Abstract: A mobile communication system and a method of providing content data to user of a vehicle using the communication system. The method includes: determining at a vehicle a last-used content data function associated with a previous ignition cycle, wherein the last-used content data function was used to provide content data to vehicle users; determining an adaptive boot sequence that includes the last-used content data function; executing the adaptive boot sequence at a subsequent ignition cycle which includes initiating the last-used content data function; and providing content data in the vehicle via the last-used content data function.

Abstract: A system and method of controlling a digital radio broadcast receiver in a vehicle includes: detecting an instruction to activate the digital radio broadcast receiver; accessing a software application at the vehicle in response to the instruction; and activating the digital radio broadcast receiver in the vehicle at the direction of the software application.

Abstract: A system and method are provided for re-provisioning a telematics unit of a telematics-equipped vehicle for wireless services. The re-provisioning process includes: connecting a computing device to an on-board diagnostics interface of the telematics-equipped vehicle; accessing a subscriber identification card of the telematics unit via the on-board diagnostics interface; requesting subscription information from a subscriber credentials server via a network connection; receiving the subscription information; and reprogramming the subscriber identification card of the telematics unit for wireless services based on the received subscription information.

Abstract: A system and method for reminding a user to dock a mobile device in a docking apparatus within a vehicle are provided. A docking apparatus includes: one or more sensors for determining whether an object is present in the docking apparatus; and at least one of speakers, a vibration mechanism, and one or more display indicators for reminding a user to place the mobile device in the docking apparatus when the one or more sensors determine that an object is not present in the docking apparatus. A system includes the docking apparatus and a mobile device. The method includes receiving an indication that the vehicle ignition is turned on; determining whether the mobile device is in a docking apparatus; and reminding the user to dock the mobile device in the docking apparatus.

Abstract: A mobile communication system and a method of providing content data to user of a vehicle using the communication system. The method includes: determining at a vehicle a last-used content data function associated with a previous ignition cycle, wherein the last-used content data function was used to provide content data to vehicle users; determining an adaptive boot sequence that includes the last-used content data function; executing the adaptive boot sequence at a subsequent ignition cycle which includes initiating the last-used content data function; and providing content data in the vehicle via the last-used content data function.

Abstract: A method and system for maintaining a wireless carrier system presence at a vehicle telematics unit in a vehicle includes placing the vehicle telematics unit in a quiescent mode that suspends its signal transmitting functions; instructing the vehicle telematics unit to periodically exit the quiescent mode and transmit a query that determines if the wireless carrier system used by a telematics service provider has changed; when the wireless carrier system has changed, receiving a new wireless profile associated with a new wireless carrier system; and storing the new wireless profile in a universal integrated circuit card (UICC) hardwired at the vehicle.

Abstract: The described method and system provide for synchronizing a mobile application on a mobile device with a DRx (discontinuous receive) schedule of a vehicle. When the vehicle ignition is turned off, a telecommunications unit on the vehicle sends a synchronization message to the mobile device, which allows the mobile application to synchronize with the DRx schedule of the vehicle. The DRx schedule includes a standby mode, a cyclic mode, and a powered down mode for the vehicle, and user requests inputted into the mobile application will be processed according to the mobile application's determination of vehicle availability during those modes. The mobile application is thus able to inform the user of the vehicle status at any point during the vehicle's DRx schedule without requiring any further information from the vehicle after the synchronization message.

Abstract: A method of collecting vehicle operating information using a wireless device includes the steps of communicatively linking a wireless device located within a vehicle to a vehicle telematics unit; receiving vehicle data at the wireless device from the vehicle telematics unit using the link; recording the received vehicle data at the wireless device; detecting that the wireless device is no longer present in the vehicle; and wirelessly transmitting the recorded vehicle data to a central facility using the wireless capabilities of the wireless device based on the detection.

Abstract: A system and method of controlling a digital radio broadcast receiver in a vehicle includes: detecting an instruction to activate the digital radio broadcast receiver; accessing a software application at the vehicle in response to the instruction; and activating the digital radio broadcast receiver in the vehicle at the direction of the software application.

Abstract: An aftermarket device is disclosed herein. In an embodiment, the aftermarket device includes, but is not limited to, a housing that is configured to be mounted to an internal surface of a vehicle. The aftermarket device further includes, but is not limited to a processor that is mounted within the housing. The aftermarket device still further includes, but is not limited to, a mounting sensor that is associated with the housing and that is communicatively coupled with the processor. The mounting sensor is configured to detect a mounting status of the housing and to provide a signal to the processor. The signal contains information indicative of the mounting status of the housing. The processor is configured to determine that the housing is improperly mounted to the internal surface of the vehicle based on the mounting status.

Abstract: A collision sensor, a collision sensing system, and a method of mounting a collision sensor to a vehicle are disclosed herein. An embodiment of the collision sensor includes, but is not limited to, a processor and a three-axis accelerometer that is communicatively coupled with the processor. The three-axis accelerometer is configured to detect an acceleration experienced by a vehicle and to generate a signal indicative of the acceleration. The processor is configured to obtain the signal from the three-axis accelerometer and to determine when the vehicle has experienced a collision based, at least in part, on the signal.

Abstract: An aftermarket module arrangement for installation into a vehicle having a vehicle bus and an electric power source is disclosed herein. The arrangement includes, but is not limited to, a module configured to communicatively couple with the vehicle bus and to electrically couple with the electric power source via a first electric power line, and further configured to engage in power line communications over the first electric power line. The arrangement further includes an aftermarket module configured to electrically couple with the electric power source over a second electric power line and to engage in power line communications over the second electric power line. The aftermarket module is further configured to communicatively couple with the module via power line communications and to communicate over the vehicle bus through the module.

Abstract: A vehicle-incident detection method is disclosed herein. Vehicle data is received at a cloud computing system from a vehicle, where the vehicle data is generated by the vehicle in response to an initial detection of a vehicle-related event. After receiving the data, the cloud computing system requests additional vehicle data from the vehicle. The additional vehicle data is generated by the vehicle at a time subsequent to the initial detection of the vehicle-related event. The additional vehicle data is received from the vehicle, and an application resident in the cloud computing system analyzes the vehicle data and the additional vehicle data to determine that the vehicle-related event occurred. The application includes computer readable code embedded on a non-transitory, tangible computer readable medium for performing the analyzing. Also disclosed herein is a vehicle-incident detection system.

Abstract: A method for teaching an aftermarket accessory component how to actuate a vehicle function is disclosed herein. The aftermarket accessory component is configured to monitor communications across a vehicle bus. The method includes, but is not limited to, sampling message traffic transmitted across the vehicle bus while the vehicle function is not actuated. The method further includes setting filters in the aftermarket accessory component based on the sampled message traffic. The method further includes prompting a user to actuate the vehicle function in a first manner. The method further includes collecting filtered message traffic from the vehicle bus while the vehicle function is actuated in the first manner. The method further includes parsing the filtered message traffic to identify a command associated with actuation of the vehicle function. The method further includes testing the command to confirm that the command actuates the vehicle function.

Abstract: The described method and system provide for forgotten phone notification and vehicle theft notification. A method includes: activating a configurable device pairing program module associated with a short-range wireless unit of the telematics unit when a triggering condition is satisfied; determining, using the configurable device pairing program module and short-range wireless unit, whether the paired mobile device is within range of the short-range wireless unit; and providing, in response to a determination that the paired mobile device is not within range of the short-range wireless unit, a notification to the paired mobile device that the vehicle is being operated in the exception state that is based, at least in part, upon the paired mobile device not being detected during the determining step.

Abstract: A collision sensor, a collision sensing system, and a method of mounting a collision sensor to a vehicle are disclosed herein. An embodiment of the collision sensor includes, but is not limited to, a processor and a three-axis accelerometer that is communicatively coupled with the processor. The three-axis accelerometer is configured to detect an acceleration experienced by a vehicle and to generate a signal indicative of the acceleration. The processor is configured to obtain the signal from the three-axis accelerometer and to determine when the vehicle has experienced a collision based, at least in part, on the signal.

Abstract: An aftermarket device is disclosed herein. In an embodiment, the aftermarket device includes, but is not limited to, a housing that is configured to be mounted to an internal surface of a vehicle. The aftermarket device further includes, but is not limited to a processor that is mounted within the housing. The aftermarket device still further includes, but is not limited to, a mounting sensor that is associated with the housing and that is communicatively coupled with the processor. The mounting sensor is configured to detect a mounting status of the housing and to provide a signal to the processor. The signal contains information indicative of the mounting status of the housing. The processor is configured to determine that the housing is improperly mounted to the internal surface of the vehicle based on the mounting status.

Abstract: A system and method are provided for re-provisioning a telematics unit of a telematics-equipped vehicle for wireless services. The re-provisioning process includes: connecting a computing device to an on-board diagnostics interface of the telematics-equipped vehicle; accessing a subscriber identification card of the telematics unit via the on-board diagnostics interface; requesting subscription information from a subscriber credentials server via a network connection; receiving the subscription information; and reprogramming the subscriber identification card of the telematics unit for wireless services based on the received subscription information.

Abstract: A method for controlling a mobile communications device while located in a mobile vehicle involves pairing the mobile communications device with a telematics unit via short range wireless communication. The method further involves, receiving an incoming text message at the mobile device while the mobile device is paired with the telematics unit. Upon receiving the text message, a text messaging management strategy is implemented via the telematics unit and/or the mobile device, where the text messaging management strategy is executable via an application that is resident on the mobile device.

Abstract: A method and system for temporarily disabling vehicle wireless services to prevent a third-party such as a bailee from using one or more vehicle wireless services without authorization. The wireless services may accrue cellular data charges to the vehicle user's account. The method includes configuring a telematics unit to identify a valet event, determining the occurrence of the valet event at the telematics unit, and initiating a valet mode in the vehicle based on the determination. In the valet mode, the vehicle wireless services may be temporarily disabled.