CH714794A2 - Timepiece comprising a mechanical movement whose movement is regulated by an electronic device. - Google Patents

Abstract

The invention relates to a timepiece comprising a mechanical oscillator, formed by a balance and a piezoelectric spiral (8), and a regulating device (24) for regulating the frequency of the mechanical oscillator which is arranged to be able to generate control pulses temporally separated and each consisting of a momentary reduction of an electrical resistance applied by the control device between two spiral electrodes relative to a nominal electrical resistance. Each regulation pulse generates a gait deviation which is variable as a function of the moment of its beginning in a half-period of the mechanical oscillator, the characteristic function of this difference of gait relative to the moment when at least one control pulse respectively in at least half a period of the mechanical oscillator being negative on a first time zone of said at least half a period and positive on a second time zone of said at least half a period.

Description

Description

Technical Field The present invention relates to a timepiece comprising a mechanical movement, provided with a mechanical oscillator which is formed by a balance and a hairspring, and an electronic regulation device for regulating the frequency of the mechanical oscillator. which controls the progress of the mechanical movement.

In particular, the electronic regulating device comprises an auxiliary oscillator of the electronic type generally more precise than the mechanical oscillator, in particular a quartz oscillator, and a measuring device arranged to be able to measure, if necessary, a drift time of the mechanical oscillator relative to the auxiliary oscillator.

Technological background [0003] Several documents concern the electronic regulation of a mechanical oscillator in a timepiece. In particular, patent application US 2013/0 051 191 relates to a timepiece comprising a balance spring and an electronic circuit for regulating the oscillation frequency of this balance spring. The hairspring is made of a piezoelectric material or has two side layers of piezoelectric material on a silicon core, two external side electrodes being arranged on the side surfaces of the hairspring. These two electrodes are connected to the electronic regulation circuit which comprises a plurality of switchable capacitors arranged in parallel and connected to the two electrodes of the hairspring.

Using FIGS. 1 to 4, a timepiece of the type described in the above-mentioned American patent application will be described. In order not to load the drawing, we have shown in FIG. 1 only the mechanical resonator 2 of the mechanical movement of the timepiece, this resonator comprising a balance 4 oscillating around a geometric axis 6 and a hairspring 8 whose terminal curve 10 conventionally passes through a piton 12 secured to 'a balance bridge (not shown) of the mechanical movement. Fig. 2 schematically shows a portion of the hairspring 8. This hairspring is formed by a central body 14 made of silicon, two lateral layers 16, 18 made of piezoelectric material, in particular aluminum nitride (AIN), and two external metal electrodes 20, 22. The two electrodes are connected by conductive wires 26, 28 (diagrammatic representation) to an electronic regulation circuit 24.

[0005] FIG. 3 (which reproduces FIG. 1 of the previous document considered with some additional information coming from FIGS. 2 and 7) shows the general arrangement of the regulating device 32 which is incorporated in the timepiece in question and in particular the electronic circuit of regulation 24. This circuit 24 comprises a first capacitor 34 connected to the two electrodes of the piezoelectric hairspring and a plurality of switchable capacitors 36a to 36d which are arranged in parallel with the first capacitor, so as to form a variable capacitor Cv so as to be able to vary the value of the capacity connected to the electrodes of the hairspring and thus vary, according to the teaching of the document, the rigidity of the hairspring. The circuit 24 further comprises a comparator 38, the two inputs of which are connected respectively to the two electrodes of the hairspring 8, this comparator being designed to supply a logic signal making it possible to determine, thanks to successive changes in the logic state of this logic signal, the passages by zero of the voltage induced between the two electrodes of the hairspring. The logic signal is supplied to a logic circuit 40 which also receives a reference signal from a clock circuit 42 associated with a quartz resonator 44. Based on a comparison between the reference signal and the logic signal supplied by the comparator 38, the logic circuit 40 controls the switches of the switchable capacitors 36a to 36d.

In addition, there is provided following the switchable capacitance circuit a full-wave rectifier circuit 46, conventionally formed by a bridge with four diodes, which supplies a _DC voltage V _DC and charges a storage capacity 48. This electrical energy supplied by the piezoelectric hairspring provides power to the device 32. There is therefore an autonomous electrical system because it is self-supplied in the sense that the electrical energy comes from the mechanical energy supplied to the mechanical resonator 2 including the piezoelectric hairspring 8, when the mechanical resonator oscillates, forms an electromechanical transducer (an electric current generator).

As indicated in document US 2015/0 051 191 in paragraph 0052, the electronic control circuit 24 can only reduce the oscillation frequency of the mechanical resonator 2 by increasing the value of the variable capacitance Cv. This finding is confirmed by the graph in fig. 4 which shows the curve 50 giving the walking distance as a function of the value of the variable capacity Cv. It is observed in fact that the deviation obtained is always less than zero and increases in absolute value when the value of the variable capacity increases. Thus, the regulation system requires that the natural frequency of the mechanical oscillator (frequency in the absence of regulation) is greater than the nominal frequency (setpoint frequency) of this mechanical oscillator. In other words, provision is made to adjust the mechanical oscillator so that its natural frequency corresponds to a frequency greater than the set frequency, the regulation circuit having the function of making this natural frequency decrease more or less so that the step corresponds to the set frequency. Thus, a great disadvantage of such a system lies in the fact that the running of the mechanical movement is not optimal in the absence of electronic regulation. For a high-precision mechanical watch movement, one must in fact degrade its own mechanical characteristics by a non-optimal adjustment. We can conclude that such an electronic regulation system only makes sense for mechanical movements of average quality, even of poor quality, the precision of these mechanical movements depending on the electronic regulation system.

CH 714 794 A2

SUMMARY OF THE INVENTION The aim of the present invention is to propose a timepiece, provided with a mechanical resonator comprising a hairspring formed at least partially from a piezoelectric material and an electronic regulation system associated with the piezoelectric hairspring, which does not have the drawbacks of the timepiece of the prior art described above, in particular which can be associated with a mechanical movement whose progress is initially optimally adjusted, that is to say to the best of his ability. Thus, the invention aims to provide an electronic regulation system which is discreet and autonomous thanks to the use of a piezoelectric hairspring and which is truly complementary to the mechanical movement by making it possible to increase its precision without otherwise degrading a optimal initial adjustment of this mechanical movement.

The invention relates to a timepiece comprising a mechanical watch movement, provided with a mechanical oscillator formed by a balance and a hairspring and arranged to synchronize the progress of the watch movement, and a regulating device for regulating the frequency of the mechanical oscillator, this regulating device comprising an auxiliary time base, formed by an auxiliary oscillator and providing a reference frequency signal, and a device for measuring a temporal drift in the progress of the watch movement relatively at a set frequency for the mechanical oscillator which is determined by the auxiliary time base. The hairspring is formed at least partially by a piezoelectric material and by at least two electrodes arranged so as to be able to present between them an induced voltage generated by the piezoelectric material when the latter is put under mechanical stress during an oscillation of the oscillator mechanical, the two electrodes being electrically connected to the regulating device which is arranged to be able to vary the impedance of the regulating system, formed by the piezoelectric material, said at least two electrodes and the regulating device, according to a signal of measurement of the time drift provided by the measurement device. More particularly, according to the invention, the regulation device is arranged so as to be able to vary momentarily the electrical resistance generated by this regulation device between the two electrodes of the hairspring and to be able to generate regulation pulses temporally separated and each consisting of a momentary decrease in this electrical resistance relative to a nominal electrical resistance which is generated by the regulation device between said two electrodes apart from the regulation pulses. According to a remarkable physical characteristic brought to light by the inventors, each of the aforementioned regulation pulses generates a step difference for the mechanical movement which is variable as a function of the instant of its start in a half-period of the mechanical oscillator, the characteristic function of this step deviation relative to the instant when at least one regulation pulse begins respectively in at least one half-period of the mechanical oscillator being negative over a first time zone of this at least half-period and positive over a second time zone of this at least half a period. The regulating device is arranged to be able to determine whether a time drift measured by the measuring device corresponds to at least a certain advance or at least a certain delay and to generate at least one regulating pulse with a pulse start selectively provided , depending on whether the measured time drift corresponds to said at least a certain advance or to said at least a certain delay, in said first time zone or in said second time zone of at least half a period of the mechanical oscillator respectively.

Thanks to the characteristics of the timepiece according to the invention, it is therefore possible to correct both an advance and a delay in the progress of a mechanical movement by acting by regulation pulses, each having a limited duration, which vary the resistance between the two electrodes of the balance spring in different time zones of corresponding half-periods according to whether an advance or a delay has been detected in the progress of the mechanical movement.

In a preferred embodiment, the regulating device comprises a switch arranged between the two electrodes of the hairspring, this switch being controlled by a control circuit which is arranged to momentarily close this switch so as to make it conductive during the regulation pulses, which then define short-circuit pulses.

Brief description of the figures The invention will be described below in more detail with the aid of the appended drawings, given by way of non-limiting examples, in which:

Fig. 1 already described, shows a timepiece of the prior art comprising a mechanical watchmaker resonator, having a piezoelectric hairspring, and an electronic regulation circuit which is connected to the two electrodes of the piezoelectric hairspring;

Fig. 2 is an enlargement of a portion of the piezoelectric hairspring of FIG. 1;

Fig. 3 partially shows the electrical diagram of the device for regulating the timepiece of FIG. 1;

CH 714 794 A2

Fig. 4 gives the walking distance for the timepiece of the previous figures as a function of a variable capacitance applied between the two electrodes of the piezoelectric hairspring; Fig. 5 shows the electrical diagram of a regulating device incorporated in an embodiment of a timepiece according to the invention which comprises a mechanical resonator with a piezoelectric hairspring; Fig. 6 shows the running deviation per day, for the timepiece according to the invention, which is generated by the regulating device of FIG. 5 as a function of the start of short-circuit pulses, during respective oscillation periods, over a half-period between two passages through the neutral position of the mechanical resonator in each of these oscillation periods; Fig. 7 shows a mode of generation of the short-circuit pulses in the regulating device of FIG. 5 as a function of a time drift measured in the running of the timepiece; Fig. 8 is a flowchart of a regulatory process implemented in the regulatory device of FIG. 5; Figs. 9 and 10 show the graph of the voltage induced between the electrodes of the piezoelectric hairspring during a short-circuit pulse produced respectively before and after a passage of the mechanical resonator by an extreme position (between two successive passages of the mechanical resonator by its neutral position); and Fig. 11 is a cross section of a preferred embodiment of a piezoelectric hairspring forming the mechanical resonator of a timepiece according to the invention.

Detailed description of the invention The timepiece according to the invention comprises, like the timepiece of the prior art described above, a mechanical timepiece movement provided with a mechanical oscillator formed by a balance and a piezoelectric hairspring and arranged to clock the movement of the watch movement. Next, the timepiece includes a regulating device 62, the electrical diagram of which is shown in FIG. 5. This regulating device, which is intended to regulate the frequency of the mechanical oscillator, comprises an electronic regulating circuit 52 and an auxiliary time base which is formed by an auxiliary oscillator and which supplies a reference frequency signal to the electronic regulation circuit. This time base comprises for example a quartz resonator 44 and a clock circuit 42 which supplies the reference frequency signal to a divider having at least two stages DIVI and DIV2. The piezoelectric hairspring 8 is formed at least partially by a piezoelectric material and by at least two electrodes 20,22 (see fig. 2,5 and 11) which are arranged so as to be able to present between them an induced voltage U (t) by said piezoelectric material when the latter is put under mechanical stress during an oscillation of the mechanical oscillator (see fig. 7). The two electrodes are electrically connected to the electronic regulation circuit 52.

The electronic regulation circuit includes a device for measuring a possible time drift in the movement of the watch movement relative to a set frequency for the mechanical oscillator which is determined by the auxiliary time base 42,44. In the embodiment shown in FIG. 5, the measuring device is formed by a hysteresis comparator 54, the two inputs of which are connected to the two electrodes 20, 22 of the piezoelectric hairspring 8. It will be noted that in the example given, the electrode 20 is electrically connected to an input of comparator 54 via the mass of the regulating device. The hysteresis comparator provides a digital “Comp” signal (see fig. 5 and 7), the logic state of which changes just after each pass of the mechanical oscillator by its neutral position (angular position 9 (t) equal to zero), more particularly after each zero crossing of the mechanical resonator forming this mechanical oscillator. The induced voltage U (t) generated by the piezoelectric hairspring is zero during the passage of the mechanical resonator through its neutral position (angular position 'zero'), while it is maximum, for a given charge applied between the two electrodes, when the mechanical resonator is in one or other of its two extreme positions (defining the amplitude of the mechanical oscillator respectively on both sides of the neutral position).

The signal "Comp" is supplied, on the one hand, to a first input 'Up' of a bidirectional counter CB forming the measuring device and, on the other hand, to a logic control circuit 56. The bidirectional counter is thus incremented by one unit for each period of oscillation of the mechanical oscillator. It therefore continuously receives a measurement of the instantaneous oscillation frequency from the mechanical oscillator. The bidirectional counter receives at its second 'Down' input a clock signal Shor supplied by the frequency divider DIVI and DIV2, this clock signal defining a set frequency for the mechanical oscillator which is determined by the auxiliary oscillator of the auxiliary time base. Thus, the bidirectional counter supplies the control logic circuit 56 with a signal corresponding to a cumulative error over time between the oscillation frequency of the mechanical oscillator and the set frequency, this cumulative error defining the time drift of the mechanical oscillator relative to the auxiliary oscillator.

CH 714 794 A2 In general, the regulating device according to the invention is arranged so as to be able to momentarily vary the electrical resistance generated by this regulating device between the two electrodes of the piezoelectric hairspring as a function of a signal of measurement of the temporal drift of the timepiece which is provided by a device for measuring this temporal drift. More particularly, the regulating device is arranged to be able to generate temporally separate regulating pulses and each consisting of a momentary decrease in the above-mentioned electrical resistance relative to a nominal electrical resistance which is generated by the regulating device between the two electrodes outside. regulation pulses. Thus, there is a system for regulating the progress of the timepiece, and therefore of the average frequency of the mechanical oscillator, which is formed by the piezoelectric material of the hairspring 8, the two electrodes 20,22 of this hairspring and the regulating device according to the invention.

In a preferred embodiment, the regulating device 62 comprises a switch 60 arranged between the two electrodes of the balance spring, this switch being controlled by the control logic circuit 56 which is arranged to momentarily close this switch so as to rendering conductive during said regulation pulses, which then define short-circuit pulses.

In the context of the invention, the inventors have highlighted that the previously mentioned regulation pulses each generate a step deviation for the mechanical movement which is variable depending on the time of the start of the pulse. regulation considered in a half period of the mechanical oscillator. This observation is shown in fig. 6 where the characteristic function 66 of the time difference of the timepiece is given on a day relative to the time when short-circuit pulses begin respectively in all the periods of oscillation of the mechanical oscillator at course of a day, more particularly in respective half-periods of these periods of oscillation which are defined, in each period of oscillation, by the two successive passages by the neutral position of this mechanical oscillator. Thus, the abscissa of the graph of fig. 6 corresponds to the time interval At between the start of the short-circuit pulses in the respective oscillation periods and the start of the half-period considered in these oscillation periods. Remarkably, the inventors have highlighted the fact that the path difference is negative over a first time zone ZT1 = ZT1.1 & ZT1.2 of the half-period considered for the start of the short-circuit pulses and that it is positive over a second time zone ZT2 of this half-period. It will also be noted that the characteristic function 66 shown in FIG. 6 relates to an alternative embodiment in which the oscillation frequency is substantially equal to 5 Hz (oscillation period = 200 ms). The path deviation in seconds per day [s / d] is given as a function of the instant when the short-circuit pulses begin over a half-period of 100 ms, between two successive passages of the mechanical resonator through its neutral position , during each of the successive oscillation periods. The short-circuit pulses each last 10 ms in the example shown, but this is not limiting.

The electronic regulation circuit is arranged to be able to determine whether a time drift measured by the measuring device corresponds to at least a certain advance (CB> N1) or to at least a certain delay (CB <-N2), l the state of the bidirectional counter CB being supplied to the logic control circuit 56 by the signal S _D t which gives the state of the bidirectional counter. The regulation device is arranged to generate at least one regulation pulse with a selectively scheduled start, depending on whether the measured time drift corresponds to said at least a certain advance or to said at least a certain delay, in the first time zone ZT1 or in said second time zone ZT2 of respectively at least half a period of the mechanical oscillator. Indeed, a short-circuit pulse of limited duration starting in the first time zone generates a certain delay for the mechanical oscillator (negative phase shift) which can at least partially correct an advance detected in the running of the timepiece , whereas a short-circuit pulse of limited duration starting in the second time zone generates a certain advance for the mechanical oscillator (positive phase shift) which can at least partially correct a delay detected in the operation of the workpiece watchmaking.

Figs. 9 and 10 show the graph of the induced voltage U (t) between the electrodes of the piezoelectric hairspring during a short-circuit pulse starting respectively at time ti in the first time zone ZT1 of any period of oscillation and at time t2 in the second time zone ZT2 of any period of oscillation, that is respectively before and after a passage of the mechanical oscillator by an extreme position between two successive passages of this mechanical oscillator by its neutral position defining the half-period considered (see fig. 7).

In a general variant, the regulation pulses each have a duration of less than a quarter of the set period which is equal to the reverse of said set frequency for the mechanical oscillator.

In a preferred embodiment, the duration of the regulation pulses is less than or equal to one tenth of a set period. At most one regulation pulse is generated per half-period of the mechanical oscillator and preferably at most one regulation pulse per oscillation period. Then, the regulation device is arranged to generate at least one regulation pulse with a selectively scheduled start, depending on whether the measured time drift corresponds to at least a certain advance or at least a certain delay, in a first interval Intl located at inside the first time zone ZT 1, for which the walking distance given by said characteristic function 66 is greater, in absolute values, at least half of a maximum walking distance of this characteristic function on the first time zone, or in a second interval Int2 situated inside the second time zone ZT2 and for which the path deviation given by the characteristic function is greater than at least half of a deviation of

CH 714 794 A2 maximum running of this characteristic function on the second time zone. Thus, a relatively large effect is ensured during the regulation pulses, in particular during the short-circuit pulses.

Referring to Figs. 7 and 8, a regulation method according to the invention will be described which is implemented by the regulation device 62, this regulation method being in accordance with the characteristics of the invention described above. As already indicated, the hysteresis comparator 54 supplies a “Comp” signal to the logic control circuit 56, which also receives a signal Sdt for measuring the time drift of the mechanical oscillator, and therefore of the timepiece under consideration. Each rising edge and each falling edge of the “Comp” signal indicate that the mechanical resonator has just passed through its neutral position, respectively during two successive alternations of the mechanical oscillator. The control circuit selectively supplies a control signal S _C om to a timer 58 which controls a transistor 60 forming the switch by applying a Dec signal to it. More precisely, the control circuit determines the instant of the start of each pulse. short-circuit 88a, 88b by triggering or resetting the timer ("Timer") which directly turns on / off the transistor 60 (switch closed), the timer determining the duration T _R of each short-circuit pulse. At the end of each short circuit pulse, the timer opens the switch again so that the transistor 60 is no longer on, that is to say non-conductive.

By exploiting the characteristic function 66 described above, the control logic circuit is associated with a time counter CT which makes it possible to measure at least two time intervals At1 and At2 in order to be able to selectively start the timer 58 in the first interval Int1 and the second interval Int2 of a half-period, as seen in FIG. 6, depending on whether the control circuit has determined a certain advance or a certain delay, namely a positive or negative time drift, in the operation of the mechanical oscillator. More precisely, when the control circuit detects a falling edge (or alternatively a rising edge) in the signal “Comp”, it resets (“reset”) the counter CT. If the signal Sdt indicates an advance, ie CB> N1, N1 being a positive natural number, then the control circuit waits for a time interval At1 to activate the timer by a signal Scom (1), this timer then generating a signal D _C c (1) which makes the transistor 60 conductive at time t1 (in the first time zone ZT1, preferably in the first interval Int1) for a duration T _R , thus generating a first short-circuit pulse 88a which generates a phase shift negative in the oscillation of the mechanical oscillator (increase in an oscillation period and therefore decrease in the instantaneous frequency). On the other hand, if the signal S _D t indicates a delay, namely CB <-N2, N2 being a positive natural number, then the control circuit waits for a time interval At ₂ to activate the timer by a signal Scom (2), this timer then generating a signal D _C c (2) which makes the transistor 60 conductive at time t ₂ (in the second time zone ZT2, preferably in the second interval Int2) also for a duration T _R , thus generating a second pulse short circuit 88b which generates a positive phase shift in the oscillation of the mechanical oscillator (reduction of an oscillation period / increase of the instantaneous frequency).

Note that the algorithm given by the flowchart in fig. 8 may have various variants. Thus, in particular, it is possible to provide a subsequence, when a certain advance or a certain delay has been observed, in which a plurality of short-circuit pulses are carried out in a respective plurality of oscillation periods. . In such a case, provision may be made for a variant where the plurality of short-circuit pulses is carried out in successive oscillation periods or another variant in which these short-circuit pulses are carried out periodically every N oscillation periods , N being an integer greater than one (N> 1). In an a priori less advantageous variant, it is however possible to carry out a plurality of regulation pulses in a plurality of consecutive half-periods. In the latter case, a regulation pulse will be triggered alternately when a falling edge and a rising edge appear in the "Comp" signal.

Using FIG. 11 (page 4/7 of the appended drawings), a preferred embodiment of the piezoelectric hairspring 70 of the timepiece according to the invention will be described. This hairspring 70, shown in cross section, comprises a central body 72 of silicon, a layer of silicon oxide 74 deposited on the surface of the central body so as to thermally compensate the hairspring, a conductive layer 76 deposited on the oxide layer silicon, and a piezoelectric material deposited in the form of a piezoelectric layer 78 on the conductive layer 76. Two electrodes 20a and 22a are arranged on the piezoelectric layer 78 respectively on the two lateral sides of the hairspring (the two electrodes being able to partially cover the lower and upper sides of the hairspring without however joining).

In the particular variant shown in FIG. 11, the first part 80a and the second part 80b of the piezoelectric layer extending respectively on the two lateral sides of the central body 72 have, by their growth from the conductive layer 76, respective crystallographic structures which are symmetrical relative to a median plane 84 parallel to these two lateral sides. Thus, in the two lateral parts 80a and 80b, the piezoelectric layer has two same respective piezoelectric axes 82a, 82b which are perpendicular to the piezoelectric layer and in opposite directions. There is therefore an inversion of the sign of the induced voltage between the internal electrode and each of the two external lateral electrodes for the same mechanical stress. However, when the hairspring contracts or expands from its rest position, there is an inversion of the mechanical stress between the first and second parts 80a and 80b, that is to say that one of these parts undergoes compression while the other of these parts undergoes traction, and vice versa. In the end, it follows from these considerations that the voltages induced in the first and second parts have, along an axis perpendicular to the two lateral sides, the same polarity so that the conductive layer 76 can form a single internal electrode which extends on the two lateral sides of the central body 72, this internal electrode having no proper electrical connection with the regulation device. In a variant

CH 714 794 A2 particular, the piezoelectric layer consists of an aluminum nitride crystal formed by a growth of this crystal from the conductive layer 76 (internal electrode) and perpendicular thereto.

claims

Claims (7)

1. Timepiece comprising a mechanical watch movement, provided with a mechanical oscillator formed by a balance (4) and a hairspring (8; 70) and arranged to synchronize the progress of the watch movement, and a regulating device (62 ) to regulate the frequency of the mechanical oscillator, this regulating device comprising an auxiliary time base (42,44), formed by an auxiliary oscillator and supplying a reference frequency signal, and a measuring device (54, CB ) a time drift in the movement of the watch movement relative to a set frequency (Shor) for the mechanical oscillator which is determined by the auxiliary time base, the hairspring being formed at least partially by a piezoelectric material and by at at least two electrodes (20,22; 20a, 22a) arranged so as to be able to present between them a voltage induced by said piezoelectric material when the latter is placed under stress mechanical nte during an oscillation of the mechanical oscillator, the two electrodes being electrically connected to the regulating device which is arranged to be able to vary the impedance of the regulating system, formed by said piezoelectric material, said at least two electrodes and the regulation device, as a function of a measurement signal of said time drift supplied by the measurement device; characterized in that the regulating device (62) is arranged so as to be able to temporarily vary the electrical resistance generated by this regulating device between said two electrodes, the regulating device being arranged to be able to generate regulating pulses (88a, 88b ) temporally separated and each consisting of a momentary decrease in said electrical resistance relative to a nominal electrical resistance which is generated by the regulating device between said two electrodes outside of said regulating pulses, each of said regulating pulses generating a step deviation for the mechanical movement which is variable as a function of the instant of its start in a half-period of the mechanical oscillator, the characteristic function (66) of said deviation relative to said instant when at least one of said regulation pulses begins respectively in s at least half a period of the mechanical oscillator being negative over a first time zone (ZT1.1 & ZT1.2) of said at least half a period and positive over a second time zone (ZT2) of said at least half a period; and in that the regulating device is arranged to be able to determine whether a time drift measured by the measuring device corresponds to at least a certain advance or at least a certain delay, the regulating device being arranged to generate at least one of said regulation pulses (88a, 88b) with a selectively scheduled start, depending on whether the measured time drift corresponds to said at least a certain advance or to said at least a certain delay, in said first time zone or in said second time zone respectively at minus half a period of the mechanical oscillator. 2. Timepiece according to claim 1, characterized in that said regulation pulses (88a, 88b) each have a duration (T _R ) less than a quarter of the set period which is equal to the inverse of said frequency setpoint. 3. Timepiece according to claim 1 or 2, characterized in that the duration (T _R ) of said regulation pulses (88a, 88b) is less than or equal to one tenth of a set period; and in that the regulation device is arranged to generate at least one of said regulation pulses with a selectively scheduled start, depending on whether the measured time drift corresponds to said at least a certain advance or to said at least a certain delay, in a first interval (Int1) located inside said first time zone (ZT1.1) and for which said walking distance given by said characteristic function is greater, in absolute values, at least half of a maximum walking distance of this characteristic function over the first time zone or in a second interval (Int2) situated inside said second time zone (ZT2) and for which said path deviation given by said characteristic function is greater than at least half d '' a maximum deviation of this characteristic function over the second time zone. 4. Timepiece according to any one of claims 1 to 3, characterized in that said regulating device (62) comprises a switch (60) arranged between the two electrodes (20, 22) of the hairspring, this switch being controlled by a control circuit (56) which is arranged to momentarily close this switch during said regulation pulses so as to make it conducting / conducting, these regulation pulses then defining short-circuit pulses. 5. Timepiece according to any one of claims 1 to 4, characterized in that said hairspring (70) comprises a central body (72) of silicon, a layer of silicon oxide (74) deposited on the surface of said central body so as to thermally compensate the hairspring, a conductive layer (76) deposited on the silicon oxide layer, and said piezoelectric material deposited in the form of a piezoelectric layer (78) on said conductive layer, said two electrodes (20a, 20b) being arranged on the piezoelectric layer respectively on the two lateral sides of the hairspring. 6. Timepiece according to claim 5, characterized in that first and second parts (80a, 80b) of the piezoelectric layer, which extend respectively on the two lateral sides of said central body (72), have structures respective crystallographic which are symmetrical relative to a median plane (84) parallel to CH 714 794 A2 these two lateral sides; and in that said conductive layer (76) forms a single internal electrode which extends on the two lateral sides of the central body, this internal electrode having no proper electrical connection with the regulating device. 7. Timepiece according to claim 6, characterized in that said piezoelectric layer (78) consists of a crystal of aluminum nitride formed by a growth of this crystal perpendicular to said conductive layer (76) and from this conductive layer.