There is provided a moving base which includes a front base with front wheels and a rear base with rear wheels, the front and rear base extendable in a front-rear direction of a vehicle; a seat movable between a seating position and a folded position; a motor which drives the front and/or rear wheel; a sensor which detects the seating position and the folded position; a display part for displaying information related to the seating position or the folded position detected by the sensor to a user; and a control unit which controls the motor in accordance with operation of an operating part, and which can execute control such that a driving operation of the motor by the operating part is disabled when the sensor does not detect the seating or folded position.

A motor vehicle having a receiving compartment, which is mounted on a vehicle console, pivotable around a vertical axis, in the area of a side wall of the vehicle console delimiting an occupant footwell of the motor vehicle. It is provided that, with regard to a line of vision, oriented in the vehicle longitudinal direction of a vehicle occupant located on a seat of the motor vehicle assigned to the relevant occupant footwell, the vertical axis is arranged on an end or end section of the receiving compartment situated counter to the aforementioned line of vision, and the receiving compartment is mounted on the vehicle console in such a way, pivotable around the aforementioned vertical axis, and is positioned in the open state in such a way, that the open receiving compartment is oriented obliquely with respect to a displacement direction of the aforementioned seat.

An occupant protection device for a vehicle includes a collision predictor, a main airbag, a seat, a sub-airbag, and a deployment controller. The collision predictor is configured to predict a collision of the vehicle. The main airbag is configured to deploy toward an occupant from a front of the vehicle when a collision of the vehicle is predicted by the collision predictor. The seat allows the occupant to be seated, and is movable in a front-back direction of the vehicle. The sub-airbag is accommodated in an upper part of the seat, and configured to deploy downward from above the occupant. The deployment controller is configured to, when a collision of the vehicle is predicted by the collision predictor, cause the sub-airbag to deploy from the upper part of the seat and subsequently cause the main airbag to deploy.

An occupant protection device for a vehicle includes a collision predictor, a main airbag, a seat, a sub-airbag, and a deployment controller. The collision predictor is configured to predict a collision of the vehicle. The main airbag is configured to deploy toward an occupant from a front of the vehicle when a collision of the vehicle is predicted by the collision predictor. The seat allows the occupant to be seated, and is movable in a front-back direction of the vehicle. The sub-airbag is accommodated in an upper part of the seat, and configured to deploy downward from above the occupant. The deployment controller is configured to, when a collision of the vehicle is predicted by the collision predictor, cause the sub-airbag to deploy from the upper part of the seat and subsequently cause the main airbag to deploy.

A travel sickness estimation system includes an estimation unit and an output unit. The estimation unit is configured to perform estimation processing of estimating, based on person information indicating conditions of a person who is on board a moving vehicle, whether or not the person is in circumstances that would cause travel sickness for him or her. The output unit is configured to output a result of the estimation processing performed by the estimation unit.

A vehicle seat structural component comprises a transverse tube and a structural element, in particular a vehicle seat side frame element the transverse tube is connected to the structural element in a connecting region. The structural element comprises a conical sleeve the structural is arranged captively in axial direction between deformed sections. One section is a curling wherein the conical sleeve is also arranged captively in radial direction.

A clutch unit used for a vehicle seat includes an input side clutch is configured such that one member of the input side inner ring member and the input side outer ring member rotates with a rotation of the operation lever, and the other member of the input side inner ring member and the input side outer ring member is rotated via the input side transmission member, so that the rotation of the operation lever is transmitted to the output side clutch. A rotation suppressing member configured to urge the other member in the rotation axis direction and apply a rotational resistance force greater than a force for the co-rotating is provided so as to suppress co-rotation of the other member. A pressing force transmission portion configured to transmit a force the rotation suppressing member urges in the rotation axis direction to the output side transmission member is provided.

A clutch unit used for a vehicle seat includes an input side clutch is configured such that one member of the input side inner ring member and the input side outer ring member rotates with a rotation of the operation lever, and the other member of the input side inner ring member and the input side outer ring member is rotated via the input side transmission member, so that the rotation of the operation lever is transmitted to the output side clutch. A rotation suppressing member configured to urge the other member in the rotation axis direction and apply a rotational resistance force greater than a force for the co-rotating is provided so as to suppress co-rotation of the other member. A pressing force transmission portion configured to transmit a force the rotation suppressing member urges in the rotation axis direction to the output side transmission member is provided.

The autonomous controller includes: a processor configured to control autonomous driving, calculate a safety area, and determine conversion into an autonomous driving mode based on a current location of the driver's seat; and a storage configured to store information about the safety area, data, and an algorithm run by the processor. The processor is configured to convert a manual driving mode into the autonomous driving mode when the current location of the driver's seat is within the safety area or when a request for conversion into the autonomous driving mode is input while driving in the manual driving mode, and move the current location of the driver's seat into the safety area and convert the manual driving mode into the autonomous driving mode when the current location of the driver's seat is not within the safety area.

A vehicle includes: a driving seat; a pair of doors; a seat moving mechanism configured to move the driving seat between a driving state and a receiving state, the driving seat in the driving state being positioned at a vehicle width direction center and facing a vehicle front, and the receiving state satisfying at least one condition of: the driving seat being positioned closer to one door of the pair of doors than in the driving state or the driving seat facing further toward the one door than in the driving state; a detection unit configured to detect a portable device in a detection area in a vicinity of the vehicle and outside a passenger compartment; and a seat control unit that controls the seat moving mechanism so as to move the driving seat into the receiving state.