A seat adjustment structure for adjusting a relative position between a seat and a base carrying the seat is provided. The seat adjustment structure is slidable with respect to the base along a longitudinal centerline, and includes: a pair of engaging members, fixed to one of the base or the seat with respect to the longitudinal centerline; a locking assembly, fixed to the other of the base or the seat, the locking assembly lockable to or unlockable from the engaging member; an operating member movable with respect to the seat along a vertical direction; and a cable, connecting the operating member and the locking assembly, and arranged to transmit a vertical movement of the operating member to the locking assembly, thereby causing the locking assembly to be locked or unlocked with respect to the engaging member to lock or unlock the base with respect to the seat.

An adjustable seat for a vehicle including a first seat section configured to support a lower leg portion of the passenger when the passenger is sitting facing the first direction and a second seat section configured to support an upper leg portion of the passenger when the passenger is sitting facing the first direction and a torso and head portion of the passenger when the passenger is sitting facing the second direction. The adjustable seat also comprising a third seat section configured to support the torso and head portion of the passenger when the passenger is sitting facing the first direction and the upper leg portion of the passenger when the passenger is sitting facing the second direction. The adjustable seat also comprising a fourth seat section configured to support the lower leg portion of the passenger when the passenger is sitting facing the second direction.

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.

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.

An easy entrance/exit system for a vehicle includes a vehicle seat, a pad, a pad-side magnetic device, and a seat-side magnet. The vehicle seat includes a seat base. The pad is supported atop the seat base for swiveling about a pivot point. The pad-side magnetic device is coupled to the pad at the pivot point. The seat-side magnet is within the seat base at the pivot point. The seat-side magnet is configured to apply a magnetic field to the pad-side magnetic device to govern swiveling of the pad about the pivot point.

[Object] To inhibit leg rests from colliding with each other and to allow a leg rest of his/her own seat to operate even in the case where a power source failure or the like occurs. [Solving Means] A seat apparatus according to an embodiment of the present invention includes: a seat body; a control unit; and a setting means. The seat body includes a leg rest. The control unit includes a controller. The controller determines whether the seat body is in a first state in which the seat body does not face a front seat or a back seat of the seat body or a second state in which the seat body faces one of the front seat and the back seat. The controller enables, where the controller has determined that the seat body is in the first state, a tilt operation command for the leg rest to tilt forward, and invalidates, where the controller has determined that the seat body is in the second state, the tilt operation command. The setting means fixes the determination result by the controller to the first state.

An integrated mobility system includes at least one road module, at least one railway module adapted to contain a plurality of road modules therein, and a plurality of loading/unloading infrastructures arranged in a plurality of boarding and unboarding stations scattered over a territory to allow operations for boarding/unboarding the road modules from the railway module. The railway module can be a two-story high-speed railway module. The boarding/unboarding stations are equipped with the loading/unloading infrastructures arranged so that the operations for boarding/unboarding the road module with respect to the railway module are always possible regardless of the position occupied by the road module inside the railway module, and regardless of simultaneous boarding and unboarding of other road modules. The road module and the railway module are arranged to be automatically interconnected to each other in the condition in which the road module is received inside the railway module.

An integrated mobility system includes at least one road module, at least one railway module adapted to contain a plurality of road modules therein, and a plurality of loading/unloading infrastructures arranged in a plurality of boarding and unboarding stations scattered over a territory to allow operations for boarding/unboarding the road modules from the railway module. The railway module can be a two-story high-speed railway module. The boarding/unboarding stations are equipped with the loading/unloading infrastructures arranged so that the operations for boarding/unboarding the road module with respect to the railway module are always possible regardless of the position occupied by the road module inside the railway module, and regardless of simultaneous boarding and unboarding of other road modules. The road module and the railway module are arranged to be automatically interconnected to each other in the condition in which the road module is received inside the railway module.

A floating seat may have at least one seat shell with a seat surface region and a backrest region. The seat may also have a base element on which the seat shell is arranged in an adjustable manner, and an adjustment mechanism for adjusting the seat shell relative to the base element and/or a seat base. The adjustment mechanism has at least one adjustment unit for adjusting the seat shell and at least one drive unit which is designed to lock the base element and the seat shell in place in a self-locking manner. The lock can be released by a force introduced into the adjustment unit by an occupant sitting in the seat shell via said seat shell as well as by a force introduced into the adjustment unit by the drive unit.

A floating seat may have at least one seat shell with a seat surface region and a backrest region. The seat may also have a base element on which the seat shell is arranged in an adjustable manner, and an adjustment mechanism for adjusting the seat shell relative to the base element and/or a seat base. The adjustment mechanism has at least one adjustment unit for adjusting the seat shell and at least one drive unit which is designed to lock the base element and the seat shell in place in a self-locking manner. The lock can be released by a force introduced into the adjustment unit by an occupant sitting in the seat shell via said seat shell as well as by a force introduced into the adjustment unit by the drive unit.