The disclosure provides for a system. The system may include a rotational control system configured to rotate a seat of a vehicle, and one or more computing devices. The one or more computing devices may have one or more processors that are configured to determine that an impact is imminent at a location on the vehicle along a collision axis. A most favorable orientation may be determined by the one or more processors based on the determined location and collision axis. Using the rotational control system, the one or more processors may rotate the seat of the vehicle to the most favorable orientation in order to reduce risks of serious injury to a passenger in the seat caused by the imminent impact. A translational control system may be used by the one or more processors to translate the seat of the vehicle to a position relative to the determined location.

A control device controls a vehicle including a seat suspension which is provided between a chassis and a seat of the vehicle and restricts vibration and of which each of a spring constant and a damping coefficient is changeable and controllable. The control device detects, as vehicle information, a vehicle speed, an acceleration, a state of acceleration operation by a driver, a state of deceleration operation by the driver, and a state of steering by the driver. The control device determines, based on the vehicle information, whether the driver has driving preference of emphasizing the steering stability performance of the vehicle or driving preference of emphasizing the ride comfort performance of the vehicle, and, according to the determined driving preference, changes an acceleration of the seat by controlling the seat suspension.

A system reduces motion sickness symptoms in operation of a vehicle. The system has a control unit which is coupled to a sensor system and/or to a navigation system, to a vehicle seat system, to a vehicle stabilization device and to a display unit for receiving and/or emitting signals. The sensor system and the navigation system are set up to receive environmental data and/or vehicle component data relating to the vehicle, from which movements of the vehicle result, and to transfer the data to the control unit. The control unit is set up to generate vehicle stabilization signals, seat adjustment signals and display signals on the basis of the received environmental data and/or vehicle component data.

A seat control apparatus controls a seat of a vehicle in which an occupant of the vehicle sits. The seat control apparatus includes an occupant weight recognition unit; an occupant sitting state recognition unit configured to recognize an occupant sitting state including at least either of a grip force of the occupant and a load applied to the occupant; a lateral acceleration estimation unit configured to estimate a subsequent lateral acceleration of the vehicle; and a seat controller configured to control the seat. The seat has an occupant support adjustment portion including at least one of a first adjustment portion, a second adjustment portion, and a third adjustment portion. The seat controller calculates an adjustment amount of the occupant support adjustment portion and controls the occupant support adjustment portion in response to the calculated adjustment amount.

A restraint system for a vehicle is disclosed. The restraint system includes a seat shaped to accommodate an occupant, wherein the seat includes a seat back and an energy absorption member that expands from a stowed position and into a deployed position. The energy absorption member fills a volume of space behind the seat back when in the deployed position to absorb energy that would otherwise be imparted towards an occupant of the seat during an impact involving the vehicle. The restraint system also includes an impact sensing device generating an impact signal in response to detecting the impact involving the vehicle is imminent. The impact signal indicates an orientation and magnitude of the impact involving the vehicle. The restraint system includes a control module in electronic communication with the energy absorption member and the impact sensing device.

A system reduces motion sickness symptoms in operation of a vehicle. The system has a control unit which is coupled to a sensor system and/or to a navigation system, to a vehicle seat system, to a vehicle stabilization device and to a display unit for receiving and/or emitting signals. The sensor system and the navigation system are set up to receive environmental data and/or vehicle component data relating to the vehicle, from which movements of the vehicle result, and to transfer the data to the control unit. The control unit is set up to generate vehicle stabilization signals, seat adjustment signals and display signals on the basis of the received environmental data and/or vehicle component data.

An automatic displacement device for use in a carrier includes at least one weight mount, at least one actuator, and at least one stability regulator. The weight mount can hold at least one heavy object accommodated in the carrier' body. The actuator is coupled to the weight mount. The stability regulator is electrically communicated to the actuator and includes a sensor and a controller. The sensor can measure a state associated with an angle of the carrier's body and output a signal representative of the state. The controller calculates a tilt of the carrier according to the signal outputted from the sensor and is capable of commanding the actuator to move the weight mount in view of the tilt to perform a compensation on the carrier.

A restraint system for a vehicle is disclosed. The restraint system includes a seat shaped to accommodate an occupant, wherein the seat includes a seat back and an energy absorption member that expands from a stowed position and into a deployed position. The energy absorption member fills a volume of space behind the seat back when in the deployed position to absorb energy that would otherwise be imparted towards an occupant of the seat during an impact involving the vehicle. The restraint system also includes an impact sensing device generating an impact signal in response to detecting the impact involving the vehicle is imminent. The impact signal indicates an orientation and magnitude of the impact involving the vehicle. The restraint system includes a control module in electronic communication with the energy absorption member and the impact sensing device.

The disclosure provides for a system. The system may include a rotational control system configured to rotate a seat of a vehicle, and one or more computing devices. The one or more computing devices may have one or more processors that are configured to determine that an impact is imminent at a location on the vehicle along a collision axis. A most favorable orientation may be determined by the one or more processors based on the determined location and collision axis. Using the rotational control system, the one or more processors may rotate the seat of the vehicle to the most favorable orientation in order to reduce risks of serious injury to a passenger in the seat caused by the imminent impact. A translational control system may be used by the one or more processors to translate the seat of the vehicle to a position relative to the determined location.

A passive safety system includes a seat support structure, a seat that is connected to the seat support structure, a motion control device operable to control motion of the seat relative to the seat support structure, a sensor that provides an output signal, and a controller. The output signal is indicative of an imminent collision. The controller causes the motion control device to move the seat relative to the seat support structure in response to the output signal.