Abstract: Vehicles can be equipped to operate in both autonomous and occupant piloted mode. Refueling stations can be equipped to refuel autonomous vehicles without occupant assistance. Refueling stations can be equipped with wireless networks that communicate with vehicles to permit autonomous vehicles to self-schedule refueling at fueling stations serving a mixture of autonomous, semi-autonomous and occupant piloted vehicles.

Abstract: A vehicle includes an interface having an electromagnetic transmitter and operable to receive tactile user input for control of a system of the vehicle. The vehicle includes a controller configured to modulate output having ultraviolet or infrared spectrum wavelength of the electromagnetic transmitter at a receiver capture rate to encode data into the output describing the control interface. The modulated output is responsive to a request.

Abstract: A broadcast filtering system for a vehicle includes a controller programmed to, in response to receiving a commercial offering from a broadcasting business via a dedicated short-range network broadcast and identifying a match between a classification associated with the business and a user-defined preferred classification associated with the vehicle, display the offering, and, in response to identifying no match between the respective classifications, prevent the display.

Abstract: One or more processors associated with a vehicle can be configured to determine whether a condition exists that requires a request for assistance, such as a vehicle malfunction, a passenger emergency, and so forth. In response to a determination that the condition exists, the processor(s) determine availability of remote objects or devices with which the vehicle can communicate wirelessly. In response to a determination that no remote object or device is available, the processor(s) cause a visible light communication (VLC) transmitter to transmit the request for assistance.

Abstract: A system includes a computer programmed to, in response to receiving a parking transmission from a parked vehicle, transmit a parking authorization credential to the parked vehicle for rebroadcast from the parked vehicle, the parking authorization credential confirming that the parked vehicle is authorized for a parking location.

Abstract: Biometric data are collected about a user in a vehicle. A user is prompted to provide an input on a wearable device to identify an object based on the biometric data.

Abstract: A bicycle-sharing system includes bicycles having beacons mounted thereto. Sensors are distributed throughout an urban environment and detect the beacons. Stations report check-in and check-out of the bicycles. Using reported detections of the bicycles and the check-in and check-out locations, a trajectory of the bicycle is determined. Where multiple sensors detect the beacon at a time, triangulation may be performed to more accurately determine the bicycle location. Trajectories of bicycles may be used for planning purposes or to track stolen or mislaid bicycles.

Abstract: A system including a computer for a vehicle is programmed to identify the vehicle as a lead vehicle in a platoon of three or more vehicles, and to identify one of the vehicles in the platoon as a caboose vehicle. The computer is programmed to deactivate a rear light of the lead vehicle, and to instruct activation of a rear light of the caboose vehicle.

Abstract: Vehicles can be equipped to operate in both autonomous and occupant piloted mode. Refueling stations can be equipped to refuel autonomous vehicles without occupant assistance. Refueling stations can be equipped with a fueling control computer that communicates with vehicles via wireless networks to move vehicles between waiting zones, service zones and served zones. Refueling stations can include liquid fuel, compressed gas and electric charging.

Abstract: Embodiments provide a vehicle comprising a wireless transceiver for transmitting a request for radio presets to a plurality of vehicles within a predetermined proximity of the vehicle; a processor for generating a list of local radio stations based on radio presets information received by the wireless transceiver and a user preference for prioritizing the stations; and an audio system for playing audio received from a selected one of the local radio stations. Embodiments also include a method in a vehicle comprising sending, via a wireless transceiver, a request for radio presets to a plurality of vehicles within a predetermined proximity of the vehicle; generating, using a processor, a list of local radio stations based on radio presets information received by the wireless transceiver and a user preference for prioritizing the stations; and playing, via an audio system, audio received from a selected one of the local radio stations.

Abstract: An alarm system for a vehicle, such as a bicycle, includes a touch sensor electrically connected to a vehicle frame. The touch sensor outputs an alarm signal based on a proximity of a person to the vehicle frame. A communication module receives signals from a remote device. A controller is programmed to selectively enable and disable the touch sensor in response to signals received from the remote device.

Abstract: A system for a vehicle includes a controller programmed to, in response to receiving from a business a confirmation generated responsive to a forwarded verification request that an account associated with the vehicle is supported by a pre-negotiated fuel purchase program in which the business participates, display a location of the business and in response to a disaffirmation generated responsive to the request, prevent the displaying.

Abstract: A vehicle system includes a primary transmitter and a secondary transmitter. The primary transmitter is programmed to transmit messages in accordance with a first communication protocol. The secondary transmitter is programmed to receive the messages transmitted by the primary transmitter in accordance with a second communication protocol. The secondary transmitter rebroadcasts the messages in accordance with the first communication protocol.

Abstract: A broadcast filtering system for a vehicle includes a controller programmed to, in response to receiving a commercial offering from a broadcasting business via a dedicated short-range network broadcast and identifying a match between a classification associated with the business and a user-defined preferred classification associated with the vehicle, display the offering, and, in response to identifying no match between the respective classifications, prevent the display.

Abstract: A system includes a processor configured to detect user proximity to a rental vehicle. The processor is also configured to instruct a user to photograph an identified portion of a vehicle. The processor is further configured to receive an image captured using a mobile device, including the processor, responsive to the instruction. Also, the processor is configured to determine if a predefined threshold correspondence between the captured image and a predefined image is met and transmit confirmation to the vehicle, responsive to the predefined threshold correspondence.

Abstract: A system including a computer for a vehicle is programmed to identify the vehicle as a lead vehicle in a platoon of three or more vehicles, and to identify one of the vehicles in the platoon as a caboose vehicle. The computer is programmed to deactivate a rear light of the lead vehicle, and to instruct activation of a rear light of the caboose vehicle.

Abstract: Disclosed is a host vehicle including: motor(s), sensors, processor(s) configured to: (i) package sensed data into a first unit; (ii) determine whether a vehicle-to-infrastructure connection is (a) active or (b) inactive; (iii) if (a), append a TRUE flag to the unit and if (b) append a FALSE flag to the unit; (iv) transmit the first appended unit over a vehicle-to-vehicle connection; (v) determine whether a second appended unit, received over a vehicle-to-vehicle connection, includes (c) a TRUE flag or (d) a FALSE flag; (vi) if (d), transmit the second appended unit over the vehicle-to-infrastructure connection; (vii) if (c), not transmit the second appended unit over the vehicle-to-infrastructure connection.

Abstract: An identified destination roadway lane from a plurality of roadway lanes that is separated from a current roadway lane of a vehicle by at least one roadway lane is received. Upon determining that a blind spot of the vehicle extending across the destination roadway lane and a roadway lane between the destination lane and a current roadway lane is free of objects, a means for providing an alert is actuated.

Abstract: A system includes a processor configured to detect user proximity to a rental vehicle. The processor is also configured to instruct a user to photograph an identified portion of a vehicle. The processor is further configured to receive an image captured using a mobile device, including the processor, responsive to the instruction. Also, the processor is configured to determine if a predefined threshold correspondence between the captured image and a predefined image is met and transmit confirmation to the vehicle, responsive to the predefined threshold correspondence.

Abstract: Disclosed is a host vehicle including: motor(s), sensors, processor(s) configured to: (i) package sensed data into a first unit; (ii) determine whether a vehicle-to-infrastructure connection is (a) active or (b) inactive; (iii) if (a), append a TRUE flag to the unit and if (b) append a FALSE flag to the unit; (iv) transmit the first appended unit over a vehicle-to-vehicle connection; (v) determine whether a second appended unit, received over a vehicle-to-vehicle connection, includes (c) a TRUE flag or (d) a FALSE flag; (vi) if (d), transmit the second appended unit over the vehicle-to-infrastructure connection; (vii) if (c), not transmit the second appended unit over the vehicle-to-infrastructure connection.