A two-wheeled vehicle includes a frame assembly having a front end and a rear end extending along a longitudinally-extending centerline, a front ground-engaging member operably coupled to the front end of the frame assembly at a front rotational axis, and a rear ground-engaging member operably coupled to the rear end of the frame assembly at a rear rotational axis. A wheel base is defined between the front and rear rotational axes and a vertically-extending centerline of the vehicle extends vertically at the midpoint of the wheel base and is perpendicular to the longitudinally-extending centerline. The vehicle also includes a fuel tank, an airbox assembly, and a battery all positioned relative to the vertically-extending centerline of the vehicle.

A two-wheeled vehicle includes a frame assembly having a front end and a rear end extending along a longitudinally-extending centerline, a front ground-engaging member operably coupled to the front end of the frame assembly at a front rotational axis, and a rear ground-engaging member operably coupled to the rear end of the frame assembly at a rear rotational axis. A wheel base is defined between the front and rear rotational axes and a vertically-extending centerline of the vehicle extends vertically at the midpoint of the wheel base and is perpendicular to the longitudinally-extending centerline. The vehicle also includes a fuel tank, an airbox assembly, and a battery all positioned relative to the vertically-extending centerline of the vehicle.

A motorcycle includes a pair of left and right front forks, a headlight, cover members (side cowls and light covers), and camera units. A front wheel is rotatably attached to the pair of left and right front forks. The headlight irradiates a forward side. The cover members each having an internal space are disposed at least laterally outside the pair of left and right front forks in a front view. The camera units detect the forward side by acquiring visible light which is one kind of electromagnetic waves (by acquiring images). In a front view, the camera units are disposed below the headlight and laterally outside the pair of left and right front forks. The camera units are disposed in the internal spaces of the cover members.

A virtual experience providing system that provides a virtual experience in a virtual reality image based on a virtual world representing a real world or an artificial world to a user who rides a rideable mobile body includes a storage medium configured to store computer-readable instructions and a processor connected to the storage medium, the processor executing the computer-readable instructions to generate a basic movement command which is a movement command to the rideable mobile body based on a steering operation of the user and generate an event action command different from the basic movement command when a predetermined event has occurred in the virtual world, wherein the event action command is a command for causing the rideable mobile body to perform an event action that is predetermined according to the predetermined event.

A self-propelled, one-wheeled vehicle may include a board having two deck portions each having a concave front footpad configured to receive a foot of a rider, and a wheel assembly disposed between the deck portions. The concave front footpad has a rider detection sensor in the form of a membrane switch conforming to the shape of the footpad (e.g., facilitated by one or more slots formed in the membrane switch). A motor assembly drives the vehicle in response to board orientation and rider detection information.

A man-machine interaction somatosensory vehicle includes a vehicle body and two wheels provided on the vehicle body. The wheels are able to rotate around the vehicle body in a radial direction. The vehicle body further comprising a supporting frame, two pedal devices provided on the supporting frame, a control device, and a driving device for driving the wheels. The supporting frame is of an integral structure and being rotatably connected to the wheels. The pedal devices includes a pedal foot board and a first position sensor located between the pedal foot board and the supporting frame and used for sensing the stress information on the pedal devices. The control device controls, according to the stress information on the two pedal devices, the driving device to drive the wheels to move or steer.

Provided are a self-balancing scooter and a control method thereof, and a kart powered by the same. The self-balancing scooter includes two scooter bodies on which foot boards and motorized wheels are disposed, and a rotating shaft device, where the rotating shaft device includes a rotating shaft, two axle seats, and a torsion limiting mechanism. The torsion limiting mechanism controls a rotation angle by the fit between a limiting portion on the rotating shaft and a fitting portion on one axle seat. The present disclosure realizes torsion limit by directly using the rotating shaft and the axle seats without the use of an additional element (for example, a limiting shaft), thus simplifying the structure of the rotating shaft device and facilitating assembly.

A device for operating a motorcycle includes a steering device with a first and a second grip element, and includes a sensor system for detecting a riding situation. The sensor system includes a grip sensor which is arranged in or on one of the grip elements and which is designed to, in an operating state of the operating device, detect external contact on the respective grip element and generate an associated grip measurement signal. The operating device furthermore includes a steering actuator which is coupled to the steering device for the purposes of setting a steering angle with respect to a steering axis, such that, in a manner dependent on the riding situation and the grip measurement signal, a predetermined steering angle can be set at the steering device by way of the steering actuator.

An auto-balancing transportation device having a wheel structure and foot platforms that pivot between an in-use and a stowed position. The pivot axis for each platform is provided within the wheel structure so that the force exerted by a rider when stepping on a foot platform is applied to the wheel structure at a point within the wheel structure, as opposed to external to it, which is unstable and may cause the device to tip over.

A self-propelled, one-wheeled vehicle includes a suspension system configured to dampen up-and-down motion of a board relative to the axle of a central wheel assembly when the vehicle encounters obstacles (e.g., bumps) on a riding surface. Illustrative suspension systems include a shock absorber and a swingarm that couple the axle to the board. The suspension system may be disposed completely below a foot deck of the vehicle.