A method for controlling an electric drive motor of an electrically drivable bicycle includes determining a cadence of a rider of the bicycle, and operating the electric drive motor under specification of (i) a first predefined target speed for the electric drive motor, which is lower than the cadence of the rider, and (ii) a first predefined torque for the electric drive motor, when the determined cadence of the rider exceeds a predefined cadence threshold value. The method further includes operating the electric drive motor under specification of (i) a second predefined target speed for the electric drive motor, which is higher than the first target speed, and (ii) a second predefined torque for the drive motor, when a rider torque exerted by the rider on a drive train of the bicycle exceeds a first predefined rider torque threshold value.

A detector for a bicycle that includes a magnet, which generates a generated magnetic field, and a magnetic field sensor. The mutual position of the magnet and of the sensor is fixed, and the sensor is immersed in the generated magnetic field. A length of a path intended for a non-diamagnetic movable element is immersed in the generated magnetic field; if in said path length there is at least one actual portion of the movable element, the sensor detects the magnetic field perturbed by the actual portion of the movable element. Bicycle equipment and a bicycle derailleur are also described.

A method for actuating a bicycle electronic gearshift comprising the steps of: receiving a signal indicative of the heart rate of a cyclist using the bicycle; receiving a signal indicative of the power delivered by the cyclist; calculating a performance index as a function of the value of the signal indicative of the power and of the value of the signal indicative of the heart rate; obtaining a reference value for the performance index; comparing the calculated performance index with the reference value of the performance index; and, emitting a control signal as a function of the outcome of comparing step. A bicycle electronic system for practicing the disclosed method comprises an electronic gearshift, a heart rate monitor, a power sensor, and a controller configured to carry out each step of the method.

A method for actuating a bicycle electronic gearshift comprising the steps of: receiving a signal indicative of the heart rate of a cyclist using the bicycle; receiving a signal indicative of the power delivered by the cyclist; calculating a performance index as a function of the value of the signal indicative of the power and of the value of the signal indicative of the heart rate; obtaining a reference value for the performance index; comparing the calculated performance index with the reference value of the performance index; and, emitting a control signal as a function of the outcome of comparing step. A bicycle electronic system for practicing the disclosed method comprises an electronic gearshift, a heart rate monitor, a power sensor, and a controller configured to carry out each step of the method.

A bicycle shifting system is basically provided with a first shifting device, a second shifting device and a controller. One of the first shifting device and the second shifting device is mechanically operated, while the other of the first shifting device and the second shifting device is electrically operated. The controller is configured to operate at least one of the first shifting device and the second shifting device in accordance with at least one of a predetermined upshifting route and a predetermined downshifting route.

A bicycle shifting system is basically provided with a first shifting device, a second shifting device and a controller. One of the first shifting device and the second shifting device is mechanically operated, while the other of the first shifting device and the second shifting device is electrically operated. The controller is configured to operate at least one of the first shifting device and the second shifting device in accordance with at least one of a predetermined upshifting route and a predetermined downshifting route.

A bicycle control system may be configured to automatically control a bicycle, or components thereof. The bicycle control system may include a system control device configured to provide a simplified shifting system wherein large changes in speed associated with starting and stopping do not require the full attention of the automatic shifting system. The shifting system, or a system control device configured for controlling the shifting system, may be configured to determine when to enter an automatic shifting control mode, establish parameters for the automatic shifting of the automatic shifting control mode, and/or compare detected activities and values of the bicycle to the established parameters.

An automatic shifting device for a bicycle is disclosed. The device may include a shifting actuator to activate the gearshift mechanism, a computing unit connected to the shifting actuator, an operator control/display unit connected to the computing unit, an inclination angle sensor, and a velocity sensor. The operator control/display unit may receive a first input value of a gear speed of the gearshift mechanism for starting on a level underlying surface; a second input value of a velocity of the bicycle at which shifting into a maximum gear speed of the gearshift mechanism takes place on a level underlying surface; and a third input value of a velocity of the bicycle at which shifting into a maximum gear speed for this terrain inclination takes place on an underlying surface with a positive terrain inclination. An individualized shifting algorithm based on the input values may be stored in the computing unit.

A shifting system for a human-powered vehicle comprises a controller. The controller is configured to receive a driving torque and a cadence of the human-powered vehicle from at least one sensor. The controller is configured to determine a permitted shift timing based on the driving torque and the cadence. The controller is further configured to control a shift mechanism to perform a gear shift during the permitted shift timing in accordance with a permitted cadence range and a first threshold of the driving torque.

A method for controlling an electric drive motor of an electrically drivable bicycle includes determining a cadence of a rider of the bicycle, and operating the electric drive motor under specification of (i) a first predefined target speed for the electric drive motor, which is lower than the cadence of the rider, and (ii) a first predefined torque for the electric drive motor, when the determined cadence of the rider exceeds a predefined cadence threshold value. The method further includes operating the electric drive motor under specification of (i) a second predefined target speed for the electric drive motor, which is higher than the first target speed, and (ii) a second predefined torque for the drive motor, when a rider torque exerted by the rider on a drive train of the bicycle exceeds a first predefined rider torque threshold value.