A vehicle includes a vehicle cabin, a filter configured to allow air blown toward the vehicle cabin to pass through the filter while adsorbing at least a portion of a substance contained in the air, a sensor configured to detect the state of the air passing through the filter, and a control device configured to output information relating to maintenance of the filter based on the result of detection performed by the sensor.

Systems and methods are provided for temperature regulation in an autonomous vehicle. In particular, systems and methods are provided for regulating the interior temperature of a delivery container in an autonomous vehicle. In various implementations, the delivery container includes one or more compartments, and a thermal management system is provided for regulating the temperature of each of the compartments.

A vehicle microclimate system includes a microclimate device that is configured to be arranged within an interior space that provides a macroclimate environment to an occupant. The microclimate device is configured to provide a microclimate environment to the occupant. The microclimate device is configured to be in close proximity to a region of the occupant having an increased thermoreceptive response compared to other occupant regions exposed to the macroclimate environment. A controller is in communication with the microclimate device. The controller is configured to determine an occupant personal comfort and automatically command the microclimate device in response to the occupant personal comfort to achieve a desired occupant personal comfort.

The present embodiments refer to a controlling system configured to be installed in a recreational vehicle, cooling devices comprising or coupled to such controlling systems, a recreational vehicle comprising such controlling systems and methods for controlling cooling the cooling devices. The controlling system comprises a central processing unit, a read out unit and a controlling unit and is configured to be coupled to a plurality of electronic devices of the recreational vehicle. The read out unit of the controlling system is configured to read out data from the electronic devices and/or sensors of the recreational vehicle coupled to the controlling system and to forward the read out data to the central processing unit. The central processing unit is configured to receive and to process the read out data received from the read out unit and to forward processed data to the controlling unit. The controlling unit is configured to receive the processed data from the central processing unit and to control at least one of the electronic devices based on at least some of the processed data.

Methods and systems for mitigating irritants during travel in a vehicle. The method includes determining, at a remote server, an airborne irritant is present external to the vehicle, which may involve data from the vehicle or from other nearby vehicles. The data may be direct irritant measurements by sensors or may be indirect data indicative of possible irritants. Based on the determination that the airborne irritant is likely present external to the vehicle, an irritant mitigation action is caused within the vehicle. The irritant mitigation action may include displaying a notification signaling presence of the airborne irritant, outputting an audio notification signaling presence of the airborne irritant, closing a window of the vehicle, or closing an air vent of the vehicle.

Methods and systems for operating a transport climate control system of a vehicle are provided. The method includes obtaining a state of charge of an energy storage device capable of providing power to the transport climate control system; determining an energy level including the state of charge, receiving a planned route for the vehicle, and receiving route status data associated with the planned route for the vehicle. The route status data includes traffic data, weather data, and/or geographic data identifying areas where the transport climate control system is to be solely powered by the energy storage device. The method further includes determining whether the energy level is sufficient to complete the planned route for the vehicle based on the planned route and the route data, and when the energy level is not sufficient to complete the planned route for the vehicle, providing a notification to a user via a display.

An air-conditioning control system includes: a weather information providing system and an air-conditioning control apparatus that controls an air conditioner installed in a vehicle. The air-conditioning control apparatus includes: a receiving unit that receives, from the weather information providing system, first weather information indicating an estimated weather condition predicted at the vehicle; a measurement unit that performs measurements concerning second weather information indicating an actual weather condition at the position of the vehicle; a judgment unit that judges whether or not a reliability level of the first weather information is below a first threshold value by comparing the first weather information and the second weather information or by detecting a change per unit time of the second weather information; and a transmission unit that transmits, to the weather information providing system.

The various embodiments described herein include methods, devices, and systems for managing client control systems of a fleet of vehicles. In one aspect, a method includes (i) receiving, at a controller from a fleet server remote from at least one vehicle, at least one graphics instruction relating to a state of the at least one vehicle's auxiliary power source, and (ii) displaying on a graphical user interface (GUI), (a) a parameter associated with a climate control system of the at least one vehicle, and (b) a ring surrounding the parameter. The ring represents the state of the auxiliary power source that changes color, intensity, or size based on a degree of energy efficiency of the climate control system of the at least one vehicle.

A mechanism is provided for controlling the internal air-quality of a vehicle, including determining a changing trend of the in-vehicle air-quality based on acquired in-vehicle sensor data and usage status of the vehicle and responsive to the determined changing trend of the in-vehicle air-quality, signaling a control system of the vehicle to control the usage status of the vehicle based on a control policy.

A computer-implemented method includes receiving, with a vehicle computing system, global position system (GPS) data associated with a vehicle, determining a solar position relative to the vehicle, receiving trip information associated with the vehicle, and executing one or more vehicle actuators based at least in part on the GPS data, the trip information and the solar position relative to the vehicle. Determining the solar position can include determining a sun glare period during a future time period based at least in part on the trip information associated with the vehicle. The vehicle computing system may display a warning indicative of the sun glare period, generate a window tint command that causes the window to tint and/or generate a vent control command that causes the vent to change one or more of an airflow temperature, and an airflow velocity.