Abstract: A system and method disclosed herein are for providing local and remote control of home and enterprise heating systems (thermostats) via the Power line communication (PLC) networks configured to provide communication and power control capability within a local area network. The PLC based control unit allows the remote access and control of the thermostat of local heating systems from within and outside the PLC based local area network.

Abstract: Various thermostat embodiment are provided that includes at least a first sensor configured to communicate information indicative of the temperature within the space, and at least a second sensor configured to communicate information indicative of the humidity within the space. The thermostat further includes a controller in communication with the at least first and second sensors, for controlling the thermostat's operation. The controller is configured to operate in a first mode in which the controller operates the air conditioner when the sensed temperature of the space is above a temperature set-point or when the sensed humidity level is above the humidity set-point. The controller is further configured to operate in a second mode in which the controller operates the air conditioner when the sensed temperature is below a set-back temperature set-point, or when the sensed humidity is above a set-back humidity set-point.

Abstract: An air-conditioning system includes: an air-conditioning apparatus in which indoor units are connected to an outdoor unit; a conveying fan; and control means for controlling the air-conditioning apparatus and the conveying fan on the basis of a target evaporating temperature. The control means resets an upper limit of the target evaporating temperature when: a control determination temperature difference which is a difference between a set temperature and a temperature of an air-conditioned space is within a predetermined range; a humidity of the air-conditioned space is equal to or lower than a predetermined value; and a thermo-ON indoor unit and a thermo-OFF indoor unit are present together in the same air-conditioned space.

Abstract: A secondary pump-type heat source system includes: heat sources connected in parallel; a load system in which the heat source water flows; a primary pump supplying the heat source water to the load system; a secondary pump provided for each heat source and supplies the heat source water subjected to heat exchange in the load system to the heat source; and a heat source controller calculating flow quantity of the heat source water flowing in the heat source side and flow quantity of the heat source water flowing in the load system side by assigning a result from measurement by a water temperature sensor detecting heat source temperature to an operating characteristic of each heat source and controlling operation of the secondary pumps based on the calculation result.

Abstract: A structure and method for temperature control includes determining a schedule for a climate control device needed for an inside temperature to reach a desired temperature, determining a perceptual temperature factor based on at least the schedule and the inside temperature, adjusting the desired temperature based on the perceptual temperature factor, and after the adjusting the desired temperature, repeating the determining the schedule.

Abstract: An idle control system for a vehicle is provided.

Abstract: The present disclosure relates generally to building control systems and, more particularly, to methods and devices for configuring and/or displaying parameters or other information such as menu screens on a programmable wall module of a building control system. In an illustrative embodiment, a configuration tool may be configured to create a number of screens for the user interface of the programmable wall module based on a number of user inputs received via the user interface of the configuration tool. In some cases, the number of user inputs received via the user interface of the configuration tool may be less than, and sometimes far less than, the number of screens that are created by the configuration tool. Regardless, with the number of screens created, the configuration tool may upload the number of screens to the programmable wall module for use on the user interface of the programmable wall module.

Abstract: Provided are a system and method for wireless irrigation control with a remote application. The system includes a processor and plurality of interactive zone switches for connection to at least one irrigation device; each zone switch further operable to detect a state of a connected irrigation device. Non-volatile memory is coupled to the processor and provided with executable instructions to direct operation of each interactive zone switch. There is at least one remote application to establish a schedule within the non-volatile memory for operation for each interactive zone switch and to receive the schedule from the non-volatile memory in response to a users desire to review or modify the schedule. A wireless network component is coupled to the processor and the non-volatile memory and is in communication with the remote application to schedule operation of at least one interactive zone switch and at least one irrigation device.

Abstract: A method performed by a zone controller for a zone of a building for improving energy efficiency in a heating, ventilation, and air conditioning (HVAC) system is provided. The method includes operating in a ventilation mode. A temperature of the zone and outside air conditions for the building are monitored. A determination is made regarding whether to switch from the ventilation mode to an economizing mode based on a first set point for the temperature of the zone and based on the outside air conditions. The first set point is determined based on a second set point for the temperature that is different from the first set point. A determination is made regarding whether to activate the HVAC system based on the second set point.

Abstract: Systems, methods, and related computer program products for controlling one or more HVAC systems using a distributed arrangement of wirelessly connected sensing microsystems are described. A plurality of wirelessly communicating sensing microsystems is provided, each sensing microsystem including a temperature sensor and a processor, at least one of the sensing microsystems being coupled to an HVAC unit for control thereof. The plurality of sensing microsystems is configured to jointly carry out at least one shared computational task associated with control of the HVAC unit. Each sensing microsystem includes a power management circuit configured to determine an amount of electrical power available for dedication to the at least one shared computational task. The at least one shared computational task is apportioned among respective ones of the plurality of sensing microsystems according to the amount of electrical power determined to be available for dedication thereto at each respective sensing microsystem.

Abstract: Methods, apparatus, systems and articles of manufacture to control fluid flow in a data center are disclosed herein. An example method disclosed herein comprises sensing a condition of a fluid in a first contained aisle on a first side of data center equipment, the fluid in the first contained aisle substantially isolated from a second contained aisle on a second side of the data center equipment, and controlling a vent to alter the fluid flow between the first contained aisle and the second contained aisle based on the sensed condition.

Abstract: A system including a thermostat user interface for a network-connected thermostat is described. The system includes a thermostat including a frustum-shaped shell body having a circular cross-section and a circular rotatable ring, which is user rotatable for adjusting a setting of the thermostat. The system further includes a client application that is operable on a touch-screen device separate from the thermostat, that displays a graphical representation of a circular dial, that detects a user-input motion proximate the graphical representation, that determines a user-selected setpoint temperature value based on the user-input motion, that displays a numerical representation of the user-selected setpoint temperature value, and that wirelessly transmits to the thermostat data representative of the user-selected setpoint temperature.

Abstract: The current application is directed to intelligent controllers that continuously, periodically, or intermittently calculate and display the time remaining until a control task is projected to be completed by the intelligent controller. In general, the intelligent controller employs multiple different models for the time behavior of one or more parameters or characteristics within a region or volume affected by one or more devices, systems, or other entities controlled by the intelligent controller. The intelligent controller collects data, over time, from which the models are constructed and uses the models to predict the time remaining until one or more characteristics or parameters of the region or volume reaches one or more specified values as a result of intelligent controller control of one or more devices, systems, or other entities.

Abstract: Many different factors may affect a user's perceived thermal comfort level within a building. Controlling a room temperature according to what the temperature may feel like to a user (i.e. the “feels-like” temperature) may increase a user's comfort level in the building. An HVAC controller may be programmed to determine a temperature offset based on one or more environmental conditions in and/or around the building, and to apply the temperature offset to the indoor temperature, resulting in a feels-like temperature. The HVAC controller may be further programmed to control an HVAC system in accordance with the feels-like temperature.

Abstract: A thermostat includes a plurality of HVAC (heating, ventilation, and air conditioning) wire connectors for receiving a plurality of HVAC control wires corresponding to an HVAC system. The thermostat also includes a thermostat processing and control circuit configured to at least partially control the operation of the HVAC system and a powering circuit coupled to the HVAC wire connectors and configured to provide an electrical load power to the thermostat processing and control circuit. The powering circuit has a power extraction circuit configured to extract electrical power from one or more of the plurality of received HVAC control wires up to a first level of electrical power, a rechargeable battery, and a power control circuit. The power control circuit is configured to provide the electrical load power using power from the power extraction circuit and the rechargeable battery.

Abstract: A user-friendly, network-connected learning thermostat is described. The thermostat is made up of (1) a wall-mountable backplate that includes a low-power consuming microcontroller used for activities such as polling sensors and switching on and off the HVAC functions, and (2) separable head unit that includes a higher-power consuming microprocessor, color LCD backlit display, user input devices, and wireless communications modules. The thermostat also includes a rechargeable battery and power-stealing circuitry adapted to harvest power from HVAC triggering circuits. By maintaining the microprocessor in a “sleep” state often compared to the lower-power microcontroller, high-power consuming activities, such as learning computations, wireless network communications and interfacing with a user, can be temporarily performed by the microprocessor even though the activities use energy at a greater rate than is available from the power stealing circuitry.

Abstract: An air conditioner capable of achieving both user comfort and power reduction is provided.

Abstract: A wind power generator generates power through a rotation of a rotor and is interconnected, and operated with its power generation output previously limited in order to be able to further supply the power to a power system in response to a decrease in system frequency. Thus, a concentrated control system derives a required restricted amount corresponding to a power generation output required to respond to the decrease in system frequency, derives a value by subtracting an amount corresponding to a latent power generation output with which the power generation output can be increased, from the required restricted amount, and sets a restricted amount of the power generation output in each wind power generator to perform the operation with the power generation output previously limited to respond to the decrease in system frequency, based on the above value.

Abstract: A forward-looking method and system is provided for determining an economically optimal energy dispatching schema to meet the combined demands of heating, cooling and electrical by an energy plant and a facilities plant. The optimal energy dispatching schema is determined for each of a plurality of incremental time segments defined in a forward-looking time period by optimizing these loads. The schema can be used for real time energy dispatching by the energy plant, in an existing energy plant optimization, and/or a new energy plant planning and design over the forward looking time period or any other forward-looking time period.

Abstract: A system for controlling energy consumption in a building having a heating, ventilation and air-conditioning (HVAC) which includes using an external application to perform HVAC energy consumption optimization algorithms and other external energy control functions and transmit application control data to a building automation system (BAS), which in turn provides hardware level equipment control for the HVAC system. The external application evaluates equipment data received from the HVAC system by way of the BAS and processes these equipment data to provide application control data back to the BAS. The application control data are calculated to achieve a desired operating efficiency for the HVAC system.

Abstract: A thermostat may include one or more temperature sensors, and a processing system configured to be in operative communication with an HVAC system. The processing system may be configured to operate a first operating state characterized by relatively low power consumption and a corresponding relatively low associated heat generation, and a second operating state characterized by relatively high power consumption and a corresponding relatively high associated heat generation. During time intervals in which the processing system is operating in the first operating state, the processing system may process the temperature sensor measurements according to a first ambient temperature determination algorithm to compute the determined ambient temperature.

Abstract: An environmental control device is disclosed and includes a temperature sensor, an audio module, an input/out module operatively connected to an environmental system, a memory module, and a processor in communication with the temperature sensor, the audio module, and the memory. The memory stores a control routine comprising processor executable instructions and an audio file associated with a predefined event related to the environmental system. The processor executable instructions are configured to receive a current state signal corresponding to one of a temperature sensor signal from the temperature sensor and an environmental system output signal from the input/output module, determine whether the current state signal corresponds to the predefined event, and generate, via the audio module, an audible signal based on the audio file in response to determining that the current state signal corresponds to the predefined event.

Abstract: According to an aspect of the disclosure, a processor is configured to detect a location of a mobile device associated with a site and detect at least one geofence operably associated with the site. The processor is further configured to detect a manual input condition provided at a network device disposed at the site, detect the mobile device being disposed away from the site based on the location of the mobile device relative to the at least one geofence, and initiate a text message to the mobile device indicating the manual input condition in response to the mobile device being disposed away from the site. The processor is further configured to detect an altered operating condition received from the mobile device in response to the text message, and alter the manual input condition of the network device at the site using the altered operating condition.

Abstract: Apparatus, systems, methods, and related computer program products for optimizing a schedule of setpoint temperatures used in the control of an HVAC system. The systems disclosed include an energy management system in operation with an intelligent, network-connected thermostat located at a structure. The thermostat includes a schedule of setpoint temperatures that is used to control an HVAC system associated with a structure in which the thermostat is located. The schedule of setpoint temperatures is continually adjusted by small, unnoticeable amounts so that the schedule migrates from the original schedule to an optimal schedule. The optimal schedule may be optimal in terms of energy consumption or some other terms.

Abstract: The invention relates to a thermostat for communicating with a remote maintenance server. The thermostat being configured for receiving and sending network data from and to the remote maintenance server. The thermostat is configured to receive network data provided by a maintenance interface service for receiving and displaying network data from and to a maintenance person. The thermostat is configured for receiving and sending remote controller data from and to a remote controller. The thermostat is configured to receive remote controller data from a user through a controller user interface. The thermostat is configured for receiving and sending appliance data from and to at least one appliance. The thermostat is configured for generating a request for appliance data from the at least one appliance and the thermostat is configured for receiving appliance data in response to the request for appliance data.

Abstract: A thermostat for a HVAC comprising: a data communication port for connection to the HVAC, wherein the thermostat is arranged to communicate via the data communication port an operating parameter of the HVAC, and estimate an energy consumption of the HVAC from the communicated operating parameter of the HVAC. The operating parameter may express a fraction of a nominal load of the HVAC, the thermostat being arranged to estimate the energy consumption from a multiplication of the operating parameter and a nominal energy consumption parameter of the HVAC at the nominal load.

Abstract: A thermostat for a climate control system includes an electronic memory in which at least three occupancy settings are stored. The occupancy settings including a pre-defined unoccupied temperature set-point associated with an unoccupied state, a pre-defined occupied temperature set-point associated with an occupied-awake state and a pre-defined sleep temperature set-point associated with an occupied-asleep state. The thermostat's microprocessor is configured to communicate with the memory, and to establish at least three time periods during the day. The microprocessor assigns to each time period one of at least three user-selectable occupancy states including an unoccupied state, an occupied-awake state and an occupied-asleep state.

Abstract: The disclosure provides an HVAC data processing and communication network and a method of manufacturing the same. In various embodiments, the network includes a subnet controller configured to control networked devices via a data bus. The subnet controller is configured to be addressable over the data bus. An environmental sensor is configured to provide environmental data to the subnet controller, and is further configured to be addressable over the data bus independent of addressing the subnet controller. A user interface is configured to provide access by an operator to the network. The user interface is further configured to be addressable over the data bus independently of addressing the subnet controller and the environmental sensor.

Abstract: An economizer component of a controller used for fuel efficient temperature regulation of a medium circulated through a zone within a hydronic and steam heating system is disclosed. The controller component includes an input interface adapted to determine if the system requires heat based on receiving one or more of a call for heat from the zone, or an indication that a burner of the system is active. The component further includes a dynamic adaptation module configured to provide a burner control signal for heating the system if required. The control signal has an adjustable high limit, and the dynamic adaptation module is configured to increment the adjustable high limit by an increment value, to a value no greater than a maximum high limit, if it is determined that the system requires heat, and decrement the adjustable high limit by a decrement value, to a value no lower than a minimum high limit, if it is determined that the system does not require heat.

Abstract: Systems, methods, and medium remotely monitor and control heating, ventilation and air-conditioning (HVAC) units. The method includes receiving by a processor via a communication network supply temperature data indicating a supply air temperature in a duct coupled to an HVAC unit. The method includes receiving by the processor via the communication network zone temperature data of a space being maintained by the HVAC unit. The method includes receiving by the processor via the communication network thermostat data from a thermostat in the space and analyzing by the processor at least one of the supply temperature data, the zone temperature data and thermostat data. The method includes generating by the processor a control signal responsive to the analysis and transmitting via the communication network the control signal to an HVAC controller, wherein the control signal causes the HVAC controller to control the HVAC unit.

Abstract: Systems and methods herein include features for compensating a temperature reading of a thermostat. The thermostat may include a housing and one or more temperature sensors within the housing. The thermostat may sense a temperature using one or more of the temperature sensors. A processor and/or memory of the thermostat may be capable of and/or configured to compensate the sensed temperature with a first temperature compensation model and compensate the sensed temperature with a second temperature compensation model. During compensation of the sensed temperature, the system may transition from compensating the sensed temperature with the first temperature compensation model to compensating the sensed temperature with the second temperature compensation model over time and independent of the sensed temperature.

Abstract: In accordance with embodiments, there are provided techniques for operating an HVAC to provide substantially contemporaneous thermal feedback in response to a user varying a temperature set point of the system. This is achieved using an HVAC system of the type having a pump in fluid communication with both a supply of gas and a duct system, having an input and an output and defining a flow path therebetween, and a temperature regulation system in thermal communication with the flow path. A controller is in electrical communication with the temperature regulation system and the pump to regulate operation of the HVAC system.

Abstract: Apparatus, systems, methods, and related computer program products for managing demand-response programs and events. The systems disclosed include an energy management system in operation with an intelligent, network-connected thermostat located at a structure. The thermostat acquires various information about the residence, such as a thermal retention characteristic of the residence, a capacity of an HVAC associated with the residence to cool or heat the residence, a likelihood of the residence being occupied, a forecasted weather, a real-time weather, and a real-time occupancy. Such information is used to manage the energy consumption of the structure during a demand-response event.

Abstract: A system is provided for remote control of at least one operating condition of a site. The system includes a proximity detection module at a residential site, which is configured to receive a communication regarding a location of a location reporting device or a mobile device. The proximity detection module is configured to alter or adjust a current temperature setting for the site based on a distance or location of the location reporting device or mobile device relative to the site.

Abstract: A monitoring security system can be coupled to a thermostatic HVAC control module, either wired or wirelessly. In at least some embodiments, the thermostatic module can be communicated with via an interactive interface of the security system. Information as to the operation of the security system and the module can be presented on a common display of the security system, and commands, which are directed to the module, can be entered via the security system.

Abstract: The present invention further provides a motor control system, which controls a motor through a power line. The motor control system includes a control apparatus and an actuation apparatus. The control apparatus includes a controller and a first communication module electrically connected to the controller. The controller receives a command and converts the command into electrical control signals. The first communication module receives the electrical control signals from the controller and transmits the electrical control signals to the power line. The actuation apparatus includes a second communication module and a motor actuator electrically connected to the second communication module. The second communication module is connected to the power line to receive the electrical control signals from the control apparatus and convert the electrical control signals into a command. The motor actuator receives the command from the second communication module to change the power supplying to the motor.

Abstract: A thermostatic controller generally includes a transceiver configured to receive a signal that includes an energy price rate for a given time period, and an electronic memory device in which one or more energy price rates received by the transceiver are stored. A microprocessor is configured to select the lowest energy price rate received within a given time period for establishing a base energy price rate; determine if the energy price rate for a present time period exceeds the base energy price rate by more than a first percentage or multiplier factor of the base energy price rate; and respond to an energy price rate that exceeds the base energy price rate by more than the first percentage or multiplier factor by transmitting a signal via the transceiver to an energy consuming appliance indicating that the energy consuming appliance should be in an off state and/or to one or more ceiling fans to activate, deactivate and/or change speed of the one or more ceiling fans.

Abstract: In a method for supplying a resource to an entity from a resource actuator, a plurality of physics-based models pertaining to the resource actuator and the entity are developed, a condition detected at the entity is received, feedback control on a resource demand of the entity employed based upon the detected condition, feed forward control on the resource demand of the entity is employed based upon the detected condition and the plurality of physics-based models, a constraint optimization problem having an objective function and at least one constraint using the plurality of physics-based models is formulated, a solution to the constraint optimization problem is determined, in which the solution provides the actuator setting, and the resource actuator is set to the actuator setting to supply the entity with the resource from the resource actuator.

Abstract: An HVAC thermostat has a processor configured to control at least one component of an HVAC system in response to temperature and at least one of (1) receive voice over internet protocol (VOIP) data and (2) transmit VOIP data.

Abstract: An outdoor air temperature information acquisition section acquires the outdoor air temperature, a room temperature information acquisition section that acquires room temperature, an air conditioner state information acquisition section that acquires information on the state of heat exchange type air conditioners and the outdoor air cooler, an estimated value calculating section for room temperature during outdoor air cooling calculating the estimated value for room temperature after switching to the complete outdoor air cooling mode that stops the heat exchange type air conditioner and carries out room temperature control by only increasing or decreasing the effect of the outdoor air cooler from the cooling mode mainly using the heat exchange type air conditioner.

Abstract: An HVAC controller is described that is configured to be more intuitive and user friendly to program and operate than convention HVAC controllers. In some instances, the HVAC controller may include a touch screen interface that provides greater flexibility in displaying information to the user and/or soliciting information from the user.

Abstract: A thermostat for controlling an HVAC system is described, the thermostat having a user interface that is visually pleasing, approachable, and easy to use while also providing ready access to, and intuitive navigation within, a menuing system capable of receiving a variety of different types of user settings and/or control parameters. For some embodiments, the thermostat comprises a housing, a ring-shaped user-interface component configured to track a rotational input motion of a user, a processing system configured to identify a setpoint temperature value based on the tracked rotational input motion, and an electronic display coupled to the processing system. An interactive thermostat menuing system is accessible to the user by an inward pressing of the ring-shaped user interface component. User navigation within the interactive thermostat menuing system is achievable by virtue of respective rotational input motions and inward pressings of the ring-shaped user interface component.

Abstract: A method for operating an HVAC system of a building is provided. The method includes providing a model for an indoor temperature of the building, a model for an operating cost of the HVAC system, and predicted future outdoor temperatures. Utilizing at least the models for the indoor temperature and the operating cost of the HVAC system and the predicted future outdoor temperatures, future operating states of the HVAC system can be calculated.

Abstract: Illustrative embodiments of the present invention are directed to methods and systems for receiving physiological data of occupants of a building and using the information to control or regulate a controllable setpoint of a climate-control system for the building. The system may operatively interface with biofeedback sensors including wearable sensors and mountable sensors placed within a controlled space within the building. The system may adjust the controllable setpoint of the climate-control system based on a comfort metric associated with at least one of the occupant of the building, the comfort metric derived from the biofeedback data.

Abstract: The disclosure provides an HVAC data processing and communication network and a method of manufacturing the same. In an embodiment, the HVAC data processing and communication network includes at least one environmental sensor, at least one subnet and a subnet controller. The subnet controller is configured to discover the at least one environmental sensor, the at least one subnet and at least one damper controller. The subnet controller is further configured to set up the network for zoned operation in the event that at least two of the at least one environmental sensor are discovered.

Abstract: In an air conditioning system and a communication method thereof a wireless network may be established between indoor units and a controller or between outdoor units so as to allow communications therebetween, thereby facilitating device addition or device deletion. Also, one or more outdoor units and a plurality of indoor units may be controlled without a dedicated communication line or with using a less mount of the dedicated communication line, and the outdoor units or indoor units may perform communications using one or more communication technologies, such as wireless communication and pipe communication technologies and wireless communication and dedicated line communication technologies, while performing communications with the controller using the wireless communication technology.

Abstract: A thermostat for a climate control system includes an electronic memory in which at least three occupancy settings are stored. The occupancy settings including a pre-defined unoccupied temperature set-point associated with an unoccupied state, a pre-defined occupied temperature set-point associated with an occupied-awake state and a pre-defined sleep temperature set-point associated with an occupied-asleep state. The thermostat's microprocessor is configured to communicate with the memory, and to establish at least three time periods during the day. The microprocessor assigns to each time period one of at least three user-selectable occupancy states including an unoccupied state, an occupied-awake state and an occupied-asleep state.

Abstract: Systems and methods are disclosed for incorporating manual changes to the setpoint for a thermostatic controller into long-term programming of the thermostatic controller. For example, one or more of the exemplary systems compares the actual setpoint at a given time for the thermostatic controller to an expected setpoint for the thermostatic controller in light of the scheduled programming. A determination is then made as to whether the actual setpoint and the expected setpoint are the same or different. Furthermore, a manual change to the actual setpoint for the thermostatic controller is compared to previously recorded setpoint data for the thermostatic controller. At least one rule is then applied for the interpretation of the manual change in light of the previously recorded setpoint data.

Abstract: The invention provides for a controller such as a thermostat for an HVAC system having a housing having a circuit board and a display screen, the display screen having at least one alpha-numeric icon and a group of touch pads having at least two displayable touch pads. A microprocessor provided for controlling the display screen. A sole mechanical button or switch is mounted in the housing and the button has a first end and second end and a touch surface extending between the first end and second end. The sole mechanical button signals the microprocessor in order to adjust the alpha-numeric icon(s), so that the combination of inputs received by the microprocessor from the group of touch pads and sole mechanical button provide for each and every adjustment required for all of the operational functions of the controller. The mechanical button may be a rocker switch. The controller may also include a navigation button.

Abstract: A method and apparatus of controlling the electric power usage of electric thermal storage heaters and systems are based on: 1) current and recorded measurements local to the heater and building; 2) current measurements external to the heater and building; 3) forecasts communicated to the apparatus. The method also includes sending out communications about power use as well as various other local measurements. The apparatus has local controls on the electric thermal storage, including but not limited to the relays that control flow of power into the heating elements, a logic module that integrates the local controls, as well as communication channels that extend outside the building to entities capable of providing automatic forecasts and potentially other types of information not available locally.