Device for controlling a continuous-rotation motor

The invention claimed is: 1. A control device ( 2 ) for controlling the power supply to a continuous-rotation motor ( 4 ) which is formed by a stator and a rotor ( 6 ), the stator comprising at least one supply coil (B 1 , B 2 ) and the rotor carrying at least one magnet ( 12 a , 12 b ) arranged so as to be magnetically coupled to said at least one supply coil when the rotor is rotating, this control device being arranged to be supplied with electrical power by a power supply unit ( 16 ), supplying a first supply voltage (Vdd), and comprising a voltage divider ( 22 , 24 ) arranged such that it can divide the first supply voltage and supply the stator with a second supply voltage that is lower than the first supply voltage, this control device being arranged such that it can generate, in a given operating mode or regime of the motor, electrical pulses which are driving pulses supplied to the stator with said second supply voltage for driving the rotor, the number of these electrical pulses per defined time interval being variable as a function in particular of the load applied to the motor; wherein the voltage divider ( 22 , 24 ) is arranged such that it can supply said second supply voltage with a plurality of different values and thus said electrical pulses with a variable voltage; wherein the control device ( 2 ) comprises a logic circuit ( 20 ) which is arranged such that it can count the numbers of electrical pulses in successive time periods; such that it can periodically select a voltage value, from among said plurality of different values provided for the second supply voltage, as a function of a counted number of electrical pulses or of a succession of counted numbers of electrical pulses; and such that it can control the voltage divider so that this voltage divider supplies the second supply voltage with the selected voltage value when generating electrical pulses after the selection of this voltage value; and wherein the logic circuit is arranged such that, with each new selection: the value of the second supply voltage is reduced, if this value is greater than a given low value, when a last calculated number of electrical pulses or a first increasing function of this last number is below a first determined threshold, or when the succession of calculated numbers of electrical pulses including the last number or of the first increasing function of each of these numbers satisfies a first selection criterion for which at least one number among the succession of numbers or the first increasing function of this number is below a first determined threshold; the value of the second supply voltage is increased, if this value is less than a given high value, when a last calculated number of electrical pulses or the first increasing function of this last number is above a second determined threshold, or when the succession of calculated numbers of electrical pulses including the last number or of the first increasing function of each of these numbers satisfies a second selection criterion for which at least one number among the succession of numbers or the first increasing function of this number is above a second determined threshold. 2. The control device according to claim 1 , wherein the logic circuit ( 20 ) is arranged such that it can determine in which value range, from among a plurality of determined value ranges, lies a calculated number of electrical pulses or the first increasing function of this number or a second function of a succession of calculated numbers of electrical pulses or of the first increasing function of each of these numbers, and such that it can periodically select a voltage value, from among said plurality of different values provided for the second supply voltage, as a function of the last determined value range. 3. The control device according to claim 2 , wherein the plurality of value ranges comprises a first value range having as an upper limit said first threshold, a second value range having as a lower limit said second threshold, and a third value range located between the first and second value ranges and having the first and second thresholds as a lower and upper limit respectively; and wherein the logic circuit ( 20 ) is arranged such that, with each new selection: when the last calculated number of electrical pulses or the first increasing function of this last number or the second function of the succession of calculated numbers of electrical pulses including the last number or of the first increasing function of each of these numbers is within the first value range, the value of the second supply voltage is decreased if this value is greater than said low value; when the last calculated number of electrical pulses or the first increasing function of this last number or the second function of the succession of calculated numbers of electrical pulses including the last number or of the first increasing function of each of these numbers is within the second value range, the value of the second supply voltage is increased if this value is less than said high value; when the last calculated number of electrical pulses or the first increasing function of this last number or the second function of the succession of calculated numbers of electrical pulses including the last number or of the first increasing function of each of these numbers is within the third value range, the value of the second supply voltage is maintained at a value resulting from the previous selection. 4. The control device according to claim 2 , wherein the control device ( 2 ) comprises a measuring circuit ( 18 ) arranged such that it can detect and count, when the rotor is rotating, the alternations or periods of an induced voltage in said supply coil (B 2 ) or in said at least one supply coil, the successive time periods each being defined by a given number of successive alternations or periods detected in the induced voltage; and wherein the logic circuit ( 20 ) is arranged such that it can determine an electrical pulse rate per alternation or period of the induced voltage for each of the successive time periods, the rate being equal to the division of the number of electrical pulses counted in the time period considered by the given number of alternations or periods in this time period, the rate defining the first increasing function of the calculated number of electrical pulses. 5. The control device according to claim 4 , wherein the measuring device is formed by: a comparator ( 18 a ) having two inputs respectively connected to the first and second terminals ( 27 , 28 ) of said supply coil (B 2 ) and providing, when the rotor ( 6 ) rotates, a digital signal (Pol_B 2 ) indicating the instantaneous polarity of the induced voltage in this coil, at least one first switch (SM 1 , SM 2 ) allowing the first terminal ( 27 ) of said supply coil (B 2 ) to be momentarily connected to a reference voltage that is less than the first supply voltage, and a counter ( 18 b ) arranged to count, in said digital signal, all the transitions between its two states, respectively corresponding to the two polarities of said induced voltage, and thus count a number of alternations of this induced voltage, or all the transitions to a given state of the digital signal and thus count a number of periods of the induced voltage. 6. The control device according to claim 4 , wherein the plurality of value ranges comprises a lower range of said rate having said first threshold as the upper limit, an upper range of said rate having said second threshold as the lower limit, and an intermediate range of said rate having the first and second thresholds as the lower and upper limits respectively; and wherein the logic circuit is arranged such that, with each new selection: when the last determined electrical pulse r