A bicycle derailleur comprises a circuit board, an electrical user interface, a motor housing, and a motor unit. The electrical user interface includes a user accessing portion configured to receive a user input. The motor housing includes a motor accommodating space. The motor unit is provided in the motor accommodating space and configured to generate rotational force and configured to be electrically connected to the circuit board. A first direction is defined from the circuit board toward the electrical user interface or from the electrical user interface toward the circuit board. The plurality of second directions is defined to be perpendicular to the first direction. The motor unit is at least partly provided between the user accessing portion of the electrical user interface and the circuit board when viewed in at least one of the plurality of second directions.

The disclosure provides a bicycle head. The bicycle head includes a head assembly and a control assembly. The head assembly includes a handlebar and a stem. The handlebar is mounted on the stem. The control assembly includes a casing, a first circuit board, an antenna and a battery. The casing is pivotably disposed at a portion where the handlebar is mounted on the stem. The first circuit board, the antenna and the battery are electrically connected to one and another, and at least one of the first circuit board, the antenna and the battery is located in the casing.

The disclosure provides a bicycle head. The bicycle head includes a head assembly and a control assembly. The head assembly includes a handlebar and a stem. The handlebar is mounted on the stem. The control assembly includes a casing, a first circuit board, an antenna and a battery. The casing is pivotably disposed at a portion where the handlebar is mounted on the stem. The first circuit board, the antenna and the battery are electrically connected to one and another, and at least one of the first circuit board, the antenna and the battery is located in the casing.

A control device for a first communicator of a human-powered vehicle configured to establish one of a wireless communication and a wired communication with a second communicator comprises a power supply controller. The power supply controller is configured to control a power supplying state of at least one of a first electric power source and a second electric power source to supply electric power to the first communicator based on at least one of a power-source state of at least one of the first electric power source and the second electric power source and a communication state between the first communicator and the second communicator.

Disclosed are a parking system and a parking control method of a personal mobility. The parking system of the personal mobility includes a first parking stand and a second parking stand having one end rotatably installed at a lower end of a main body of the personal mobility and configured to be rotated downward to be unfolded to opposite sides of the main body or rotated upward to be folded, a parking motor configured to operate the first and second parking stands, and a power transmission device configured to transmit a rotational force of the parking motor to shafts of the first and second parking stands to simultaneously rotate the first and second parking stands in opposite directions.

A control device includes a housing having a base portion and an extension portion. The base portion of the housing has an inward facing side and an outward facing side. The control device includes a lever coupled to and pivotable relative to the housing, and a master cylinder portion supported by the housing. The master cylinder portion has a hollow fluid cylinder. The control device also includes a piston assembly supported by the housing. The piston assembly is movable relative to the master cylinder portion. At least part of the piston assembly is disposed within the master cylinder portion. The master cylinder portion is angled relative to the outward facing side of the base portion of the housing, such that the first end of the fluid cylinder is closer to the outward facing side than the second end of the fluid cylinder is relative to the outward facing side.

A handlebar apparatus for an electronic vehicle including e-bikes and e-scooters. The handlebar apparatus includes an elongated handlebar having tubular handle portions. The apparatus further includes an electronic device housed within a casing of the handlebar. The handlebar apparatus includes sensors for receiving a throttling input and a braking input. The electronic device can perform most of the electronic operations of the electronic vehicle including receiving the throttling input and braking input and sending commands to the powertrain and braking assembly of the electronic vehicle.

A handlebar apparatus for an electronic vehicle including e-bikes and e-scooters. The handlebar apparatus includes an elongated handlebar having tubular handle portions. The apparatus further includes an electronic device housed within a casing of the handlebar. The handlebar apparatus includes sensors for receiving a throttling input and a braking input. The electronic device can perform most of the electronic operations of the electronic vehicle including receiving the throttling input and braking input and sending commands to the powertrain and braking assembly of the electronic vehicle.

A motorised mobility device including: a wheeled base; a saddle seat; and an adjustable support extending between the wheeled base and the saddle seat. The adjustable support is adjustable to raise the saddle seat from a sitting position to a standing position

A method for controlling engine braking in a vehicle comprises: determining a position of a throttle operator; determining a speed of the vehicle; and determining an engine braking mode selected. In response to the position of the throttle operator being a fully released position and the selected braking mode being a first engine braking mode: controlling an engine and a position of a throttle valve according to the first engine braking mode for applying a first level of engine braking. In response to the position of the throttle operator being the fully released position and the selected braking mode being the second engine braking mode: controlling the engine and the position of the throttle valve according to the second engine braking mode based at least on the speed of the vehicle for applying a second level of engine braking. A vehicle implementing the method is also disclosed.