A human-powered vehicle control device includes an electronic controller that controls a motor. The motor assists in propulsion of a human-powered vehicle including a transmission configured to change, in steps, a first ratio of a rotational speed of a drive wheel to a rotational speed of a rotary body to which human drive force is input. The controller controls the motor in a first control state if the first ratio is changed by only one step during a predetermined period or a signal is received for changing the first ratio by one step during the predetermined period. The controller controls the motor in a second control state that differs from the first control state if the first ratio is changed by at least two steps during the predetermined period or a signal is received for changing the first ratio by at least two steps during the predetermined period.

The present disclosure describes a controller for a light electric vehicle. The controller may include a user interface that includes one or more visual indicators and selectable buttons. The visual indicators may be used to convey various status indicators and/or alerts to an individual that is riding the light electric vehicle. The selectable buttons may be used to alter an operating state of the light electric vehicle and/or to provide operating status information about the light electric vehicle.

An electric vehicle includes a carrier, at least one wheel assembly, a driving module and a controlling module. The carrier is for carrying an user. The wheel assembly is disposed at the carrier and includes a wheel. The driving module includes a motor disposed at the wheel assembly. The driving module is for switching the motor and includes a sensing unit and a microprocessor. The sensing unit is electronically connected to the motor to detect at least one characteristic of the motor. The microprocessor is electronically connected to the motor. The microprocessor determines whether a predetermined conduction is satisfied according to the characteristic of the motor. When the predetermined conduction is satisfied, the motor is turned off by the microprocessor.

An electronic device is related to a human-powered vehicle operating device that includes an operating mechanism, which is for operating at least one of a human-powered vehicle transmission device and a human-powered vehicle braking device, and at least one operating member. The electronic device comprises a storage, an electronic controller, and a communication unit. The storage stores setting information related to an operation of the at least one operating member and to an output destination device. The electronic controller is configured to generate an output signal corresponding to the operation of the at least one operating member based on the setting information. The communication unit transmits the output signal to the output destination device that includes at least one of a game device, a training device, an audio device, and a video device.

A power supply device is provided for a human-powered vehicle. The power supply device comprises a base, a first electrical port, a second electrical port and a third electrical port. The first electrical port is provided to the base. The first electrical port has a first connection configuration. The second electrical port is provided to the base, and having a second connection configuration. The third electrical port is provided to the base, and having a third connection configuration. The first connection configuration, the second connection configuration and the third connection configuration have a same shape.

The disclosed computer-implemented method may include detecting a throttle position of a micromobility vehicle (MV) and determining an acceleration of the MV based at least on the throttle position. The acceleration is associated with a torque magnitude of the MV. The method also includes comparing the acceleration with a target acceleration associated with the throttle position. The method further includes modifying the torque magnitude based at least on the comparison of the acceleration of the MV with the target acceleration associated with the throttle position. Various other methods, systems, and computer-readable media are also disclosed.

An operating device for a human-powered vehicle comprises a base member, an informing unit, and an operating member. The base member is configured to be mounted to a handlebar. The informing unit is configured to inform a user of first information relating to an assist driving unit configured to assist a human power. The operating member is movably coupled to the base member to control a component different from the assist driving unit.

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.

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.

An apparatus for determining bicycle pedaling may include a sensor that detects the angular velocity and/or position of a drivetrain or rear sprocket assembly of the bicycle The apparatus may determine values indicative of pedaling. The apparatus may be configured to be housed within a component of the bicycle, such as within a hollow opening of the spindle or crank axle. The apparatus also may include a wireless transmitter to communicate with another component, such as a suspension controller.