Abstract: A vehicle includes at least one processor that receives an in-coming communication for a driver, routes the in-coming communication to a mail system in response to a driver workload exceeding a predefined value, and after a predetermined period of time following routing the in-coming communication to the mail system, generates a notification for the driver indicating that a communication was received in response to the driver workload being less than the predefined value at an expiration of the predetermined period of time.

Abstract: A vehicle system includes a memory device, a communication interface, and a processing device. The memory device stores a primary keyless entry code associated with a vehicle. The communication interface receives an update command to change the primary keyless entry code to an updated keyless entry code. The processing device stores the updated keyless entry code in the memory device. When an authorized person provides the updated keyless entry code to the vehicle via, e.g., a keypad, the authorized person may gain access to the vehicle.

Abstract: Vehicle operating systems are autonomously operated. A transient in an upcoming path of the vehicle is determined from a comparison of vehicle path data and vehicle status data to a threshold of mechanism first operating system. Operational parameters for one of first and second operating systems are selected according to the comparison. The selected operational parameters are applied to the operation of the one of the first and second operating systems.

Abstract: One of a condition affecting a vehicle and a planned action of the vehicle are identified. An instruction is provided to actuate movement of a steering wheel in the vehicle, wherein the movement is determined according to the one of the condition and the planned action.

Abstract: A vehicle model including main and secondary modules is provided. The vehicle module may also include vehicle components, a frame, a camera system, and a controller. The vehicle components are operably connected to the modules. The frame supports the modules and components and defines a 3D grid including identifiable reference points. The camera system is arranged with the frame to capture activity within the 3D grid. The controller is in communication with, and configured to direct operation of, the modules, components, and camera system based on the identifiable reference points and accessible vehicle CAD data. The vehicle components may comprise a subject platform located adjacent to, detached from, and integrated to function with the modules. The subject platform may be configured to vertically adjust between a plurality of positions for simulating ground outside a vehicle.

Abstract: A vehicle includes a steering wheel located in a passenger compartment. The steering wheel is configured to be moved from an operational position to a stowed position. In the event of a collision, a first airbag is configured to deploy when the steering wheel is in the operational position and a second airbag is configured to deploy when the steering wheel is in the stowed position.

Abstract: In one embodiment, a vehicle model is disclosed. The vehicle model includes a main vehicle module including a primary base and a number of components. The number of main vehicle module components is moveably mounted to the main vehicle module primary base. The vehicle model also includes a secondary vehicle module including a number of components. The main vehicle module and secondary vehicle modules are relatively positionable relative to one another to obtain a first and second vehicle configuration. The first and second vehicle configurations are different from each other.

Abstract: Data may be collected relating to autonomous operation of a vehicle. A first confidence assessment concerning whether the vehicle should operate autonomously may then be generated, and it may be determined whether the first confidence assessment meets or exceeds a predetermined threshold. An alert may be provided via a user interface in the vehicle relating to ending autonomous operation of the vehicle if the first confidence assessment meets or exceeds the predetermined threshold.

Abstract: Data is collected during operation of a vehicle. A determination is made that a confidence assessment of at least one of the data indicates at least one fault condition. A first autonomous operation affected by the fault condition is discontinued, where a second autonomous operation that is unaffected by the fault condition is continued.

Abstract: A vehicle includes at least one autonomous driving sensor configured to monitor at least one condition while operating in an autonomous mode. The vehicle further includes a processing device configured to identify at least one occupant, select a profile associated with the occupant, and autonomously operate at least one subsystem according to the selected profile and the at least condition monitored by the at least one autonomous driving sensor.

Abstract: A vehicle operator is identified. Based at least in part on the operator's identity, one or more parameters are determined specifying a mode for autonomously operating the vehicle. The vehicle is autonomously operated at least in part according to the one or more parameters.

Abstract: A vehicle is operated at least partially autonomously. A predicted path of the vehicle is monitored to identify an object with which the vehicle is likely to collide. A graphical user interface (GUI) is provided that includes the predicted path, a proposed path for the vehicle to avoid a collision with an object, and the vehicle. A selection is made to follow one of the predicted path and the proposed path. The GUI is updated to include the selected one of the predicted path and the proposed path, along with a location of the vehicle on the selected one of the predicted path and the proposed path.

Abstract: A wearable computing device in a vehicle is identified by a vehicle in a computer. Collected data is received relating to autonomous operation of the vehicle. A message is sent to the wearable computing device based at least in part on the collected data.

Abstract: A vehicle includes a steering wheel located in a passenger compartment. The steering wheel is configured to be moved from an operational position to a stowed position. In the event of a collision, a first airbag is configured to deploy when the steering wheel is in the operational position and a second airbag is configured to deploy when the steering wheel is in the stowed position.

Abstract: Keypad indicia are integral with a window of a vehicle. The keypad indicia are formed using a ultra-violet (UV) fluorescent dye that is nearly invisible to a human eye until exposed to UV light. A UV light emitting device of the vehicle is configured for outputting UV light. The light emitting device is mounted for enabling the keypad indicia to be exposed to the outputted UV light thereby causing the keypad indicia to become readily visible by the human eye. An imaging device of the vehicle captures user interaction with the keypad indicia while the keypad indicia is exposed to the outputted UV light. The keypad interaction processor determines if a sequence of body part movements with respect to the keypad indicia that is captured by the imaging device during exposure of the keypad indicia to the outputted light corresponds to an access code of the vehicle.

Abstract: A vehicle computer system comprising a wireless transceiver configured to send a nomadic device human machine interface to a nomadic device in a web browser format. The vehicle computer system further comprises a vehicle server utilizing a contextual data aggregator that utilizes vehicle data and off-board data to generate a dynamic human machine interface, the server further configured to generate an in-vehicle human machine interface for output on a vehicle display and generate the nomadic device human machine interface for the nomadic device to display.

Abstract: Driver braking performance feedback may be conveyed to a vehicle operator as a braking efficiency score using a vehicle display system. The display system may include a vehicle display for displaying a braking efficiency indicator or gauge corresponding to the braking efficiency score. The braking efficiency score may be based on a comparison of the total regenerative braking energy recaptured during at least one braking event to a either a maximum amount of braking energy that may be recaptured during the at least one braking event or an actual total braking energy expended during the at least one braking event. The braking efficiency score may be displayed upon the completion of a braking event or upon a completion of a trip including a plurality of braking events. The display may also convey a distance corresponding to a portion of a trip distance achieved through regenerative braking.

Abstract: A vehicle computer system comprising a wireless transceiver configured to send a nomadic device human machine interface to a nomadic device in a web browser format. The vehicle computer system further comprises a vehicle server utilizing a contextual data aggregator that utilizes vehicle data and off-board data to generate a dynamic human machine interface, the server further configured to generate an in-vehicle human machine interface for output on a vehicle display and generate the nomadic device human machine interface for the nomadic device to display.

Abstract: A vehicle interface system may include an interface configured to present icons representing selectable vehicle features; and a controller programmed to generate a score for each of the features based on a contextual variable including one or all of a vehicle location, vehicle speed, past feature usage information, and a predicted end location for the vehicle, and display certain of the icons and hide other of the icons based on the generated scores.

Abstract: A vehicle system having a controller configured to receive a sensor input. The controller may generate a feature score based at least in part on the sensor input and a location data within a database. The controller may associate the feature score to a selectable option. The controller may instruct a user interface device to display the selectable option in response to the feature score.