A bicycle derailleur comprises a base member, a chain guide, a motor unit, and a linkage structure. The base member has at least one first link-pin-receiving opening. The motor unit has at least one second link-pin-receiving opening. The linkage structure comprises at least one link member and at least one link pin. The at least one link member is configured to movably couple the chain guide to the base member. The at least one link member has at least one third link-pin-receiving opening. The at least one link pin is configured to pivotally couple the at least one link member to the base member about at least one link pivot axis. One of the at least one link pin is configured to extend through the at least one first link-pin-receiving opening, the at least one second link-pin-receiving opening, and the at least one third link-pin-receiving opening.

A saddle riding type vehicle having a front fork that supports a front wheel, a head pipe that rotationally movably supports the front fork, a down frame extending downward from the head pipe, a front wheel brake supported by the front fork, to brake the front wheel, a braking force adjustment device that controls braking force of the front wheel brake, and output piping that connects the braking force adjustment device and the front wheel brake, the output piping has metal piping extending forward from the braking force adjustment device disposed behind the down frame, flexible piping, and a connecting member that connects the metal piping and the flexible piping. The connecting member is disposed in front of the down frame, and the flexible piping extends forward from the connecting member, to be connected to the front wheel brake.

A saddle riding type vehicle having a front fork that supports a front wheel, a head pipe that rotationally movably supports the front fork, a down frame extending downward from the head pipe, a front wheel brake supported by the front fork, to brake the front wheel, a braking force adjustment device that controls braking force of the front wheel brake, and output piping that connects the braking force adjustment device and the front wheel brake, the output piping has metal piping extending forward from the braking force adjustment device disposed behind the down frame, flexible piping, and a connecting member that connects the metal piping and the flexible piping. The connecting member is disposed in front of the down frame, and the flexible piping extends forward from the connecting member, to be connected to the front wheel brake.

An operating device for an electric bicycle may include a control/regulation device and a lighting unit. The lighting unit may include at least one electrical lighting element for emitting light. The at least one lighting element may be electrically connected to the control/regulation device such that the at least one lighting element is activatable via the control/regulation device. Via the control/regulation device, a light code with at least one of active and inactive light elements of the lighting unit is providable to visualize at least one momentary state of the electric bicycle.

An operating device for an electric bicycle may include a control/regulation device and a lighting unit. The lighting unit may include at least one electrical lighting element for emitting light. The at least one lighting element may be electrically connected to the control/regulation device such that the at least one lighting element is activatable via the control/regulation device. Via the control/regulation device, a light code with at least one of active and inactive light elements of the lighting unit is providable to visualize at least one momentary state of the electric bicycle.

An electric power generator is provided for a human-powered vehicle. The electric power generator includes an axle, a stator, a rotor and a first electrical cable. The axle has a first axial end, and a second axial end. The stator has a first axial stator-end that faces the first axial end of the axle with respect to the rotational center axis and a second axial stator-end that faces the second axial end of the axle with respect to the rotational center axis. The rotor is rotatably mounted on the axle to rotate around a rotational center axis of the electric power generator. The first electrical cable is electrically connected to the stator on the first axial stator-end of the stator. The first electrical cable extends axially through the stator toward the second axial stator-end of the stator with respect to the rotational center axis.

An electrical assembly is provided to a human-powered vehicle. The electrical assembly includes an electric component and an electrical cable. The electrical cable has a first cable-end electrically connected to the electric component and a second cable-end spaced from the first cable-end by an intermediate section of the electrical cable. A cable intersection is formed in the intermediate section of the electrical cable to restrict movement of the electrical cable relative to the electric component.

A suspension assembly for a cycle includes a plurality of links pivotably connected to one another by a plurality of pivots. A rotation sensor measures an angular relationship between two links and a setpoint of the suspension assembly is adjusted based on the angular measurements.

A method for controlling electronic shifting of a bicycle includes identifying, by a processor, a gear shift command. The processor adjusts a cadence band based on the identified gear shift command. The cadence band includes an upper cadence limit and a lower cadence limit. Adjusting the cadence band includes increasing the upper cadence limit, decreasing the lower cadence limit, or increasing the upper cadence limit and decreasing the lower cadence limit. The electronic shifting of the bicycle is controlled based on the adjusted cadence band.

A method for controlling electronic shifting of a bicycle includes identifying, by a processor, a torque at a crank arm of the bicycle. The processor compares the identified torque or a parameter based on the identified torque to a predetermined band. The predetermined band has an upper limit and a lower limit. The processor determines a target cadence based on the comparison. The processor determines a cadence band based on the determined target cadence. The method also includes controlling the electronic shifting of the bicycle based on the determined cadence band. The controlling of the electronic shifting of the bicycle includes actuating a motor of a derailleur of the bicycle for the electronic shifting of the bicycle when a cadence of the bicycle is outside of the determined cadence band.