Abstract: A building control system that includes a central coordinator and one or more discrete air conditioner controllers configured to communicate with one or more discrete air conditioner units. The discrete air conditioner controller may include a wireless I/O block for receiving signals in a first signal format from the central coordinator and for transmitting signals to the one or more discrete air conditioner units in a second signal format. In some instances, the discrete air conditioner controller may be configured to wirelessly transmit a signal to at least one discrete air conditioner unit in response to receiving a signal from the central coordinator. This configuration may provide a measure of distributed control of the building control system in a cost effective and efficient manner.

Abstract: Disclosed herein is a power demand forecast device including: an absence detection section adapted to detect whether a consumer is absent at a given location; and a power demand forecast section adapted to forecast a power demand on a forecasted date and time in future based on an absence detection result obtained by the absence detection section.

Abstract: Systems and methods for controlling lab equipment such as transmitters are provided that includes a mini automation controller (MAC). The system provides a control system, user interface, and interfaces, including network interfaces usable for interfacing equipment, MAC, and user interfaces over a network, which provide a variety of functions including automation and monitoring of transmission sequences and receiver events. An exemplary MAC may include an Ethernet controller capable of converting an Ethernet signal to a serial signal. The MAC may also include a receiver monitor section comprising a fiber optic receiver input, a copper cable receiver input, and a monostable multivibrator. In addition to the receiver monitor section, the MAC may have a transmitter control section including a transmitter control pulse and a power output. An exemplary MAC may have a microcontroller coupled to the Ethernet controller, the receiver monitor section, and the transmitter control section.

Abstract: Described are methods, systems, and apparatus, including computer program products, relating to an air module and control thereof. An air module can include a controller, an air intake module configured to receive first air from a first air source and to receive second air from a second air source, an evaporative cooling module in fluid communication with the air intake module, and a mechanical cooling module in fluid communication with the evaporative cooling module. The controller can be configured to cause the intake module to mix the first air and the second air to form intake air, and selectively cool the intake air to form supply air by at least one of causing the evaporative cooling module to selectively cool the intake air, and causing the mechanical cooling module to selectively cool the intake.

Abstract: The present invention relates to a lighting control analyzer (170), and a corresponding method (600), for determining occupancy behavior in an area (110, 200) illuminated by at least one lighting device (120a-c) controllable by a lighting controller (160). The lighting control analyzer is adapted to receive light settings (d) for control of the at least one lighting device, the light settings being determined by the lighting controller using a lighting control strategy for the area. The lighting control strategy represents a desired illumination of the area, based on presence information associated with the area. The lighting control analyzer is further adapted to determine the occupancy behavior, based on the light settings and the lighting control strategy. The occupancy behavior may comprise normal locations of occupants (401-417), how often occupants are normally located at different locations, and entrance points of the area.

Abstract: A method and a device for controlling an energy-generating system are operated with a renewable energy source. In the method, a prediction about an energy yield of the energy-generating system is made for a predefined prediction time period, and a predefined area, using a learning system with an input vector and an output vector. The output vector includes operating variables for a multiplicity of successive future times of the time period. The input vector includes variables, influencing the operating variables, for a point in time from a multiplicity of points in time of a predefined observation time period. The input variables include at least three items of information for the observation time period and the predefined area. The energy-generating system is controlled on the basis of the generated prediction such that weather-conditioned fluctuations in the energy yield of the energy-generating system are reduced.

Abstract: An air conditioning system includes an air handling unit (AHU) configured to control outdoor air that is externally supplied, exhaust air that is discharged from indoors to outdoors, and return air that is circulated indoors and supplied again, control the outdoor air or mixed air of the return air and the outdoor air at a set temperature, and supply cool/warm supply air indoors, at least one outdoor unit configured to supply a refrigerant to the AHU, a controller configured to control the AHU through communication with the outdoor unit, and an interface unit configured to operate as an input/output unit of the controller. The interface unit displays setting menus for devices forming the AHU, sets basis data for controlling the devices in response to data received through the setting menus, inputs the set basis data to the controller, and outputs a control menu and a monitoring menu in accordance with functions of the AHU changed according to a configuration of the plurality of devices.

Abstract: A method for controlling intelligent household appliances, comprising: acquiring an appliance control signal set and an initialization feedback signal set corresponding to the control signal set, and sending a control signal; receiving the control signal, sending the control signal to the household appliance to instruct the household appliance to perform an operation represented by the control signal; acquiring state information and a feedback signal of the household appliance; and calculating a variation amount of the state information, and judging a matching rate between the feedback signal and the initialization feedback signal The present invention also provides an intelligent socket, which can allow a terminal to obtain an actual control result after a control instruction being sent An intelligent socket based on a high power infrared emitting tube, wherein the high power infrared emitting tube is provided in a limiting hole for infrared emission in a direction away from a panel.

Abstract: A numerical controller has a first axis (reference axis) and a second axis (superimposed axis), and performs superimposed control which superimposes a movement amount of the reference axis on a movement amount of the superimposed axis, and thereby controls the movement of the superimposed axis. The numerical controller controls an acceleration start time of the axis to be accelerated, in a superimposition interval in which the reference axis is accelerated and the superimposed axis is decelerated (or reference axis is decelerated and superimposed axis is accelerated). After the axis to be decelerated is sufficiently decelerated, the axis to be accelerated is accelerated, and a moving speed of the superimposed axis does not exceed a speed limit of a machine in an acceleration/deceleration interval.

Abstract: Systems and methods for managing a programmable thermostat are described herein. One or more system embodiments include a programmable thermostat having a first management profile; a data acquisition subsystem; and a data analysis subsystem. The data acquisition subsystem is configured to receive thermostat data from the programmable thermostat, and the data analysis subsystem is configured to receive the thermostat data from the data acquisition subsystem, and determine a second management profile for the programmable thermostat based, at least in part, on the thermostat data.

Abstract: A process for direct fabrication of a part at a predetermined structural position. The process comprises: a) scanning, via a three-dimensional scanner, the structure in the region of the predetermined position; b) comparing a virtual surface mesh of the predetermined position with a real surface mesh of the predetermined position, the real surface mesh calculated based on data obtained from the scanning; c) determining the gaps between the two meshes; d) calculating the data for modeling an inserted part, the dimensions of which fill up the determined gaps, to obtain an inserted part model; e) merging of a virtual model of a part, linked with the predetermined position, with the inserted part model, to obtain a model adjusted to the geometry of the structure in the region of the predetermined position; f) fabricating, by material deposition, an adjusted part at the predetermined position based on the adjusted model.

Abstract: Methods and systems for weight-based identification of three dimensional (3D) printed parts. Various embodiments disclosed herein may permit reliable processing of 3D printed parts to effectively scale a 3D printing service to large volumes of orders for 3D printed parts.

Abstract: In wire-electrical discharge machine and a numerical control apparatus thereof and a numerical control apparatus for controlling a machine tool, optional minute blocks are automatically created in front of and behind a connecting point, i.e., a joint of a block to which an offset command is instructed, and an offset value is exchanged between the minute blocks so that a correct offset value is set in a desired block.

Abstract: An automated computer-implemented method for generating commands for controlling a computer numerically controlled machine to fabricate an object from a workpiece, the method including the steps of selecting a maximum permitted engagement angle between a rotating cutting tool and the workpiece, selecting a minimum permitted engagement angle between the rotating cutting tool and the workpiece, and configuring a tool path for the tool relative to the workpiece in which the engagement angle gradually varies between the maximum permitted engagement angle and the minimum permitted engagement angle.

Abstract: Systems and methods are provided for an appliance system. The system includes an appliance, and a processor connected to the appliance such that the processor places the appliance in one of an enabled state and a disabled state. The processor is configured to track usage of the appliance and to place the appliance in a disabled state when the usage of the appliance exceeds a threshold amount. The system also includes a data receiving device configured to receive a code, wherein upon receipt of a valid code, the processor is configured to adjust the threshold amount to allow additional usage of the appliance.

Abstract: An apparatus includes vibration data obtainer 30 obtaining data on vibration caused by a tool in cutting, a vibration frequency calculator 22 calculating a vibration frequency of the tool by analyzing the obtained vibration data, a regenerative chatter detector 23 detecting whether regenerative chatter occurs by comparing the calculated vibration frequency of the tool with a spindle rotation number, and a spindle rotation controller 24 gradually decreasing or increasing the spindle rotation number when occurrence of regenerative chatter vibration is detected, and a stable rotation number calculator 25 monitoring variation of the vibration frequency of the tool and determining a spindle rotation number when the variation of the vibration frequency exceeds a predetermined reference value to be a stable rotation number.

Abstract: A semiconductor process management system is provided. The semiconductor process management system includes a communicator that receives a process recipe from one or more process apparatuses and receives a measured value for each sampling point from one or more measuring apparatus, and a first determination unit that establishes a mutual influence model between the process recipe and the measured value for each sampling point based on the process recipe and the measured value for each sampling point.

Abstract: The invention relates to a device for contact-free control of a patient table includes a camera system for detecting at least one gesture of a user of the device, a processing unit for converting the at least one detected gesture into at least one command for controlling the patient table, and an execution unit for executing the at least one command for controlling the patient table. The device can furthermore include a monitoring system for monitoring the control of the patient table and an authentication system for authenticating the user.

Abstract: A working machine feed axis control device: disposes a velocity feedback loop and forms a cascade coupling on the inner side of a location feedback loop; comprises a velocity gain setting apparatus (30) which multiplies the output of the velocity feedback look by a first gain (kv), and a location gain setting apparatus (31) which multiplies the output of the location feedback loop by a second gain (kp); subtracts the output of the velocity gain setting apparatus (30) and the output of the location gain setting apparatus (31) from a torque instruction (?); and outputs the remaining torque instruction (?) to a subject to be controlled (27).

Abstract: An intelligent thermostat control system for a building, such as a residential home, that automatically adjusts a thermostat setting in the home based on real-time data continually received from mobile devices and/or social media files associated with the residents. This allows the thermostat controller to override the explicit programmed settings with implicit settings based on activity analysis taking the actual locations and schedules of the residents into account. The intelligent thermostat controller may control different zones differently to take into account the schedules and locations of specific residents associated with specific zones. The temperature controller may also adaptively learn a number of parameters based on monitored data, such as travel times and heating/cooling times for the zones based, to determine times for adjusting the thermostats.