Systems and methods are disclosed herein for an interchangeable electric scooter with seating option for 2 passengers is proposed. The assembly provides various advancements including but not limited to a glossy finish, a rectangular front frame member, an aerodynamic manual brake fin, a communication device support member, floor and front panels having multiple colors and designs, On/Off digital locking system, front and back cameras, solar panel, retractable umbrella, cell phone charging spot and holder, Bluetooth connectivity, GPS enabled, smart helmet, an integrated router forming a Wi-Fi hotspot, a daytime running lamp and back lit lights, number plate, a help switch, a sound system, a camera for livestream and social media synchronization, a communication device charger, an integral GPS.

Systems and methods are disclosed herein for an interchangeable electric scooter with seating option for 2 passengers is proposed. The assembly provides various advancements including but not limited to a glossy finish, a rectangular front frame member, an aerodynamic manual brake fin, a communication device support member, floor and front panels having multiple colors and designs, On/Off digital locking system, front and back cameras, solar panel, retractable umbrella, cell phone charging spot and holder, Bluetooth connectivity, GPS enabled, smart helmet, an integrated router forming a Wi-Fi hotspot, a daytime running lamp and back lit lights, number plate, a help switch, a sound system, a camera for livestream and social media synchronization, a communication device charger, an integral GPS.

According to one embodiment of the present invention, provided is a power assisted driving system comprising: a measurement part for measuring an operation state of a crank; a control part for determining a voltage or current necessary for power assistance on the basis of the measured value of the measurement part; a motor part, to which the voltage or current is applied, for providing driving power; and a power supply part for providing electric power to components other than itself.

A utility vehicle includes an electric powertrain assembly. The electric powertrain assembly includes at least a battery and a motor for controlling torque at various ground-engaging members of the vehicle. The configuration of the electric powertrain assembly allows for increased storage on the utility vehicle.

A utility vehicle includes an electric powertrain assembly. The electric powertrain assembly includes at least a battery and a motor for controlling torque at various ground-engaging members of the vehicle. The configuration of the electric powertrain assembly allows for increased storage on the utility vehicle.

An electric mobility apparatus is disclosed. The electric mobility apparatus may include a mid-frame assembly in which a bracket fastened to at least one component is mounted on an inner side, a front frame assembly having a portion inserted into a front face of the mid-frame assembly so as to be coupled to the mid-frame assembly, and a tail frame assembly having a portion inserted into a rear face of the mid-frame assembly so as to be coupled to the mid-frame assembly, wherein the bracket is fastened to both side faces inside the mid-frame assembly.

An electric mobility apparatus is disclosed. The electric mobility apparatus may include a mid-frame assembly in which a bracket fastened to at least one component is mounted on an inner side, a front frame assembly having a portion inserted into a front face of the mid-frame assembly so as to be coupled to the mid-frame assembly, and a tail frame assembly having a portion inserted into a rear face of the mid-frame assembly so as to be coupled to the mid-frame assembly, wherein the bracket is fastened to both side faces inside the mid-frame assembly.

A personal mobility that adjusts power supply based on a state of a kickstand is provided. The personal mobility includes a main body, a kickstand provided rotatably on one end in the main body, and a variable resistor that is provided on an axis of the kickstand as an axis. The variable resistor is configured to output a voltage that varies based on a position of the kickstand. A controller is then configured to adjust power supply when the position of the kickstand is a parking position.

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. The vehicle may have a secondary battery chargeable via a three-pin charging port including an input pin, a ground pin, and an identification pin configured to receive an expected identification signal from an external charging circuit.

Systems and methods for facilitating an operation of an electric off-road vehicle are provided. A method includes determining an estimated battery consumption data for a planned trip along a route including an off-road trail with the electric off-road vehicle using past battery consumption data and communicating the estimated battery consumption data for the planned trip to an operator of the electric off-road vehicle. When the electric off-road vehicle is travelling along the off-road trail, the method includes receiving actual battery consumption data associated with the electric off-road vehicle, and revising the estimated battery consumption data for the planned trip based on the actual battery consumption data. The revised estimated battery consumption data is communicated to the operator of the electric off-road vehicle during the planned trip.