A method of controlling a temperature of water delivered by a water heating system, includes providing communication device which is adapted to receive a communication from at least one mobile device, the communication device being located so as to determine when the at least one mobile device is within a predefined zone in which is located a pre-selected water access point. In response to a determination that the at least one mobile device is within the predefined zone, enabling a user selecting a temperature setting of the where the water heating system. The selection is wirelessly communicated to a receiver which is in communication with the water heating system.

A battery-operated wireless control system for outdoor cooking and heating appliances is disclosed. The system may include an electronic controller paired to a wireless temperature probe and a wireless monitor device capable of storing and recharging the wireless temperature probe. The electronic controller may control the operation of a fuel supply assembly, a fan assembly, and a spark generating assembly included in the appliance.

Methods and systems facilitate network communications between a wireless network-connected thermostat and a cloud-based management server in a manner that promotes reduced power usage and extended service life of a energy-storage device of the thermostat, while at the same time accomplishing timely data transfer between the thermostat and the cloud-based management server for suitable and time-appropriate control of an HVAC system. The thermostat further comprises powering circuitry configured to: extract electrical power from one or more HVAC control wires in a manner that does not require a “common” wire; supply electrical power for thermostat operation; recharge the energy-storage device (if needed) using any surplus extracted power; and discharge the energy-storage device to assist in supplying electrical power for thermostat operation during intervals in which the extracted power alone is insufficient for thermostat operation.

A wireless device used to communicate with and control one or more components of an HVAC system from a remote location is provided. The wireless device is configured to display two or more icons on the display of the device, wherein each icon executes a function that aids the user in controlling one or more components of the HVAC system. The wireless device dynamically orders the two or more icons on the display of the device, each according to a dynamic ranking algorithm. The dynamic ranking algorithm is based on a number of factors such as, for example, a relative frequency of selection of each of the two or more icons by a user, the current time of day, the current time of year, the current temperature, and/or the current location of the wireless device.

An intercept device for HVAC controls that allows for overrides of local settings, either by onboard processing and storage, or by networked communication with on-premise or off-premise control mechanisms or cloud services. The existing thermostat may be mounted directly to the intercept device, or the intercept device may be located at any other location along the control line between the existing thermostat and the controlled equipment, allowing for retention of the original thermostats interface, controls, and aesthetics. The HVAC control intercept may also incorporate wired or wireless networking functions, and additional onboard controls and displays to allow for direct adjustment of the intercept device settings and operational mode.

An air-conditioning setting screen has a coordinate space defined by a Y-axis along which temperature items are indicated in increments of one degree and an X-axis along which time-point items are indicated in increments of one hour. Operation points PT corresponding to the time-point items are arranged in the coordinate space. The air-conditioning setting screen displays time-series changes in a previous day's body-movement values such that the density of a background color is higher for times at which the body-movement value is larger and the density of a background color is lower for times at which the body-movement value is smaller.

A thermostat device may include a processing system configured to learn a heating schedule at a first location according to an automated schedule learning algorithm that processes inputs including user inputs and occupancy sensing inputs and derives schedule-affecting parameters therefrom that are processed to compute the heating schedule. The processing system may also be configured to determine whether the thermostat has been moved to a new location, and if it is determined that the thermostat has been moved to the new location, then determine one or more parameters associated with the new location and establish a new heating schedule for the new location, and where zero or more of the previously measured schedule-affecting parameters are re-used based on the one or more parameters associated with the new location.

A temperature control system includes a central control system including a central controller that outputs a temperature command signal, and a DC power source configured to output a DC power, wherein the central control system is configured to combine the DC power with temperature command signals to output a modulated power signal on a power line.

A method, system or computer usable program product for controlling an on-demand hot water heater including providing a plurality of nodes for receiving hot water from an on-demand hot water heater in a hot water delivery system, receiving a demand with a node identifier for hot water at a node, determining a hot water temperature for the node from a centralized database, the database including a set of node identifiers with a corresponding set of preset hot water temperatures, and controlling a temperature of hot water flowing from the water heater based on the determined hot water temperature.

The method simultaneously manages climate control systems of a fleet of vehicles at a fleet server remote from the vehicles. The fleet server has one or more processors and memory storing one or more programs for execution by the processor(s). Initially, at least one parameter relaying information about performance of a climate control system of a respective vehicle is received, from each vehicle. Each vehicle's climate control system includes at least an electrically driven compressor. The system then determines whether a performance inefficiency exists for the climate control system of at least one vehicle based at least in part on the parameter(s) received from the at least one vehicle. Upon determining that a performance inefficiency exists, an efficient operational setting that reduces the performance inefficiency is determined. Finally, an operational setting instruction is transmitted to the at least one vehicle to control the climate control system of that vehicle.