Abstract: A computer-implemented system and method for searching comprises receiving digital twin instance part assembly information (IPAD) from a sensor scan of a physical part assembly produced by assembling a first physical part with a second physical part. Digital twin framework part assembly data (FPAD) is received representing a correctly assembled physical part assembly and that corresponds to the physical part assembly. Context data associated with a context within which the physical part assembly is produced is also received. The FPAD is compared with the IPAD, utilizing the context data, to determine whether a deviation of the IPAD from the FPAD exceeds a threshold. Responsive to the deviation exceeding a threshold, the method comprises providing corrective information to a device of an assembler for re-assembling the first physical part to the second physical part to produce a reassembled physical part assembly based on the corrective information.

Abstract: A threat detection system for industrial controllers, comprising: at least one Programmable Logic Controller (PLC); at least one physical device connected with the PLC; a Deterministic Fictitious Programmable Logic Controller (DFPLC) deterministically programmed to respond with at least one predetermined signal to at least one input signal received; and a monitoring unit connected with the DFPLC; the DFPLC disguised as a PLC; and the monitoring unit configured to send at least one input signal to the DFPLC, receive at least one response from the DFPLC and communicate at least one alert upon the at least one response being other than an expected response according to the deterministic programming of the DFPLC.

Abstract: An information processing device includes: a memory; and a processor configured to: hold each of values of state variables included in an evaluation function representing energy; calculate the change value of the energy for each of state transitions, when a state transition occurs due to a change of any of the values of the state variables; control a temperature value representing temperature; select any of the state transitions, based on priority information set based on state transition information updated last time with respect to identification information for identifying each state transition, and transition acceptance information indicating transition acceptance determined based on the change value, and a generated thermal noise; and output a lowest energy state which is the values of the state variables when the energy to be updated based on the selected state transition becomes a lowest value.

Abstract: A method includes a system that operates according to a control schedule; detects events that indicate occupancy; stores a record of the events that indicate occupancy in one or more memory devices; and enters an auto-away state. A determination to enter the auto-away state may be based at least in part on a length of a time interval during which no events that indicate occupancy were detected and the stored record of the events that indicate occupancy. The system may also detect a pattern of instances where the auto-away state is entered over a plurality of days and adjusts the control schedule based at least in part on the pattern of instances where the auto-away state is entered.

Abstract: An approach to intelligent additive manufacturing makes use of one or more of machine learning, feedback using machine vision, and determination of machine state. In some examples, a machine learning transformation receives data representing a partially fabricated object and a model of an additional part (e.g., layer) of the part, and produces a modified model that is provided to a printer. The machine learning predistorter can compensate for imperfections in the partially fabricated object as well as non-ideal characteristics of the printer, thereby achieving high accuracy.

Abstract: Apparatus (1) for additively manufacturing three-dimensional objects (2) by means of successive layerwise selective irradiation and consolidation of layers of a build material (3) which can be consolidated by means of an energy source (4), which apparatus (1) comprises an application unit (6) with at least one application element (7) adapted to apply build material (3) on a build plane (8), characterized in by a determination unit (12) that is adapted to determine contact information relating to a force acting on the at least one application element (7), preferably during an application process.

Abstract: An approach to intelligent additive manufacturing makes use of one or more of machine learning, feedback using machine vision, and determination of machine state. In some examples, a machine learning transformation receives data representing a partially fabricated object and a model of an additional part (e.g., layer) of the part, and produces a modified model that is provided to a printer. The machine learning predistorter can compensate for imperfections in the partially fabricated object as well as non-ideal characteristics of the printer, thereby achieving high accuracy.

Abstract: Traditional home-automation systems utilize a single hub for controlling secondary devices within a home. The techniques described herein, meanwhile, utilize multiple hubs within the environment and/or located remotely from the environment. For instance, an environment may include multiple electronic devices, each configured to control one or more secondary devices within the environment. In addition, a remote service may be configured to control one or more secondary devices within the environment. As such, each controlling device stores and executes an instance of a control engine, rather than relying on a single instance of a control engine located at a single controlling hub.

Abstract: A device and method for the controlled processing of at least one workpiece (1), comprising a workpiece carrier (2) on which at least one workpiece receptacle (2.1) is present remote from a rotary shaft (2.0), at least one processing unit (3) and at least one inspection unit (4), which are offset relative to the rotary shaft (2.0) by an angular distance (?n) from one another, are each arranged so that they can be adjusted and moved in a translational manner radially with respect to the rotary shaft (2.0), so that a processing beam (E) and an inspection beam (P), offset relative to one another by the angular distance (?n), describe the same spiral-shaped movement path (S) relative to the workpiece carrier (2), and the inspection results derived at an inspection point (PP) are used to control process parameters in order to change the effect of the processing beam (E).

Abstract: A method and an apparatus for controlling an air conditioner are provided, and the air conditioner is also provided. Herein, the method for controlling the air conditioner may include: acquiring at least one operating environment parameter of the air conditioner; determining a target temperature of the air conditioner and a revolving speed of an internal fan according to the at least one operating environment parameter of the air conditioner; and adjusting a frequency of a compressor on the basis of the operating environment parameter and the target temperature of the air conditioner and the revolving speed of the internal fan.

Abstract: An air conditioning system includes: outdoor units; indoor units each communicating with any one of the outdoor units by a first communication method; and a central control device communicating with each of the outdoor units by a second communication method and controlling the outdoor units and the indoor units. One of the outdoor units generates, by using a first address used for communication performed using the first communication method, a second address used for communication performed using a second communication method, generates a second address for one or more of the indoor units by using a first address, and obtains second addresses from another outdoor unit and the central control device. The central control device obtains, from each of the outdoor units, second addresses of the outdoor unit and each indoor unit, and controls operations of the outdoor units and the indoor units by using the second addresses obtained.

Abstract: A ventilation system with: (i) a volumetric enclosure having an inlet and an outlet and for coupling to an interior of a building habitable by human occupants; (ii) a fan located within the volumetric enclosure and for drawing air exterior to the building and supplying the air to the interior of the building; (iii) a programmable control apparatus for enabling and disabling the fan in response to a plurality of parameters, at least some of the parameters relating to quality of air to be moved in response to the fan; and (iv) circuitry coupled between the inlet and the outlet for measuring a signal representative of a volume of air passing through the volumetric enclosure over a period of time.

Abstract: The present application provides a method for inspecting a display panel and an inspection apparatus. Wherein the method for inspecting the display panel including the following steps: setting substrate random sampling parameters in a manufacturing process by a manufacturing execution module, and transmitting the random sampling parameters to a production line control module; receiving and storing the random sampling parameters by the production line control module; generating a random sampling control signal and transmitting to a detector according to the random sampling parameters by the production line control module; and performing a random sampling to a substrate by the detector in accordance with the random sampling control signal.

Abstract: A home appliance can operate in a future time frame. Information is obtained from a power distributor in order to determine a time when to operate the home appliance in this future time frame. The home appliance then operates at the time determined with information from the power distributor.

Abstract: A building management system includes a meter configured to provide data samples of a real point. The real point corresponds to a first physical parameter measured by the meter. The building management system also includes an analytics circuit configured to store a real point object representing the real point and store a meter object representing the meter. The meter object includes a points attribute that lists one or more point objects associated with the meter object including at least the real point object. The analytics circuit is also configured to store a virtual point object representing a virtual point. The virtual point corresponds to a second physical parameter not measured by the meter. The analytics circuit is also configured to update the points attribute in the meter object to list the virtual point object as one of the point objects associated with the meter object.

Abstract: The present application is directed at pin programming od controllers for power converters and provides for the programming of a plurality of different controller parameters using a single programming resistor. The value of the programming resistor is used as a pointer to select a table storing a plurality of different settings for the controller.

Abstract: A data control apparatus includes an analog signal input interface for receiving an analog signal from a first device, a communication interface for receiving correlation information indicating addresses of storage areas in a storage and conditional values associated with the storage areas, and a data controller for writing a digital value generated from the analog signal into one of the storage areas. The data controller includes a cam switch block for acquiring a reference signal generated from an input signal input from a second device and comparing a value of the reference signal with at least one of the conditional values, and a logger block for switching the storage area into which the digital value is written, on the basis of the comparison in the cam switch block, and writing the digital value into the storage area.

Abstract: A method for operating a fieldbus controller (2) having a plurality of I/O modules (4) is provided, the fieldbus controller (2) being coupled to a valve assembly (6) via the plurality of I/O modules (4). The method includes providing a user interface (8) for wirelessly operating the fieldbus controller (2), wherein providing the user interface (8) includes: providing a configuration interface (14) for configuring an operating mode of the plurality of I/O modules (4); providing a monitor interface (16) for reading status information from the plurality of I/O modules (4); and providing a control interface (18) for controlling a state of the plurality of I/O modules (4), the state of the plurality of I/O modules affecting a state of the valve assembly (6).

Abstract: A processing apparatus for processing a substrate includes: a plurality of end devices; a low-level controller configured to control specific end devices among the plurality of end devices; and a module controller configured to execute a recipe for processing the substrate, to specify control steps satisfying a specific condition among a plurality of control steps of the recipe, and to transmit the specified control steps to the low-level controller, wherein the low-level controller controls the specific end devices based on the control steps received from the module controller.

Abstract: Systems and methods are provided for monitoring and controlling one or more environmental conditions of a building. The method comprises obtaining feedback from a first sensor at a first location within the building and feedback from a second sensor at a second location within the building. The method further comprises combining the feedback from the first sensor with the feedback from the second sensor in a weighted manner to generate a combined feedback, wherein a weight of the feedback from the first sensor relative to a weight of the feedback from the second sensor is based on a time of day. The method finally comprises operating HVAC equipment to drive the combined feedback toward a setpoint for the building.