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 sensory stimulation system for autonomous vehicle (AV) can determine a set of maneuvers of the AV. Based on each respective maneuver, the sensory stimulation system can determine a set of visual stimulation outputs to provide a passenger of the AV with visual indications of the respective maneuver. The sensory stimulation system can then display the set of visual stimulation outputs on a display unit within the interior of the AV prior to executing each respective maneuver.

In one aspect a vehicle may include a motor, a drive train and chassis, a battery, a seat assembly including a seat in which people can sit, at least one processor, a camera accessible to the at least one processor, and storage accessible to the at least one processor. The storage may include instructions executable by the at least one processor to receive data pertaining to at least one characteristic of a person and to, based on the data, adjust at least one mechanism within the vehicle.

A vehicle includes a body and a door moveable relative to the body between the open and closed position. The vehicle includes a seat fixed relative to the door. The seat includes a seat back and a seat bottom. The body has a longitudinal axis, and the seat bottom extends from the seat back toward the longitudinal axis along a cross-vehicle direction perpendicular to the longitudinal axis when the door is in the closed position.

A system for adjusting at least one adjustable component (30, 32, 34, 36, 38) of a vehicle (10) is disclosed. The system may include an exterior sensor (44) configured to generate a signal indicative of an identity a user before the user enters the vehicle (10), and a controller (60) in communication with the exterior sensor (44) and an actuator (40) configured to adjust the at least one adjustable component (30, 32, 34, 36, 38). The controller (60) may be configured to automatically cause the actuator (40) to adjust the at least one adjustable component (30, 32, 34, 36, 38) responsive to the signal.

A vehicle adjustment assembly including sensors for adjusting the position of an auxiliary component of the vehicle is disclosed. The sensor is connected to the vehicle and is configured to detect a user's characteristics. The sensor generates data regarding the user's characteristics, and a computer receives the data generated by the sensor related to the user's characteristics. The auxiliary system is adjusted via input signals from the computer in response to the data generated by the sensor.

An autonomous vehicle seat positioning system has a controller connected to a display, a control panel and a positioning mechanism of a vehicle seat assembly. The controller operates in a position saving mode and a position selecting mode. In the position saving mode, positioning inputs made by the first occupant are saved in memory as a first upright setting corresponding to the first occupant manually driving the vehicle. Positioning inputs made by the first occupant of the vehicle seat assembly are also saved in memory as a first relaxation setting corresponding to the first occupant viewing the display with the vehicle operating in a self-driving mode. In the position selecting mode, the controller operates the positioning mechanism to move the vehicle seat assembly to positions corresponding the first upright setting or the first relaxation setting.

Methods and systems for a complete vehicle ecosystem are provided. Specifically, systems that when taken alone, or together, provide an individual or group of individuals with an intuitive and comfortable vehicular environment. The present disclosure includes a system to create, modify, and maintain profiles associated with users. The user profiles are generated based on selectively collecting data associated with the users. Although each user profile may include settings, preferences, habits, and content associated with an individual user and/or vehicle, some user profiles may represent multiple users. These user profiles can change a configuration of a vehicle to match settings for a user, such as a driver and/or passenger. The configurations may also include the recognition of a unique set of gestures for a user. Further, the user profiles can be transferred from vehicle-to-vehicle and/or user-to-user.

The invention disclosure relates to a control system for a motor-displaceable cargo compartment device of a motor vehicle, wherein the cargo compartment device comprises a motor-displaceable closure element, wherein an operator occurrence sensor is provided, wherein a control arrangement monitors the operator occurrence sensor to determine whether a predetermined operator occurrence exists and, upon detection of such a predetermined operator occurrence, displaces the cargo compartment device with the aid of a motor, wherein the control arrangement displaces the closure element in the opening direction with the aid of a motor upon detection of a primary operator occurrence via the operator occurrence sensor. Further the cargo compartment device comprises at least one motor-displaceable cargo compartment component and the control arrangement displaces at least one such cargo compartment component with the aid of a motor upon detection, via the operator occurrence sensor, of a secondary operator occurrence following the primary operator occurrence.

Systems and methods for driver identification using vehicle approach vectors are disclosed. An example disclosed vehicle includes a plurality of beacons configured to connect to a first mobile device and a second mobile device. The example vehicle also includes a plurality of ultrasonic sensors. The example vehicle includes a driver identifier configured to predict trajectories for the first and second mobile devices based on information received from the plurality of beacons and the plurality of ultrasonic sensors, and determine which one of the mobile devices is associated with a driver based on the predicted trajectories.