A vehicle seating assembly is provided. The seat assembly includes a front seat assembly having a front seat bottom adapted to be mounted to the vehicle body and a front seat back adapted to be mounted to the vehicle body adjacent to the front seat bottom. A sensor cooperates with at least one of the front seat bottom and the front seat back. An actuator is disposed on at least one of the seat bottom and seat back. The seat assembly includes a rear seat assembly behind the front seat assembly. A vehicle seat controller receives an input indicative of a rear occupant seated information and convey a signal to an actuator to move a front seat assembly to an accommodation position in response to the input.

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 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.

A seat assembly is provided with a seat cushion, and a seat back. Sensors are operably connected to the seat cushion and the seat back to detect a seating position of an occupant. An actuator is operably connected to the seat cushion and the seat back for adjustment of a plurality of settings of the seat assembly. An interactive user interface permits manual adjustment of the actuator. A controller is in electrical communication with the plurality of sensors, the at least one actuator, and the user interface. The controller is configured to receive seating position data input indicative of a manually selected seating position. Detection data is received from the plurality of sensors, and compared to the manually selected seating position to determine if the occupant is seated evenly. The at least one actuator adjusts an occupant seating position to the manually selected seating position.

A vehicle is operable in a manual driving mode and in an at least partially automatic driving mode. To allow a rapid change from the automatic to the manual driving mode, the respective position of a driver seat and/or at least one driving-relevant cockpit element is adjusted for functional use by a driver of the vehicle such that the at least one driving-relevant cockpit element can be functionally used by the driver whenever the vehicle is, or is to be, operated in the automatic driving mode.

A seat assembly is provided having a seat bottom and a seat back mounted adjacent the seat bottom. A cushion is disposed on at least one of the seat bottom and seat back and defines a seating surface. The seating surface has a plurality of regions. A controller is in communication with the cushion and is programmed to independently vary a stiffness of each of the regions along the seating surface.

Methods, systems, and a computer readable medium are provided for a vehicle containing multiple blade processors for performing vehicle and/or infotainment tasks, functions, and operations. The blade processors can be included in a crate having a first communication zone defining a trusted network within the vehicle to connect with trusted computational devices and/or modules provided or certified by the vehicle manufacturer but not untrusted computational devices and/or modules provided by vehicle occupants, a second communication zone defining an untrusted network to connect with the untrusted computational devices and/or modules, and a third communication zone providing power and data transmission to the blade processors. A master blade processor can assign a component and/or module requiring a blade processor for execution to a selected blade processor.

A seat assembly is provided with a seat cushion and a seat back. A controller is in electrical communication with an actuator. The controller is programmed to receive a data input indicative of occupant anthropometry data. The data input is compared with predetermined data ranges. A setting of the actuator is adjusted to a predetermined setting based on the predetermined data range. A data input indicative of a selected driving mode is received by the controller. The setting of the actuator is adjusted to another predetermined setting based on the selected driving mode. The actuator includes an inflation device, side bolster air bladders, a seat back recline actuator, a tilt actuator, and a central air bladder. The driving modes include a touring mode, a sport mode and a performance mode.

Embodiments for reducing unwanted motion experienced by an occupant of a vehicle by a processor. In response to an anticipated movement of the vehicle, a motion of a seating surface of the vehicle is caused to at least partially compensate for the anticipated movement of the vehicle.

A method for customizing a vehicular massage function includes providing massage element indicia, creating massage subroutines using the massage element indicia, selecting a vehicle that includes a seat having a massage element configuration, placing the massage subroutines in communication with the vehicle, adapting the massage subroutines to be compatible with the massage element configuration and activating the seat to perform at least one massage subroutine.