One embodiment of an electric convenience vehicle (ECV) may include a frame, a plurality of wheels configured to support and move the frame, a user support member supported by the frame, a steering mechanism disposed toward a front portion of the ECV, a motor configured to cause at least one wheel to be propelled forward, propelled backward, or to remain in a fixed position, a throttle, when activated in a first position, may cause the motor to propel the wheel(s) in a forward direction, when activated in a second position, may cause the motor to propel the wheel(s) in a reverse direction, and a control and communications unit (CCU) disposed in front of the user support member, and configured to control operations of the motor.

A bicycle battery pack that can be reduced in volume includes a housing configured to be located on a frame of a bicycle and battery cells accommodated in the housing. The battery cells include at least a first battery cell and a second battery cell. The housing includes a side wall extending in a longitudinal direction of the frame in a state located on the frame. An outer portion of the side wall includes at least one groove. The at least one groove is recessed toward a region between the first battery cell and the second battery cell.

A vehicle operation and riding data collection device includes a housing defining an internal cavity, a power source supported by the housing in the internal cavity, a communications element supported by the housing in the internal cavity, a global positioning element supported by the housing in the internal cavity, at least one sensor supported by the housing in the internal cavity, and a processor configured to manage the power source, the communications element, the global positioning element, and the at least one sensor, to perform functional features corresponding to providing vehicle operation and riding data to, and receiving input from, a user.

Position indicating devices, systems and methods useable for signaling the positions of pedestrians or vehicles.

An electric vehicle includes a steering element that can include a handle bar element. A platform supports a ride of the electric vehicle. At least one front wheel and at least one rear wheel are included and coupled to the platform. An electric motor provides a mechanical power to at least one of the front and rear wheels. A battery housing removably receives and holds one or more battery packs, where the one or more battery packs are configured to power the electric vehicle. A camera is included.

A wireless switch for an active component is disclosed. The system includes a wireless switch configured with a low power wireless communication capability and a controller in wireless communication with the wireless switch, wherein the controller receives an input from the wireless switch, and communicates an adjustment command to at least one smart component.

A wireless switch for an active component is disclosed. The system includes a wireless switch configured with a low power wireless communication capability and a controller in wireless communication with the wireless switch, wherein the controller receives an input from the wireless switch, and communicates an adjustment command to at least one smart component.

A rideable golf bag cart/cycle (10) is a personal riding golf cart/cycle adapted to transport a single rider (13) and a golf bag (12) for use on a golf course. The cart/cycle (10) is generally symmetrical about a longitudinal plane (16) and includes a frame (18) with a seat (20), a front wheel and steering components (22), a rear wheel (24), an inclined bag support structure (26) extending between the legs of the rider (13), and a motor/control subassembly (28). A collapsed mode (30) in some embodiments is achieved by folding down the handlebars (72) and pivoting the running boards (56) up against the frame (16). An enhanced embodiment (118) includes a canopy (122) and a deluxe multifunctional console (124).

The present disclosure describes a system for determining an optimal gear ratio for a light electric vehicle. The optimal gear ratio may be based on an anticipated or current route of an individual riding the light electric vehicle, riding habits of the individual and/or on maintenance status information associated with the light electric vehicle. When the optimal gear ratio is determined, the system provides an indication of the optimal gear ratio to the light electric vehicle.

Presented here is a system and method for creating easy-to-understand notifications of the vehicle state. The notification can be visual or can be auditory and can indicate to the user the vehicle state even when the user's attention is directed elsewhere. The indication can serve to attract the user's attention before more involved information is presented to the user, such as text, or the indication can serve to communicate to the user the vehicle state in an easy-to-understand way such as using color-coded displays or audio indications. The intensity of the indication can be adjusted based on the likelihood that indication will be perceived by the user by, for example, measuring ambient light and/or ambient noise. Reducing the intensity of the indication conserves energy of an energy source associated with the vehicle.