A seat automatic arrangement method and apparatus of an autonomous driving vehicle is provided. The seat automatic arrangement method and apparatus have an advantage that it is possible to automatically arrange seats in the vehicle into the seat-facing mode through remote control, and it is possible to prevent interference when moving the seats by arranging the seats in accordance with priority when arranging the seats into the seat-facing mode, thereby being able to more smoothly arrange the seats into the seat-facing mode in an autonomous driving vehicle.

A motor vehicle having a passenger compartment with a forward region, a central region, and a rearward region, a floor, a seating rail system positioned on the floor and extending along a longitudinal direction of the vehicle, a plurality of seating assemblies arranged in the passenger compartment in a first row, a second row, and a third row. Each seating assembly has a seat base coupled to the seating rail system, a seat movably coupled to the seat base, a seat back movably coupled to the seat base, and seat actuators configured to activate the seating assemblies. The vehicle has a center console on a center console rail system extending longitudinally, a center console actuator, and a controller that receives an input commanding a selected passenger compartment arrangement and controls the actuators to position the seat assemblies and center console in the commanded passenger compartment arrangement.

A seat automatic arrangement method and apparatus of an autonomous driving vehicle is provided. The seat automatic arrangement method and apparatus have an advantage that it is possible to automatically arrange seats in the vehicle into the seat-facing mode through remote control, and it is possible to prevent interference when moving the seats by arranging the seats in accordance with priority when arranging the seats into the seat-facing mode, thereby being able to more smoothly arrange the seats into the seat-facing mode in an autonomous driving vehicle.

A vehicle seat control system includes a front seat, a rear seat associated with the front seat back and forth, a footrest mounted on a rear of a seatback of the front seat, a leg-rest mounted on a seat cushion of the rear seat associated with the front seat back and forth, an individual seat switch unit mounted on the front seat and the rear seat, respectively, and an integrated controller configured to determine current state information of the front seat and the rear seat through sensor units mounted on each of the front seat and the rear seat and to perform interference avoidance control in consideration of current state information of a seat associated with a specific seat when receiving a request for an operation of the footrest or the leg-rest from a switch unit of the specific seat.

A system of controlling various actuators associated with human support surfaces is disclosed. Such a system is made up of a support surface, a controller, and an actuator. The system may optionally include batteries, a means of charging the batteries, and a graphical user interface as well as a communication link between the graphical user interface and the support surfaces. The actuators are capable of altering contour and/or firmness, of a support surface, they may be vibrational or heating/cooling in nature, and they may also alter the overall relative position of a support surface to another support surface, and/or to the ground plane.

The present disclosure relates to a display device and a method of controlling the display device. The display device includes a display component, a touch component, a response component and a control component. The display component is configured to display a horn page; the touch component is configured to generate a horn touch signal according to a first touching operation occurring on the horn page, and output the horn touch signal to the controller and the response component; the controller is configured to trigger a horn to honk according to the horn touch signal; and the response component is configured to generate a first tactile response according to the horn touch signal while the horn is honking.

A method for the automatic adjustment of a cockpit inside a road vehicle comprising the steps of determining anthropometric data of a driver; processing an ergonomic position of a model of the driver sitting on board the road vehicle; processing an optimal configuration of the cockpit; operating a plurality of actuator systems so as to cause the cockpit to reach the optimal configuration; wherein the ergonomic position of the model is processed in association with a minimum ground visibility; a minimum visibility of a control panel; and at least one first comfort angle of a body joint of the driver.

A system for controlling the position of a vehicle seat is disclosed. The system includes in network communication, an input device, a detection system, at least one controller, and at least one controllable device. The detection system measures a current value of at least one of the recline, fore-aft, or swivel position of the seat. The input device communicates to the controllers a desired value for at least one of these seat positions. The controller compares the measured value to a limiting value and the desired value and calculates a movement factor value. The movement factor value determines the communication between the controller and the controllable device. If the movement factor value falls into a range where the seat can be moved to the desired value, the controller signals the at least one controllable device to control the adjustment of at least one of the recline position, the fore-aft position, or the swivel position to the desired value. However, if the movement factor value falls outside a range where the seat can be moved to the desired value, the controller signals the at least one controllable device to limit the adjustment of the at least one of the recline position, the fore-aft position, or the swivel of the position.

A motor vehicle includes a passenger compartment, a steering wheel configured to be moveable between a use position and a stowed position, a floor, a seating rail system positioned on the floor and extending along a longitudinal direction of the motor vehicle, and a plurality of seating assemblies arranged in the passenger compartment in a first row, a second row, and a third row and configured to be actuated to a plurality of positions. Also included is a center console on a center console rail system extending longitudinally on the floor. A controller is configured to receive an input commanding a selected passenger compartment arrangement. The controller controls the actuators to position the seat assemblies, the center console and the steering wheel in the commanded passenger compartment arrangement.

An aircraft seat pod with a reclining seat includes a controller interface that extends around a surface of the pod, include a surface obscured by the seat when in an upright position. The controller tracks the position and orientation of the seat and displays seat controls on the interface at a convenient location. More than one interface may be disposed at different locations to conveniently accommodate passengers of different size or in different orientations. Vision sensors may track the position and orientation of a passenger and preemptively display controls at a convenient location.