Abstract: A system for activating a vehicle to a key-on state by detecting a presence of a near field communication (“NFC”) tag is provided. The system includes a vehicle bus, a start button in communication with the vehicle bus, an NFC antenna, and a control module. The NFC antenna is positioned to selectively couple with the NFC tag if the NFC tag is within a predetermined distance from the NFC antenna. The control module is in communication with the NFC antenna and the start button. The control module includes control logic for determining if the determining if the NFC antenna is coupled with the NFC tag. The control module includes control logic for determining if the start button has received the input to activate the vehicle to the key-on state. The control module includes control logic for sending a signal through the vehicle bus to activate the vehicle.

Abstract: A passive entry passive start (PEPS) system is provided for performing at least one PEPS function with respect to a vehicle as an end device (e.g., smart phone or key fob, etc.) approaches the vehicle and comes within range for authorization. The vehicle includes a plurality of sensors and a central module. The central module is communicatively coupled to the end device and to the sensors via short-range wireless connections. The central module can determine, based on signal strength information provided from the sensors or the end device, whether the end device is within range for authorization. When the end device is determined to be within range for authorization, the central module can control performance of at least one PEPS function at the vehicle.

Abstract: A system is provided that includes a wireless communication device (or end device), a vehicle having a central module, and a key provisioning server. The key provisioning server is communicatively coupled to the wireless communication device and the central module via wireless connections. The central module can establish a wireless connection with the wireless communication device to initiate a current communication session. When the wireless connection is established with the central module, the wireless communication device communicates a request message to request temporary security information (e.g., public key and/or a digital certificate). The key provisioning server can then provide, in response to the request message, the temporary security information to the wireless communication device and/or the central module. The temporary security information can then be used to encrypt communications between the wireless communication device and the central module.

Abstract: A device location determination includes authenticating a device within range of a vehicle via a node in a vehicle. The vehicle includes a first peripheral device and a second peripheral device that is disposed at a location on the vehicle that is different than the first peripheral device. The peripheral devices are coupled to an antenna of the node. The device location determination also includes receiving from the device a first signal strength value associated with a first signal of the first peripheral device, a second signal strength value associated with a second signal of the second peripheral device, and a third signal strength value associated with a third signal transmitted by the node. The device location determination also includes determining a location of the device from the signal strength values and performing a remote function with respect to the vehicle.

Abstract: Mobile device-activated vehicle functions are implemented by authenticating a vehicle with a device via wireless signals transmitted between a low frequency antenna of the device and a low frequency antenna of the vehicle when the vehicle is in communicative range of the device. The mobile device-activated vehicle functions are further implemented by receiving, via computer processor embedded in the device, a selection from one of a plurality of input components embedded in the device, the selection associated with a vehicle function, and transmitting a request to implement the vehicle function via the low frequency antenna coupled to the computer processor and the low frequency antenna of the vehicle.

Abstract: Vehicle lane changing monitor functions are implemented by a lane sensor disposed in a vehicle, a gaze detection sensor disposed in the vehicle, and a computer processor embedded in the vehicle. Logic that is executable by the computer processor implements a method. The method includes receiving data, from the lane sensor, indicating an occurrence of a lane shifting event that indicates the vehicle is drifting away from a vehicle lane. The method further includes monitoring biometric data received from the gaze detection sensor and, upon determining a gaze change event has not occurred within a threshold period of time with respect to the lane shifting event, a corrective action within the vehicle is initiated.

Abstract: A vehicle user control system includes an interactive pad providing tactile feedback to a user and disposed on an exterior portion of a steering wheel. Also included is a controller in operable communication with the interactive pad and at least one vehicle component, wherein the controller is configured to perform at least one vehicle command associated with the at least one vehicle component.

Abstract: A system for activating a vehicle to a key-on state by detecting a presence of a near field communication (“NFC”) tag is provided. The system includes a vehicle bus, a start button in communication with the vehicle bus, an NFC antenna, and a control module. The NFC antenna is positioned to selectively couple with the NFC tag if the NFC tag is within a predetermined distance from the NFC antenna. The control module is in communication with the NFC antenna and the start button. The control module includes control logic for determining if the determining if the NFC antenna is coupled with the NFC tag. The control module includes control logic for determining if the start button has received the input to activate the vehicle to the key-on state. The control module includes control logic for sending a signal through the vehicle bus to activate the vehicle.

Abstract: In-vehicle functions are implemented using a location device disposed in a vehicle, a central controller of the vehicle, and logic executable by a computer processor of the central controller. The location device includes a wireless communications interface. The logic receives a unique identifier of the location device. The unique identifier identifies a location in the vehicle in which the location device is disposed. The logic also validates the location device and an end user device in response to activation of the location device by the end user device via the communications interface. The logic further receives a request from the end user device to implement end user-configured settings for an electronic component that services the location in the vehicle corresponding to the unique identifier and activates the electronic component based on the end user-configured settings.

Abstract: A carbon dioxide feedback system and a method of providing carbon dioxide feedback in a computer system is provided. The method includes computing an amount of carbon dioxide generation avoided by a vehicle at a processor, calculating a number of equivalent trees based on the computation, and displaying the number of equivalent trees on a display device.

Abstract: A method of controlling a vehicle system of a vehicle is provided. The method includes: receiving image data that is captured from an occupant of the vehicle; determining a focus of the occupant of the vehicle based on the image data; and generating a user command to control the vehicle system based on the focus of the occupant.

Abstract: In-vehicle messaging includes intercepting an incoming communication on a mobile communication device. The incoming communication is received by a messaging application on the mobile communication device. The in-vehicle messaging also includes parsing the communication, associating elements of the communication with metadata of a digital music application, and transmitting the communication, as well as instructions for handling the communication, over a communication link between the mobile communication device and a vehicle stereo system for presentation on a component of the vehicle stereo system.

Abstract: Remote application of vehicle control settings includes detecting a vehicle in proximity of the mobile communication device, authenticating the vehicle via a secured pairing between an identifier of the vehicle and an identifier of the mobile communication device, retrieving driver preference settings assigned to the identifier of the vehicle and the identifier of the mobile communication device, and transmitting the driver preference settings to the vehicle.

Abstract: Remote application of vehicle control settings includes detecting a vehicle in proximity of the mobile communication device, authenticating the vehicle via a secured pairing between an identifier of the vehicle and an identifier of the mobile communication device, retrieving driver preference settings assigned to the identifier of the vehicle and the identifier of the mobile communication device, and transmitting the driver preference settings to the vehicle.

Abstract: A connectivity device is provided. The connectivity device includes at least one network transceiver that communicates with a vehicle network. At least one wireless communication module communicates with a remote device. A message manager module manages communications between the at least one network transceiver and the at least one wireless communication module.

Abstract: A carbon dioxide feedback system and a method of providing carbon dioxide feedback in a computer system is provided. The method includes computing an amount of carbon dioxide generation avoided by a vehicle at a processor, calculating a number of equivalent trees based on the computation, and displaying the number of equivalent trees on a display device.

Abstract: A vehicle communication method is provided. The method includes receiving a first wireless communication that is transmitted from a remote device; and managing a transmission of the first wireless communication over a vehicle network using a configurable message list.

Abstract: A method of remotely starting a vehicle using a remote device is provided. The method includes: receiving a first temperature associated with the vehicle; evaluating the first temperature at the remote device; and initiating the starting of the vehicle by generating a signal to the vehicle based on the start request and the first temperature.