Various examples of tilting a human support surface in a vehicle are disclosed. A frame is attached to the surface of the vehicle. The vehicle also includes rotation system mounted between the frame and a vehicle surface. The rotation system can be controlled to tilt a human support surface of the frame towards a direction of acceleration associated with a driving maneuver as the driving maneuver is executed.

System and method for obtaining and recording information about cargo includes a frame defining a cargo-receivable compartment, a position determining system at least partly on the frame and that allows for determination of position of the frame, an identification system on the frame that obtains information about cargo when present in the compartment, a memory component that receives and records information about position and movement of the frame, and the obtained information about cargo when present in the compartment in association with a unique identification of the frame, and a communications system on the frame to enable communication of information to and from the memory component.

A system includes a vehicle, the vehicle comprising a vehicle network. The system further includes a wireless earpiece worn by a user in operative communication with the vehicle network. The vehicle is configured to determine a role of the user and user settings for the vehicle from data received from the wireless earpiece and implement the user settings for the vehicle. A method for adjusting user settings associated with a vehicle based on data from a wireless earpiece includes acquiring user data from a wireless earpiece worn by a user at a vehicle, based on the user data, determining by the vehicle one or more user settings and a role of the user, and automatically adjusting by the vehicle of one or more vehicle features based on the one or more user settings in accordance with the role of the user.

A method of operation of a navigation system includes: determining an occupancy status with a capturing sensor based on detecting a passenger presence in real time; determining a lane availability of a lane type based on a current location; generating an access notification based on the occupancy status, the lane availability for traversing on the lane type; and updating the access notification with a control unit dynamically and in real time based on a change in the occupancy status, the lane availability, or a combination thereof for presenting on a device.

A vehicle seat includes a seat bottom and a seat back coupled to the seat bottom to extend away from the seat bottom. The seat back includes a backrest an a headrest coupled to the backrest to locate the backrest between the headrest and the seat bottom.

A system includes a vehicle having a vehicle network and a set of earpieces in operative communication with the vehicle network. The vehicle is configured to assign a plurality of access rights to the user of the set of earpieces based on both the identity of the user and the role of the user. A method for identifying a role of one or more users within a vehicle includes identifying one or more users within the vehicle, identifying the roles of one or more of the users within the vehicle using a set of wireless earpieces, and providing access rights to the one or more users within the vehicle in response to identification of one or more of the users within the vehicle.

Systems, devices, and techniques are provided for occupancy assessment of a vehicle. For one or more occupants of the vehicle, the occupancy assessment establishes position and/or identity for some or all of the occupant(s).

A vehicle seat control system (1) includes a first backrest portion (302) rotatably connected to a seating portion (301) by a first connection unit (308), a second backrest portion (302) rotatably connected to the first backrest portion by a second connection unit (309), a folding adjustment unit (304) that adjusts an angle of the second connection unit, a seat surface adjustment unit (304) that adjusts a height of the seating portion, a first angle detection unit (308a) that detects a first angle that is formed between the first backrest portion and a floor surface, a second angle detection unit (309a) that detects a second angle that is formed between the second backrest portion and the first backrest portion, and a control unit (160) that controls the folding adjustment unit on the basis of the first angle at the time of automatic driving of the vehicle to adjust the second angle, and controls the seat surface adjustment unit to maintain a height of a reference position in the second backrest portion to be equal to or greater than a reference height in a case that the height of the reference position in the second backrest portion is smaller than the reference height.

A system and method automatically adjusts a driver's steering experience based upon driving conditions, including turns and terrain. In accordance with one embodiment, the steering wheel essentially bends into the turn and advances towards the driver, thereby providing a more natural and enjoyable driving experience. The system comprises one or more sensors disposed within the vehicle to measure g-forces. A processor in the vehicle, receiving the signals from the sensors, sends control signals to the steering wheel in response to the signals received. An electromechanical system physically moves the steering wheel relative to a driver of the vehicle in response to the control signals received from the processor. Other embodiments cause one or more seats in the vehicle to moves in response to turns, acceleration and/or deceleration (braking).

An occupant support adapted for use in a vehicle includes a seat bottom, a seat back, and a sensory system. The seat bottom is coupled to a floor of the vehicle. The seat back extends upwardly away from the seat bottom. The sensor system is configured to monitor for fatigue of an occupant of the occupant support.