An air conditioning control system includes processing circuitry. The processing circuitry includes an ambient temperature obtainment unit, a departure time estimation unit configured to estimate a departure time of a vehicle, an air conditioning condition calculator configured to calculate an operation period and an operation output that allow a passenger compartment temperature of the vehicle to reach a preset target temperature, an air conditioning start time determination unit configured to determine an activation time of an air conditioner, and an air conditioning controller. The air conditioning start time determination unit is configured to determine that the activation time is a time earlier than the departure time by the operation period.

Disclosed may be a method of controlling a valet mode of a vehicle, the method including determining whether the vehicle may be in valet mode, when the vehicle may be determined to be in the valet mode, setting the vehicle to a plurality of parking state modes based on the traveling state of the vehicle being parked, and calculating an air conditioning limit power capable of limiting the air conditioning of the vehicle based on each of the valet mode and the plurality of set parking state modes.

A display system may include a camera configured to capture an image of a calibration reference associated with an automobile, a display, and a controller in communication with the camera and the display. The controller may be configured to selectively adjust a color temperature of the display based on the image of the calibration reference.

A computer includes a processor and a memory storing instructions executable by the processor to receive data indicating that an electric vehicle is in an enclosed space; in response to receiving the data, instruct window actuators of the electric vehicle to open windows of the electric vehicle; and in response to receiving the data, instruct a heater of the electric vehicle to generate heat.

Systems, apparatuses, and methods disclosed provide for receiving internal information, external static information, and external dynamic information of a hybrid vehicle, and selectively enable or disable a stop/start function for the engine of the hybrid vehicle based on the internal hybrid vehicle information, external static information, and external dynamic information. The stop/start function controls selective activation and deactivation of the engine during operation of the hybrid vehicle.

A motor-vehicle includes one or more electrically-operated valves, arranged on the structure of the motor-vehicle in a lower position with respect to the windows, for providing a communication between a passenger compartment and the external environment, and one or more electronic control units programmed to activate a ventilation mode of the passenger compartment when the motor-vehicle is parked with the engine off, even with the driver outside the vehicle. The ventilation mode includes controlling at least partial opening of one or more windows and the opening of one or more of the valves to generate a flow of natural air from the bottom upwards through the passenger compartment of the motor-vehicle.

An exhaust intrusion mitigation system for a vehicle includes one or more processors and a memory communicably coupled to the one or more processors. The memory stores an enclosure detection module which determines if a vehicle is parked within an enclosure with the engine running. An exhaust module determines a point in time at which one or more vehicle vents should be closed if the vehicle remains in the enclosure and the engine remains on. A mitigation module controls operation of the vehicle to close the one or more vents at the point in time when the vent(s) should be closed.

A vehicular air-conditioning device includes an inside air temperature detector, an inside air-conditioning portion, and an air-conditioning controller. The inside air-conditioning portion includes a temperature adjuster and a blower. The air-conditioning controller includes an auto control portion, an open signal detector, a thermal load determiner, and a power saving control portion. The auto control portion is configured to perform an auto control. The open signal detector is configured to detect an open signal. The thermal load determiner is configured to determine whether a thermal load on the passenger compartment exceeds an air-conditioning capacity of the auto control. The power saving control portion is configured to perform a power saving control to limit an increase of a power consumption regardless of the inside air temperature when the open signal is detected and it is determined that the thermal load exceeds the air-conditioning capacity of the auto control.

A method for preparing a vehicle prior to an occupant entering the vehicle includes acquiring information indicative of an upcoming time of entry of the occupant into a compartment of the vehicle, and commencing air replacement of at least part of the air in the compartment of the vehicle prior to the upcoming time of entry of the occupant. In some embodiments, the method also includes detecting whether the compartment of the vehicle has occupants, and commencing the air replacement responsive to detecting that the compartment of the vehicle has no occupants. In some embodiments, the method further includes determining a latest possible time for commencing the air replacement provided that the air replacement is to be completed at the upcoming time of entry of the occupant, and commencing the air replacement based on the determined latest possible time.

In a case where an engine is started based on a remote operation, a limitation condition for limiting an engine start is tightened or a stop condition after the engine is started is relaxed, as compared to a case where the engine is started based on a switch operation in an occupant cabin. That is, it is difficult to start the engine when the engine is started based on the remote operation, and it is easy to stop the engine when the engine is started based on the remote operation. As a result, it is possible to take more appropriate measures when the engine is started based on the remote operation.