An autonomous vehicle (AV) can receive a pick-up location from a backend transport facilitation system to service a pick-up request from a requesting user. The AV can further process sensor data from a sensor array of the AV to dynamically identify potential hazards while autonomously operating the AV along a current route to the pick-up location. The AV can receiving, from the backend transport facilitation system, a set of configuration instructions to configure adjustable components of an interior of the AV based on comfort preferences of the requesting user, and determine an optimal timing schedule to implement each of the set of configuration instructions. Thus, the AV can execute the set of configuration instructions based on the optimal timing schedule to configure the adjustable components of the configurable interior system prior to arriving at the pick-up location.

An air-conditioning apparatus includes a receiving unit configured to receive remote control information transmitted from a remote control device, an adapter configured to receive remote information including operation details conveyed through an external network, an information outputting unit configured to output information when the adapter receives the remote information or when the receiving unit receives the remote control information, and a controller configured to control operations of the information outputting unit. The controller includes an information adjustment unit configured to cause the information outputting unit to output different information when the adapter receives the remote information and when the receiving unit receives the remote control information.

An outdoor unit and an indoor unit communicate with each other. The outdoor unit includes a communication circuit that outputs a pulse signal to be transmitted to the indoor unit. The indoor unit includes a communication circuit that receives the pulse signal transmitted by the outdoor unit. An air conditioner 100 includes at least one photocoupler to transfer to the communication circuit the pulse signal output by the communication circuit. The communication circuit transmits a pulse signal with a first polarity and a pulse width corrected to be shorter by a predefined correction time than a predefined reference pulse width of the pulse signal.

Methods and devices for controlling a heating, ventilation, and air conditioning (HVAC) system by a thermostat are provided. Input can be received from a user via a thermostat, the input being indicative of an adjustment of an HVAC-related setting. On a real-time basis, the HVAC-related setting that is being adjusted can be compared against a feedback criterion designed to indicate a circumstance under which feedback is to be presented to the user. The circumstance can be indicative of an achievement of a HVAC-related setting of a predetermined responsibility level with respect to an energy usage of the HVAC system. Upon a real-time determination that the feedback criterion is satisfied, visual feedback can be caused to be presented to the user in real-time. The real-time feedback can include a visual icon having a visual appeal corresponding to a desirability of the satisfaction of the feedback criterion.

There is provided a control method for an information terminal device having a display and controlling an air conditioner over a network. The control method makes the information terminal device perform processing including: displaying a temperature setting screen where an air conditioner temperature is settable for each of a plurality of time periods; calculating a first time period preset temperature using a first preset temperature at a boundary time and a second preset temperature at a go-to-bed time; calculating a second time period preset temperature using the first preset temperature and a third preset temperature at a wake-up time; displaying the first time period preset temperature and second time period preset temperature; and outputting to the network a control command corresponding to the first preset temperature and second preset temperature when the first time period preset temperature and second time period preset temperature have been fixed.

An HVAC system includes an HVAC unit having a cooling mode and a heating mode for conditioning the air in an inside space, and a programmable thermostat located remotely from the HVAC unit. The HVAC unit may have an onboard controller configured to control when the HVAC unit is in the cooling mode or heating mode, and whether the HVAC unit is activated or not. In some cases, the onboard controller of the HVAC unit may use a common temperature setpoint when controlling in the cooling mode and the heating mode. The programmable thermostat may have a programmable schedule with a plurality of time periods, where each time period has a heating setpoint and a cooling setpoint separated by a dead band. The onboard controller of the HVAC unit may be configured to accept input signals from the remotely located thermostat. The remotely located thermostat may send one or more input signals to the onboard controller of the HVAC unit in accordance with the programmable schedule, where the one or more input signals cause the onboard controller of the HVAC unit to set the HVAC unit to a particular one of the cooling mode and the heating mode, and to activate the HVAC unit so as to condition the air in the inside space in the particular one of the cooling mode and the heating mode.

Apparatus, systems, methods, and related computer program products for carrying out a demand response (DR) event via an intelligent, network-connected thermostat associated with a structure. The systems disclosed include an energy management system in operation with an intelligent, network-connected thermostat located at a structure. The thermostat is operable to control an HVAC system. Control during a DR event period may be performed based on an optimal control trajectory of the HVAC system, where the control trajectory is optimal in that it minimizes a cost function comprising a combination of a first factor representative of a total energy consumption during the DR event period, a second factor representative of a metric of occupant discomfort, and a third factor representative of deviations of a rate of energy consumption over the DR event period.

An HVAC remote controller for use in an HVAC system is described. In some instances, the HVAC remote controller may include a wirelessly interface for communicating with one or more HVAC controllers and/or other HVAC devices. The HVAC remote controller may be configured to execute a user setup routine for entering user setup information, where the user setup routine may cause the HVAC remote controller to display a sequence of two or more user setup screens, sometimes at a common menu level rather than a sub-menu. Some or all of the two or more user setup screens may include, for example, a message center indicating a parameter or function to be set, one or more buttons for adjusting or selecting the parameter or function, and a next button to advance the user setup routine to a next screen in the sequence of user setup screens.

Some embodiments are directed to an apparatus for monitoring at least one thermal control device, the device including a power supply input terminal suitable for being connected to an electric power source. The monitoring apparatus includes an electronic console that stores control instructions from the or each thermal control device. The control instructions include, for each thermal control device, at least one temperature setpoint and one energy consumption setpoint; at least one temperature sensor suitable for providing temperature data measurements, the temperature and energy consumption setpoints being determined based on parameters comprising at least said temperature data measurements; and at least one device for controlling the electric power supply of the or one of the thermal control devices, connected to the power supply input terminal of said device and suitable for controlling the electric power supply of the device based on at least the temperature and energy consumption setpoints.

According to certain embodiments, a thermostat is configured for use in a climate control system. The thermostat is operable to use two-way communication for communicating operational information between the thermostat and at least one rooftop unit (RTU) within the climate control system. For example, the two-way communication comprises sending first operational information to the RTU and receiving second operational information from the RTU. The operational information comprising one or more climate control commands, setpoints, configuration information, diagnostics, and/or sensor data. The thermostat is further operable to operate the climate control system based on the operational information communicated between the thermostat and the RTU.