Systems and methods are disclosed for supporting and executing automated control of climate comfort settings based on user classification within a group identity database. Methods of generating and employing the group identity database are also disclosed.

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 method and system for a responsive climate control interface are disclosed. The climate control interface includes an interactive element further comprised of a climate settings map and a climate setting selector. The climate setting selector can be moved to different locations on the climate settings map in order to select a climate setting with a particular temperature and fan speed. The appearance of both the climate settings map and the climate setting selector can be changed as the climate change selector is moved in order to visually indicate temperature and fan speed settings. The system also includes a haptic feedback module that can convert climate settings into haptic feedback levels.

An in-car temperature-controlling device for a car in its parked state uses a wireless remote control to remotely control a power-activating unit, an engine-starting unit, a window-activating unit and an AC-activating unit of the car, so as to adjust the car's in-car temperature. Its installation is easy and needs no structural changes to the car, so the car using the device can, in its parked state, have its in-car temperature prevented from being too high or too low. The in-car temperature-controlling device is characterized in contributing to convenience, safety, comfort and low costs, and is applicable to all existing and newly built cars.

A motor vehicle comprises an HVAC system including a climate control circuit coupled to onboard sensors, a human-machine interface, and climate actuators. The actuators are responsive to respective command parameters generated by the control circuit in response to the sensors and the human-machine interface. A wireless communication system transmits vehicle HVAC data to and receives crowd data from a remote server. The control circuit initiates a request for crowd data via the communication system to the remote server, wherein the request includes peer parameters for identifying a vehicle environment. The control circuit receives a response via the communication system from the remote server. The response comprises crowd data and at least one weight indicating a confidence level associated with the crowd data. The control circuit generates at least one command parameter using a set of fuzzy rules responsive to the crowd data and the weight from the response.

A method for vehicle selection performed by a user equipment (UE) associated with a customer includes transmitting, from the UE to a vehicle control system, customer location information identifying a location of the customer. The method also includes receiving, from the vehicle control system based on transmitting the customer location information, vehicle location information and a set of compartment climate values associated with each vehicle of a set of vehicles within a range of the location of the customer. The method further includes outputting the current compartment climate value and a location associated with the vehicle location information of each vehicle of the set of vehicles for display at the UE. The method still further includes transmitting, to the vehicle control system, a message indicating a selection of one vehicle of the set of vehicles based on receiving a customer input at the UE, the one vehicle being selected based on one or both of the current compartment climate value of the one vehicle and the location associated with the vehicle location information of the one vehicle.

A method of notifying in-car air pollution is disclosed and includes: a) providing an in-car air pollution detection system including at least one in-car gas detection module, at least one out-car gas detection module, an in-car air conditioner including an audio element and a display element, and a plurality of filtering and purification components disposed in the interior space of the car for filtering and purifying the air pollution source in the interior space of the car; b) notifying an initial value of the in-car gas detection datum; c) notifying a post-purification value of the in-car gas detection datum, wherein the post-purification value of the in-car gas detection datum is broadcasted by the audio element and/or displayed by the display element of the in-car air conditioner; and d) intelligently selecting an external gas to be introduced or not to be introduced into the interior space of the car.

A multi-touch smartphone display used as a track pad in a motor vehicle is provided. A system includes a handheld device having a multi-touch display, a vehicle controller that transmits and receives data from the handheld device when the handheld device is docked into the vehicle, and a display that is mounted within the vehicle. The docked handheld device functions as a track pad to receive user input. The display is configured to display vehicle functions and applications on the handheld device. The vehicle controller is configured to transmit one or more commands to one or more vehicle components based on the received user input to execute the command.

A system and method for selectively controlling a specific window of a power window system of a vehicle. The system includes a portable remote control including activation switches, each corresponding to a specific power window of a vehicle, a first wireless transceiver mounted onto the vehicle, and a second wireless transceiver disposed in the portable remote control. Actuation of an activation switch causes the second wireless transceiver to communicate a demand signal to the first wireless transceiver that identifies the specific power window of the vehicle corresponding to the actuated activation switch. The first wireless transceiver receives the demand signal and communicates instruction to an electronic control unit of the vehicle to actuate the specific window identified by the demand signal. The electronic control unit then actuates the specific power window of the vehicle that corresponds to the activation switch initially actuated.

An air conditioning system for a vehicle that air conditions a vehicle cabin before a user gets into a vehicle, in which the air conditioning system strongly air conditions the vehicle cabin by increasing an air conditioning output for a predetermined period after the user gets into the vehicle.