental structure.

Abstract: Node controllers and power distribution networks in accordance with embodiments of the invention enable distributed power control. One embodiment includes a node controller comprising a memory containing: a plurality of node operating parameters; and a plurality of node operating parameters describing operating parameters for a set of at least one node selected from the group consisting of at least one downstream node and at least one upstream node; wherein the processor is configured by the node controller application to: receive and store in memory a plurality of coordinator parameters describing operating parameters of a node coordinator by the network interface; and calculate updated node operating parameters using an iterative gradient projection process to determine updated node parameters using node operating parameters that describe operating parameters of node and operating parameters of the set of at least one node, where each iteration is determined by the coordinator parameters.

Abstract: A control system is provided for controlling an electrically operated device. The control system includes a first control box and a second control box. The first control box is equipped with a single button. In case that an input power is normally received and the button is pressed, a pairing process is performed. In case that the input power is interrupted, the second control box is in an emergency mode.

Abstract: According to one embedment, a supply chain monitoring system can collect performance information from a server associated with each of a tier 1 control tower, tier 2 product assembler, tier 3 part and/or component manufacturer, and tier 4 material supplier to monitor a performance of one or more functions of a supply chain. The system obtains event information regarding an event potentially adversely impacting performance of the supply chain, determines a range of disruption of the event indicating a likely spatial range impacted by the event, and compares the range of disruption of the event against the supply chain to determine that a supply chain component has been impacted by the event.