An in-vehicle ventilation system includes a host ECU configured to acquire vehicle outside information using wireless communication, an air conditioner ECU configured to control an air conditioner installed in a vehicle compartment, a zone ECU configured to control a device in the vehicle compartment and to communicate with the host ECU and the air conditioner ECU and a power window unit configured to open and close a window of a vehicle. The zone ECU or the host ECU is configured to perform, based on information acquired inside the vehicle compartment and the vehicle outside information to be acquired by the host ECU, interlocked ventilation control interlockingly controls the power window unit and the air conditioner ECU.

Disclosed are a vehicle and an air-conditioning control method therefor that are capable of executing an after-blow function for an air-conditioning system without concern about discharge of a battery. The method of controlling an air-conditioning system of an eco-friendly vehicle includes determining a remaining time to a destination when a first condition related to the state of the vehicle and setting of the destination and a second condition related to an indoor temperature of the vehicle are satisfied, determining the state of the air-conditioning system related to condensation water of an evaporator of the air-conditioning system when the remaining time is equal to or less than a first time, and activating an after-blow function to stop the cooling function of the air-conditioning system and to operate a blower based on the determined state of the air-conditioning system.

Provided are techniques for thermally efficient route selection. A request is received for a route for a vehicle to travel from a first geographic location to a second geographic location. Route data is retrieved for each of a plurality of routes, where the route data includes, for each portion of each route at a given time and day, air temperature adjacent to a road surface. Vehicle data is retrieved for the vehicle, where the vehicle data includes a desired temperature of an item being carried and a desired inlet air temperature. The route from the first geographic location to the second geographic location is determined using the route data and the vehicle data, where the route is thermally efficient. The vehicle is directed along the route, where the route specifies a lane from a plurality of lanes of a road for each portion of the route.

An air-conditioning control system acquires settlement information on an electronic settlement performed by an occupant D of a vehicle using a mobile terminal via a car-navigation system from the mobile terminal having an electronic settlement function, and controls an air conditioner on the basis of the acquired settlement information. The settlement information includes a commodity purchased by the electronic settlement or a service having a value paid by the electronic settlement, as a settlement target.

A system for managing ripeness of perishable goods including: a storage device to store perishable good requirements, ripening capability parameters, ripening schedules, and perishable good parameters associated with the perishable goods; and a ripeness management system coupled to the storage device. The ripeness management system including: a current ripeness determination module to determine current ripeness levels in response to at least one of the perishable good parameters, the perishable good requirements, and the ripening schedules; a ripeness schedule module to determine predicted ripeness levels in response to at least one of the current ripeness levels, the ripening capability parameters, and the ripening schedules; and a meshing module to determine ripening schedule adjustments in response to at least one of the current ripeness levels, the perishable good parameters, the ripening schedules, and the ripening capability parameters.

A server includes a processor, programmed to receive a vehicle location from a vehicle, receive a weather condition of the vehicle location from a cloud server, responsive to receiving a calendar of a user including an event, calculate a departure time based on the vehicle location and a location of the event, responsive to receiving a desired cabin temperature of the user from a mobile device, calculate a minimum time for the vehicle to reach the desired cabin temperature based on the weather condition, calculate a vehicle start time using the departure time and the minimum time, and send an instruction to the vehicle to start at the vehicle start time.

A defrosting control system includes processing circuitry. The processing circuitry calculates a frost formation rate, indicating a frost formation amount of a windowpane on which frost is formed at an estimated departure time of a vehicle, based on frost formation information and the estimated departure time. The processing circuitry calculates an operation period of a defroster needed to remove frost from the windowpane based on the frost formation rate. The processing circuitry determines that an activation time of the defroster is a time earlier than the estimated departure time by the operation period. The processing circuitry transmits an operation request signal for starting operation of the defroster at the activation time.

A vehicle air conditioning system, including: a vehicle interior environmental information acquisition unit that acquires environmental information of a vehicle interior; a vehicle exterior environmental information acquisition unit that acquires environmental information of surroundings of the vehicle; a sensible temperature prediction unit that predicts a sensible temperature of an occupant of the vehicle after a predetermined amount of time has elapsed, based on the environmental information acquired by the vehicle cabin interior environmental information acquisition unit and the vehicle cabin exterior environmental information acquisition unit; and an air conditioner controller that controls an air conditioner based on information regarding a future sensible temperature of the occupant which has been predicted by the sensible temperature prediction unit and a comfortable sensible temperature of the occupant which is stored in a storage unit.

A system and method are described for providing an air quality alert to an occupant of a host vehicle. The system includes a communication unit adapted to be mounted in the host vehicle and configured to receive a wireless vehicle-to-x communication comprising an air quality value associated with a geographic area outside the host vehicle. The system also includes a controller adapted to be mounted in the vehicle and provided in communication with the communication unit. The controller is configured to generate an air quality alert control signal operative to provide an air quality alert to the occupant of the host vehicle based on a relationship of the air quality value to an air quality threshold value.

The vehicle air conditioning apparatus comprises at least one physical condition information sensor which detects information on physical conditions of passengers in a vehicle as physical condition information. The vehicle air conditioning apparatus selectively executes an outside-air circulation control for discharging air from an interior of the vehicle to outside of the vehicle and introducing outside air to the interior of the vehicle from the outside of the vehicle and an interior-air circulation control for taking the air from the interior of the vehicle and returning the taken air to the interior of the vehicle. The vehicle air conditioning apparatus executes the outside-air circulation control when the electronic control unit determines that at least one of the passengers has an infection, based on the physical condition information.