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.

A seat control apparatus is provided. The seat control apparatus may include: one or more processors, and memory storing instructions that, when executed by the one or more processors, cause the seat control apparatus to detect a collision of a vehicle, output, based on the detection, a collision occurrence signal; determine a seat operation mode of the vehicle between an automatic mode and a manual mode, output, based on the determination, one of an automatic mode seat operation request command or a manual mode seat operation request command, determine, based on the collision occurrence signal, whether to transmit one of the automatic mode seat operation request command or the manual mode seat operation request command; and drive, based on the one of the automatic mode seat operation request command or the manual mode seat operation request command, one or more seat motors to control a seat of the vehicle.

A vehicle seat includes a seat bottom and a seat back coupled to the seat bottom to extend upwardly away from the seat bottom and move relative to the seat bottom. The vehicle seat is coupled to a vehicle floor for movement relative to the vehicle floor between a use arrangement and a storage arrangement.

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.

Methods and systems for tracking user behavior, the user behavior including one or more of: one or more user actions and one or more user interactions with a vehicle. A storage system stores the user behavior, where the tracked user behavior is associated with a driver and the storage system is capable of storing the tracked behavior for the driver from a plurality of vehicles.

A vehicle is described, and includes a telematics device, a GPS tracking device, and a multi-position driver's seat including a seat position actuator that is operatively connected to a seat controller and disposed to control a position setting thereof. A control system and method for the vehicle is described and includes receiving an alert of an impending traffic event, and determining a desired activation command for the seat position actuator based upon the impending traffic event. The seat controller controls the seat position actuator responsive to the desired activation command.

Vehicular control method to avoid collisions in which a smartphone is coupled to the vehicle while in a vehicular compartment. Data is generated from vehicle-resident sensors about operation of the vehicle and transferred from the vehicle to the smartphone while the smartphone is coupled to the vehicle. A communications network with another vehicle is established using the smartphone and the data transferred from the vehicle to the smartphone and data from sensors on the smartphone is transmitted via the smartphone and established communications network to other vehicle, the data including data about location and movement of the vehicle. Then, while the smartphone is coupled to the vehicle, a vehicular operational function is controlled based in part on data transmitted using the smartphone and established communications network to cause movement of the vehicle to change in order to avoid a collision with the other vehicle.

Various systems, mediums, and methods may be implemented to retrieve data from a user's mobile device. In one example, a system may determine a number of reviews received by the user's mobile device. Some of the reviews may include poor reviews, such as low ratings (e.g., one or two star ratings), negative written reviews, and/or other forms of data indicative of various establishments and/or services. In such instances, the system may generate notifications and transmit the notifications to merchant devices, such that the merchants may be alerted of the user having a history of providing poor reviews. As such, the system and/or the merchants may be notified accordingly to ensure the user will be satisfied with the services provided and to avoid a negative review from the user.

A method of controlling a seat system. A physiological condition of the seat occupant may be assessed based on at least two of the heart rate, breathing rate, and heart rate variability. A countermeasure may be executed to alter the physiological condition of the seat occupant and/or data associated with the heart rate, breathing rate, and/or heart rate variability may be communicated.

A sensory stimulation system within an interior of an autonomous vehicle (AV) can obtain maneuver data representing one or more maneuvers to be performed by the AV. For each respective maneuver of the one or more maneuvers, the system can determine one or more visual outputs to provide a passenger of the AV with a sensory indication of the respective maneuver, and then output the one or more visual outputs via the display system.