Vehicle seat adjustment systems including cameras are disclosed. The vehicle seat adjustment system includes a camera configured to capture a seat arrangement of a front seat of a vehicle and one or more seats behind the front seat, a screen, communicatively coupled to the camera, configured to display the seat arrangement captured by the camera, an input device configured to receive an input from a user for adjusting positions of the one or more seats, an actuator communicatively coupled to the input device and configured to adjust positions of the one or more seats, and a controller communicatively coupled to the camera, the screen, the input device and the actuator. The controller receives the input from the input device and instruct the actuator to adjust the positions of the one or more seats based on the input from the user.

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.

A vehicle seating assembly includes a lower leg support, a seat, and a seatback. A seat rotational member rotatably couples the lower leg support to the seat. A seatback rotational member rotatably couples the seat to the seatback.

A system includes a vehicle, the vehicle comprising a control system and a wireless transceiver operatively connected to the control system. The control system is configured to wirelessly communicate with a wearable device worn by a user using the wireless transceiver and the control system is configured to receive input from one or more sensors of the wearable device.

An occupant customized seat control apparatus and method are provided. The method includes recognizing, by a camera, an occupant that approaches a vehicle, controlling a display to move based on a height of the recognized occupant, determining whether the recognized occupant is an infant, and when the recognized occupant is determined to be an infant, determining whether a booster seat needs to be controlled based on the height of the recognized occupant, and when at least one of the booster seat, a footrest, or the combination thereof needs to be controlled, converting a value of the recognized height into a booster seat actuator movement amount value, and controlling the booster seat to move based on the converted actuator movement amount value.

Various systems and methods for providing an occupant profiling system are described herein. A system for profiling a vehicle occupant includes a vehicle control system, comprising: a sensor fusion circuit coupled to a plurality of sensors installed a vehicle seat, the sensor fusion circuit to: determine that a human occupant is seated in the vehicle seat; sample a backrest sensor arrangement and a base cushion sensor arrangement of the vehicle seat to obtain backrest sensor data and base cushion sensor data, when the human occupant is determined to be seated in the vehicle seat; sample, when the human occupant is determined to be seated in the vehicle seat, a height sensor to obtain a height sensor value; and statistically determine from the backrest sensor data, the base cushion sensor data, and the high sensor data, whether the human occupant matches a reference profile.

A method for assigning a user profile of a user to a seat in a motor vehicle by at least one mobile unit, wherein the mobile unit has at least one identifier and a sensor arrangement for detecting at least one translational and/or rotational degree of freedom, wherein the mobile unit transmits the identifier to the motor vehicle, wherein the mobile unit or the motor vehicle evaluates the data from the sensor arrangement as to whether a boarding movement into a motor vehicle is occurring, wherein the motor vehicle or the mobile unit by the data of a door opening sensor arrangement, assigns the boarding movement to a seat assigned to a vehicle door, wherein the user profile is then assigned to the seat. Also disclosed is a mobile unit and a motor vehicle.

Equipment and processes generate a seating solution by obtaining occupant data, calculating body dimensions from the occupant data, and calculating a best-fit body arrangement for an occupant. Occupant data may be obtained in various ways using available computational devices and software or by manually measuring the relevant dimensions on the occupant. A user interface for inputting occupant metrics and/or occupant measurements may be provided in a mobile terminal included in the vehicle or separate from the vehicle, thus giving users increased flexibility while maximizing simplicity and usability for the user or other personnel obtaining the data. Once an occupant's best-fit body arrangement is determined, it may be altered by changing the predetermined criteria to achieve optimum comfort, safety, and therapeutic benefit as well as used for providing improved comfort on a continuous basis and/or in response to detected or predicted vehicle, road, or atmospheric conditions.

A system for testing a pressure sensor of a seat includes a loading device and a processor. The loading device removably applies weight to the seat. The processor receives a measurement of a pre-installation pressure offset of a bladder of the pressure sensor measured before installation of the pressure sensing assembly into the seat. The processor is programmed to receive a weighted measurement from the pressure sensor in the seat when the loading device applies weight to the seat and an empty seat measurement from the pressure sensor in the seat when the loading device does not apply weight to the seat. The processor determines a threshold value by subtracting the empty seat measurement from the weighted measurement. The processor determines a seat pressure offset value by subtracting the pre-installation pressure offset value from the threshold value. The processor compares the seat pressure offset value to a selected range.

A seat assembly is provided with a seat bottom, a seat back, and a plurality of sensors operably connected to at least one of the seat bottom and the seat back to detect a seating condition of a seated occupant. A controller is in electrical communication with the plurality of sensors and the at least one actuator. The controller is programmed to receive input from the plurality of sensors indicative of a seating condition of the seated occupant. The seating condition of the seated occupant is compared to stored seating conditions of prior seat occupants to determine that the seated occupant is a prior occupant.