Method for controlling a motor of a derailleur of a bicycle electronic gearshift, and component suitable for carrying out such a method

What is claimed is: 1. A method for controlling a motor of a derailleur of a bicycle electronic gearshift during a displacement from an initial position to a destination position, the method comprising a step of feedback controlling a current (I(t)) absorbed by the motor during the displacement from the initial position to the destination position by controlling a drive voltage (V(t), FW(t), RW(t)) of the motor such that the drive voltage (V(t), FW(t), RW(t)) of the motor is adjusted throughout the displacement from the initial position to the destination position, the step of feedback controlling a measured current (I(t)) absorbed by the motor comprises controlling the drive voltage (V(t), FW(t), RW(t)) of the motor so that an error (EPSILON(t)) defined by a difference between a reference current (Iref(t), Iref(y(t)), Iref(t,y(t))) and the measured current (I(t)) absorbed by the motor tends to become zero. 2. The method according to claim 1 , comprising defining the reference current (Iref(t)) as a function of time, more in particular a direct function of the time (t) elapsed since a start of the displacement from the initial position to the destination position. 3. The method according to claim 1 , comprising defining the reference current (Iref(y(t))) as a function of a residual distance (y(t)) from the destination position. 4. The method according to claim 1 , comprising defining the reference current (Iref(t,y(t))) as a function both of a time (t) elapsed since a start of the displacement from the initial position to the destination position, and of a residual distance (y(t)) from the destination position. 5. The method according to claim 2 , comprising defining the reference current (Iref(t)) as a monotonically increasing function of the elapsed time (t), at least in an initial time interval of the displacement. 6. The method according to claim 3 , comprising defining the reference current (Iref(y(t))) as a monotonically increasing function of the residual distance (y(t)), at least in a final part of the displacement. 7. The method according to claim 1 , further comprising a step of interrupting a power supply to the motor after a time limit (Tmax), irrespective of whether the destination position has been reached or not. 8. The method according to claim 1 , wherein the step of feedback controlling the current (I(t)) absorbed by the motor comprises measuring the absorbed current (I(t)) and filtering the measured current (I(t)) absorbed by the motor, more preferably analogically and/or digitally filtering. 9. The method according to claim 1 , comprising a step, preliminary to a step of displacement attempt, of carrying out integrity checks of a controller of the motor, and in a negative case aborting the displacement and signaling anomalies and/or a step, subsequent to the step of displacement attempt, of checking whether the destination position has been reached within a certain tolerance, and in a negative case aborting the displacement and signaling an anomaly. 10. A derailleur of a bicycle electronic gearshift, the derailleur comprising: an electric motor, and a controller of the electric motor, wherein the controller of the electric motor is configured to carry out a feedback control of a current (I(t)) absorbed by the motor during a displacement from an initial position to a destination position such that a drive voltage (V(t), FW(t), RW(t)) of the motor is adjusted throughout the displacement from the initial position to the destination position, the feedback control of a measured current (I(t)) absorbed by the motor comprises controlling the drive voltage (V(t), FW(t), RW(t)) of the motor so that an error (EPSILON(t)) defined by a difference between a reference current (Iref(t), Iref(y(t)), Iref(t,y(t))) and the measured current (I(t)) absorbed by the motor tends to become zero. 11. An assembly of a derailleur of a bicycle electronic gearshift, the assembly comprising: an electric motor, and a controller of the electric motor external to the derailleur, wherein the controller of the electric motor is configured to carry out a feedback control of a current (I(t)) absorbed by the motor during a displacement from an initial position to a destination position such that a drive voltage (V(t), FW(t), RW(t)) of the motor is adjusted throughout the displacement from the initial position to the destination position, the feedback control of a measured current (I(t)) absorbed by the motor comprises controlling the drive voltage (V(t), FW(t), RW(t)) of the motor so that an error (EPSILON(t)) defined by a difference between a reference current (Iref(t), Iref(y(t)), Iref(t,y(t))) and the measured current (I(t)) absorbed by the motor tends to become zero. 12. A bicycle electronic gearshift comprising: at least one derailleur having an electric motor, and a controller of the electric motor, said at least one derailleur configured to displace a chain among toothed wheels of a set of toothed wheels associated with an axle of pedal cranks or with a hub of a rear wheel of a bicycle, respectively, wherein the controller of the electric motor is configured to carry out a feedback control of a current (I(t)) absorbed by the motor during a displacement from an initial position to a destination position such that a drive voltage (V(t), FW(t), RW(t)) of the motor is adjusted throughout the displacement from the initial position to the destination position, the feedback control of a measured current (I(t)) absorbed by the motor comprises controlling the drive voltage (V(t), FW(t), RW(t)) of the motor so that an error (EPSILON(t)) defined by a difference between a reference current (Iref(t), Iref(y(t)), Iref(t,y(t))) and the measured current (I(t)) absorbed by the motor tends to become zero. 13. The derailleur according to claim 10 , wherein the controller of the electric motor carries out a feedback control of a residual distance (y(t)) from the destination position, said feedback control of the residual distance (y(t)) being a control loop external with respect to said feedback control of the current (I(t)) absorbed by the motor. 14. The derailleur according to claim 10 , wherein the controller comprises an H bridge for driving the electric motor and a shunt connected to a lower side of the H bridge to draw a current representative of the current (I(t)) to be measured. 15. The method according to claim 4 , comprising defining the reference current (Iref(t,y(t))) as a monotonically increasing function of the elapsed time (t), at least in an initial time interval of the displacement. 16. The method according to claim 4 , comprising defining the reference current (Iref(t,y(t))) as a monotonically increasing function of the residual distance (y(t)), at least in a final part of the displacement. 17. The assembly according to claim 11 , wherein the controller of the electric motor carries out a feedback control of a residual distance (y(t)) from the destination position, said feedback control of the residual distance (y(t)) being a control loop external with respect to said feedback control of the current (I(t)) absorbed by the motor. 18. The bicycle electronic gearshift according to claim 12 , wherein the controller of the electric motor carries out a feedback control of a residual distance (y(t)) from the destination position, said feedback control of the residual distance (y(t)) being a control loop external with respect to said feedback control of the current (I(t)) absorbed by the motor. 19. The assembly according to claim 11 , wherein the controlle