A vehicle travel controller carries out automatic travel control of controlling a vehicle to travel automatically based upon travel state information of the vehicle and information on an exterior of the vehicle. An automatic/manual traveling changeover switch is capable of switching between an automatic driving mode in which the automatic travel control is carried out by the vehicle travel controller and a manual driving mode in which the driver drives the vehicle manually. A driving posture controller controls a reclining motor so that the reclining angle of the driver's seat in the automatic driving mode is larger than the reclining angle of the driver's seat in the manual driving mode.

A method for cancelling seat vibration includes receiving, from an accelerometer, a plurality of accelerometer measurements and applying a first filter to the plurality of accelerometer measurements to remove accelerometer measurements of the plurality of accelerometer measurements having a frequency above a first threshold frequency. The method also includes applying a second filter to an output of the first filter to remove accelerometer measurements of the output of the first filter having a frequency above a second threshold frequency and applying a third filter to an output of the second filter to generate an accelerometer measurement output having a center frequency corresponding to a resonant frequency of the vibration of the at least one component of the seat. The method also includes determining an absolute magnitude value of the accelerometer measurement output and selectively controlling a motor based on the absolute magnitude value of the accelerometer measurement output.

A modular smart motor assembly comprising a controller and electric motor. The modular smart motor assembly is part of a smart motor system within a vehicle, and operable to adjust configurable elements of the interior of the vehicle. The controller may be detachably coupled to the electric motor, and may be utilized to retrofit existing electric motor systems.

A vehicle blind-spot reduction device includes side-view mirrors on sides of a vehicle, an actuator configured to move an optical display of each of the side-view mirrors, a detector configured to detect a display position of the optical display, a surrounding environment information acquirer configured to acquire environment information on surrounding of the vehicle, a moving object detector configured to detect a moving object running beside the vehicle on the basis of the surrounding environment information, a blind spot setter configured to set a blind spot of each of the side-view mirrors on the basis of the display position of the optical display, and a display surface adjuster. Based on determining that the moving object has entered the blind spot, the display surface adjuster causes the actuator to operate to adjust the display position of the optical display such that a driver who drives the vehicle can see the moving object.

A method for operating a vehicle including at least one device, in which the one device is altered from a first state to a second state by an electronic computing device of the vehicle. The electronic computing device ascertains a present time and automatically alters the device from the first state to the second state on the basis of the ascertained time. Provision is made for the second state to be ascertained automatically by the electronic computing device from the first state.

A vehicle seat control apparatus is configured to be provided in a vehicle switchable between a manual driving state in which a driver performs a driving operation of the vehicle and an automatic driving state in which the driving operation is performed automatically. The apparatus includes a seat adjuster, a controller, and a storage. The seat adjuster adjusts a position of a seat of the vehicle. The controller drives the seat adjuster and makes a transition between the driving two states. The storage stores seat position information indicating the seat position in the the manual driving state. The controller drives the seat adjuster on a basis of the seat position information read out from the storage, and moves, by the seat adjuster, the seat rearward on a basis of the seat position in the manual driving state as a reference position, upon making a transition from the manual driving state to the automatic driving state.

An adjustable vehicle seat includes a seat base having a seat surface and a backrest having a backrest surface. In the seat base and/or in the backrest, sensors are provided that detect forces, pressures and/or movements effected by a person sitting on the vehicle seat and consequently issue a signal. A control device is provided that detects the signals issued by the sensors and actuates actuators provided in the vehicle seat to adjust the seat base and/or backrest, or components thereof, in order to adjust the vehicle seat.

The invention relates to a seat, in particular a vehicle seat, with an operating device for setting seat parameters, wherein the operating device comprises at least one multifunction operating element having at least one selection element, by means of which at least two operating levels can be selected, wherein the multifunction operating element is movable in at least five switching directions, wherein each switching direction can be assigned to a specific function which is associated with the selected operating level and changes a seat parameter.

A key fob includes selectors for performing conventional remote operations (e.g., locking/unlocking doors) as well as a “pet mode” selector. When the pet mode selector is pressed by a user, a coded wireless signal is sent to a vehicle computer. The vehicle computer is operatively connected to multiple vehicle systems that each controls various features of the vehicle. Responsive to receipt of the coded wireless signal, the vehicle computer instructs a selected group of the systems to operate in a specified manner so as to create a comfortable environment for a pet within the vehicle. For example, in pet mode, the vehicle computer may cause one or more windows to lower, the sunroof to open the trunk lift gate to pivot open, and the seat backs of one or more rows of seats to tilt or fold down.

A car seat system for automatically displacing the movable components of the car seat. The car seat including sensors and a computing module to detect the measurements of a child placed in the car seat. The car seat system determines the current position of the movable components and displaces the movable components automatically based on the child's measurements or a desired amount. The car seat system automatically learns child's behaviors when the child is placed in the car seat. The car seat system learns schedules utilized by the child, routes taken by the driver of the car, and other data over a period of time. The behavioral, scheduling, routing, and other data obtained is stored by the car seat system and utilized to enhance the safety and comfortability of the child during a car ride. The car seat system also determines thickness of clothing worn by the child while placed in the car seat and adjusts the shoulder belts to accommodate for the clothing while providing a snug fit of the shoulder belts that fall within safety recommendations. The car seat also auto reclines to a desired angle and also rotates about itself to face the door. The car seat system includes an auto-incident detection mode. In this mode, the system detects an incident, such as an accident, hard braking, or another hazard, and automatically displaces the features in the car seat to make the car seat secure during the crash minimizing the effect of the incident on the child. The car seat also includes pretensioners and motors to release, pull back, and lock the car seat belts.