A sensor system is able adjust control location and the type of controls based on the positioning of a user's hands. The sensor system is adapted to detect the positioning of a hand or body part and compensate for the changing positions of the hand or body part. When the positioning of the hand or body part changes, the controls that are able to be activated by the hand or body part also change and adapt to the location where the controls are activated, providing accessible and/or contextualized controls.

A handlebar assembly for steering a vehicle includes a handlebar, a grip positioned on the handlebar at a first end of the handlebar assembly, and a hand control assembly positioned adjacent the grip. The hand control assembly includes an optical sensor. The optical sensor has a housing with a light transmissive section, a light source configured to emit light, and a light sensor configured to detect light. The light source and the light sensor are positioned at least partially within the housing. The optical sensor is operable to detect movement of a vehicle operator along the light transmissive section of the housing by detecting reflected light from the light source with the light sensor.

A handlebar assembly for steering a vehicle includes a handlebar, a grip positioned on the handlebar at a first end of the handlebar assembly, and a hand control assembly positioned adjacent the grip. The hand control assembly includes an optical sensor. The optical sensor has a housing with a light transmissive section, a light source configured to emit light, and a light sensor configured to detect light. The light source and the light sensor are positioned at least partially within the housing. The optical sensor is operable to detect movement of a vehicle operator along the light transmissive section of the housing by detecting reflected light from the light source with the light sensor.

A vehicle includes a right front wheel, a left front wheel, a brake operator, grips, and a steering force transmission which transmits a steering force to the right front wheel and the left front wheel. The steering force transmission includes a steering shaft, a handlebar, and a tie rod. Brake operators, which operate the brakes, and the grips are located on the handlebar, and a rubber damper located on the steering force transmission significantly reduces or prevents vibrations from being transmitted to the grips, wherein the vibrations are due to a difference between a frictional force generated between the right front wheel and a corresponding road surface and a frictional force generated between the left front wheel and a corresponding road surface.

A vehicle includes a right front wheel, a left front wheel, a brake operator, grips, and a steering force transmission which transmits a steering force to the right front wheel and the left front wheel. The steering force transmission includes a steering shaft, a handlebar, and a tie rod. Brake operators, which operate the brakes, and the grips are located on the handlebar, and a rubber damper located on the steering force transmission significantly reduces or prevents vibrations from being transmitted to the grips, wherein the vibrations are due to a difference between a frictional force generated between the right front wheel and a corresponding road surface and a frictional force generated between the left front wheel and a corresponding road surface.

The embodiments herein describe a feedback system for an electric motorcycle. The feedback system notifies a user of the electric motorcycle of various conditions of the electric motorcycle via one or more output devices. In one embodiment, the feedback system causes the left and right grips of the handlebar of the electric motorcycle to vibrate to communicate information to the rider of the electric motorcycle.

A grip assembly comprising a sheet comprising a plurality of grips for handles, said plurality of grips being contained in the sheet itself, such that at least one grip is adapted to be separated from the sheet through at least one weakening line when said sheet receives a force greater than the breaking stress of said weakening line.

A personal mobility and a controlling method adjusting speed based on shape information of the handle are provided. The personal mobility includes a power device, a braking device, and a handle. The handle includes a plurality of axes provided to be movable and a deformable cover surrounding the plurality of axes. A detector detects movement of each of the plurality of axes and a controller operates the power device and the braking device based on a positional relationship between the plurality of axes according to the movement of each of the plurality of axes.

An electric vehicle includes a steering element with a handle bar element. The steering element has a hand grip portion, and at a distal end a plurality of UVC light sources producing light that is incident on the hand grip portion. The UVC light sources are coupled to a controller and a power source. A platform supports a rider of the electric vehicle. The electric vehicle includes: at least one front wheel and at least one rear wheel; an electric motor configured to provide a mechanical power to at least one of the front and rear wheels; and a battery housing configured to removably receive and hold one or more battery packs, wherein the one or more battery packs are configured to power the electric vehicle.

A personal mobility includes a steering shaft, a handlebar extending from an upper end of the steering shaft to opposite sides, two grip parts installed on opposite ends of the handlebar, respectively, to be displaceable with respect to the handlebar in a direction of intersecting a longitudinal direction of the handlebar, and a buffer device provided between each of the grip parts and the handlebar to reduce vibration or shock transmitted from the handlebar to the grip part.