CH715362A2 - Method for adjusting the average frequency of a time base incorporated in an electronic watch. - Google Patents

Abstract

The invention relates to a method for determining a constant parameter of a muting value, for adjusting an average running frequency of a watch equipped with a quartz oscillator, which comprises the following steps, executed by a self-calibration circuit of the electronic device of the watch: from a first external top and a second external top received from a system external to the watch and distant by a measurement duration, corresponding to a reference number of reference periods for a periodic calibration signal (Scal) derived from the time measurement signal (Sosc) and having a calibration frequency derived from the natural frequency of the quartz oscillator, determining a calibration parameter representative of a relationship between a calibration period and a reference period for the periodic calibration signal, and determining a value of the inhibition parameter c instant according to the calibration parameter. The invention also relates to an electronic device (20) incorporated in an electronic watch for the implementation of said method.

Description

Technical area

The invention relates to the field of electronic watches and more specifically a method of adjusting the average frequency of a time base incorporated in an electronic watch.

Technological background

Electronic watch movements generally include an internal time base providing a time signal formed by periodic walking pulses and a display device receiving this time signal. The internal time base comprises, in a known manner, an oscillator and a clock circuit. The oscillator, for example a quartz oscillator, is arranged to supply a periodic time measurement signal Sosc having said natural frequency Fosc. The clock circuit is arranged to produce a clock signal Sh having the average running frequency Fhor of the watch from the time measurement signal produced by the oscillator. The clock circuit is for example a frequency divider circuit, most often formed by a chain of dividers, generally dividers by two. In a digital example, the setpoint frequency Fhor * for a clock signal Sh produced by an internal time base in an electronic watch is Fhor * = 8192 Hz, namely a quarter of the setpoint frequency Fosc * = 2 < 15> = 32,768 Hz for a quartz oscillator incorporated in the internal time base.

In industrial production, however, it is difficult to mass produce oscillators for electronic watches, all having a well-defined natural frequency making it possible to obtain, at the output of the time base, a clock signal whose operating frequency reaches the increasingly high levels of precision sought, today of the order of 5 s / y, or even less for very precise time bases.

Also, it is known to produce oscillators producing, at the end of the manufacturing phase, a time signal of an actual natural frequency Fosc in a frequency range slightly greater than the desired target frequency, for example Fosc = 32,771 Hz or 32,772 Hz for a setpoint frequency Fosc * = 32,768 Hz, then to adjust the clock signal generated by the time base as best as possible by associating with this time base a frequency adjustment circuit . In known manner, an adjustment circuit provides the clock circuit with an inhibition signal which acts so as to suppress, at a certain level of the divider, a number of periods of an internal signal Sint to the clock circuit during successive inhibition periods, for example of the order of a few seconds to a few minutes, to correct on average the running frequency Fhor of the signal produced by the internal time base of the watch.

The number of periods to be deleted in the internal periodic signal by Cinh muting period corresponds to an Vinh muting value determined individually for each oscillator. In the case of a non-thermo-compensated oscillator, the muting value is constant, independent of the temperature. In the case of a thermocompensated oscillator, the inhibition value takes account of the temperature in the watch and is given by a mathematical relation such as: <tb> <SEP> Vinh (T) = a · T <4> + b · T <3> + c · T <2> + d · T + e where T is the temperature measured by a sensor arranged in the nearby watch of the quartz oscillator and where a, b, c, d, e are coefficients of the above-mentioned polynomial which are stored in a memory. At predefined instants, for example at each inhibition period or cycle, the adjustment circuit updates the inhibition value as a function of the temperature and then acts to suppress a corresponding number of periods in the generation of a predefined internal signal from the clock circuit.

[0006] Conventionally, specialized measurement and programming equipment is used to determine a deviation of the watch's operating frequency relative to a setpoint frequency supplied by an external clock and to program the inhibition value in the electronic device of the watch. Such measurement and programming equipment is however particularly expensive and currently requires access to a resistive link of the electronic device or an electrical contact with the electronic device.

Summary of the invention

The invention aims to provide a technically simple and therefore inexpensive solution for adjusting the average operating frequency of electronic watches, and more precisely for calculating the inhibition value associated with each electronic watch. More concretely, the invention proposes a new self-calibration process consisting, for the electronic device of the watch, in determining by its own means a constant parameter of the inhibition value.

By constant parameter is meant in the context of the invention a parameter of the inhibition value which is independent of the temperature. In the case of a time base which is not thermo-compensated and whose inhibition value is defined by a constant value determined for the electronic watch in question, the constant parameter is this inhibition value. In the case of a thermo-compensated time base and whose inhibition value is defined by a mathematical relation as a function of temperature, the constant parameter is the constant coefficient or term of this mathematical relation.

To this end, the invention provides a method for determining a constant parameter of an inhibition value, or constant inhibition parameter, for adjusting an average running frequency Fhor of a watch electronic device comprising an electronic device comprising: an internal time base comprising a time measurement oscillator and a clock circuit, the time measurement oscillator having a natural frequency Fosc and being arranged to supply a periodic time measurement signal Sosc having the natural frequency Fosc, the clock circuit being arranged to receive the time measurement signal Sosc and to supply a clock signal Sh having the average running frequency Fhor, a circuit for adjusting the mean operating frequency Fhor comprising a memory storing at least said constant inhibition parameter, the adjustment circuit being arranged to inhibit, by predefined inhibition period and as a function of at least parameter d constant inhibition, one or more periods in the generation of an internal periodic signal Sint to the clock circuit involved in the generation of the clock signal Sh so that the average operating frequency is more precise, the internal periodic signal being derived from the time measurement signal, the method for determining the constant inhibition parameter being characterized in that it comprises the following steps, consisting in: ET1: from a first external top and a second external top received from a system external to the watch and distant by a measurement duration Tm corresponding to a reference number Nref of reference periods Pref for a signal calibration periodical Scal derived from the time measurement signal Sosc and having a calibration frequency Fcal derived from the natural frequency Fosc, determine a calibration parameter M representative of a ratio between a calibration period Pcal equal to the inverse of the calibration frequency Fcal and the reference period Pref, ET2: determine a value of the constant inhibition parameter as a function of the calibration parameter.

Thus, with the method of the invention, the determination of the constant parameter of the inhibition value (also called "constant inhibition parameter") is done essentially inside the watch and with the material means. of the watch, the only external elements of the watch necessary for the implementation of the invention being two ticks of an external reference clock and means for transmitting the two ticks to the watch. Existing means such as a smartphone or a constellation of satellites are perfectly suitable for this and easily accessible. Calibration of the watch adjustment circuit can thus be easily carried out at the end of production and even be easily repeated over the use of the watch if necessary. In addition, since the implementation of the method only requires the supply of two external tops to the watch, it is possible to simultaneously calibrate the adjustment circuit of several watches, by sending the two external tops simultaneously to a large number watches, which is particularly interesting at the end of manufacturing.

The method according to the invention can be implemented both for a first determination of the constant inhibition parameter, typically at the end of the watch production line, or even later for example during an interview or 'a watch repair.

The first external top and the second external top received by the calibration circuit are supplied by an external system, such as for example a reference clock external to the watch or a device external to the watch comprising or coupled to a clock of external reference, The first external top and the second external top thus give the watch a precise value of the measurement time.

The watch calibration parameter, determined in step ET1, is representative of a period Pcal of the calibration signal relative to the reference period Pref for this calibration signal and is thus representative, if the signal calibration has not been inhibited in its generation from the time measurement signal, of a Pose period of the time measurement signal relative to a corresponding Pose * setpoint period. In particular, the calibration parameter is equal to the Pcal / Pref ratio between a period of the calibration signal and a corresponding reference period.

The calibration parameter determined in step ET1 makes it possible to calculate a calibration value Vcal = (1 - M) · Cinh / Pint where M is the calibration parameter given by the equality M = Pcal / Pref, Pint is the period of the internal periodic signal, not inhibited or inhibited (in the latter case it is an average period), or a setpoint period for this internal periodic signal, and Cinh is the expected inhibition period.

Depending on whether the periodic calibration signal is derived from the internal periodic signal inhibited or not, the calibration value Vcal is respectively a correction value of the inhibition value and it makes it possible to correct the constant inhibition parameter, or an instantaneous value for the inhibition value and it makes it possible to determine the constant inhibition parameter.

In general, the constant inhibition parameter is: in the absence of thermo-compensation, the inhibition value; or a constant coefficient of a mathematical relationship calculating the inhibition value as a function of the temperature.

In the absence of thermo-compensation for the oscillator, the inhibition value is constant and we can distinguish two cases. In a first case where the periodic calibration signal has not been inhibited in its generation since the time measurement signal, the updated inhibition value is the calibration value Vcal. The calibration value Vcal therefore defines a replacement value for the inhibition value. In a second case where the periodic calibration signal is derived from the inhibited internal periodic signal, the calibration value Vcal is then a correction value for the initial inhibition value so that the updated inhibition value is equal to the addition of the initial inhibition value and the calibration value (note that, in this second case, the calibration value can be positive or negative).

In the case of a thermo-compensated oscillator, the above-mentioned calibration value Vcal makes it possible to determine or correct the constant coefficient e of a mathematical relationship for the inhibition value Vinh (T) = f (T) + e as follows: In a first case where the periodic calibration signal has not been inhibited in its generation from the time measurement signal, the calibration value Vcal is an instantaneous value for Vinh (T) , that is to say an updated inhibition value for a current temperature Tcur measured by a temperature sensor arranged in the watch during the implementation of the method according to the invention. Thus Vcal = Vinh (Tcur) = f (Tcur) + e1 where ei is the updated constant inhibition coefficient. In a first variant, a Vinit value (Tcur) is calculated which is an initial inhibition value calculated by the relation Vinit (Tcur) = f (Tcur) + e0 where e0 is the previously memorized constant inhibition coefficient (ie the initial value of this coefficient). Then, we carry out the calculation Vcor = Vcal - Vinit (Tcur) = e1– e0. Thus, Vcor is a correction value for the constant inhibition coefficient and we obtain a present value / replacement value e1 = Vcor + e0 for the constant inhibition coefficient. In a second variant, we can calculate only f (Tcur) and we thus obtain the replacement value e1 = Vcal - f (Tur) for the constant inhibition coefficient. In a second case where the periodic calibration signal is derived from the inhibited internal periodic signal, the calibration value Vcal is then an instantaneous correction value for Vinh (T). Indeed, in this case, the calibration value Vcal = Vinh (Tcur) - Vinit (Tcur) = e1– e0, and e1 = Vcal + e0.

Thus, in the case of a thermo-compensated oscillator, the calibration parameter determined in step ET1 of the method makes it possible to determine an offset which makes it possible to correct the term or constant coefficient e of the mathematical relationship giving the value inhibition as a function of temperature.

In the case where the periodic calibration signal is derived from the internal periodic signal which is inhibited, the method according to the invention can also include an initial step ET0 consisting in deactivating the adjustment circuit of the electronic device so that the internal signal is momentarily not inhibited. This preliminary step, for the calculation of the constant inhibition parameter during step ET2, avoids taking into account a previously memorized constant inhibition parameter and the time zones in which it occurs or the inhibition period. The ET2 step is thus carried out more easily and more quickly, since the calibration signal is then regular and is therefore easier to process.

According to an embodiment of the method according to the invention, step ET1 comprises the following steps, consisting in: ET1A1: between the first external top and the second external top, count a number Ca of periods of the calibration signal, and ET1A2: calculate the calibration parameter by dividing the reference number Nref by the number of periods counted Ca.

In this embodiment, the measurement of the offset between the period of the calibration signal and the reference period provided by the reference clock is produced directly from the calibration signal. The technical means necessary for the implementation, in this case a single counter arranged to count the periods of the calibration signal, are sufficient to allow the desired precision to be obtained, as will be seen better below.

According to another embodiment of the method according to the invention, step ET1 comprises the following steps, consisting in: ET1B1: count, between the first external top and the second external top, a first number Cb1 of periods of a high frequency HF signal, ET1B2: count a second number Cb2 of periods of the HF signal, between a third internal top and a fourth internal top distant by a calibration duration Tcal corresponding to the reference number Nref of periods of the calibration signal Pcal, and ET1B3: calculate the calibration parameter by dividing the second number counted Cb2 by the first number counted Cb1.

In this embodiment, a high frequency HF signal is used to measure the offset between the period of the calibration signal and the reference period provided by the reference clock. The technical means necessary for the implementation, in this case a high frequency generator and a counter, are thus a little more substantial, but they make it possible to obtain a result with the desired precision more quickly, as will be detailed below. .

According to yet another embodiment of the method according to the invention, step ET1 comprises the following steps, consisting in: ET1C1: determine the actual duration Phf of a period of a high frequency HF signal, generated by an HF generator internal to the electronic watch, between two tops provided by the internal time base or the external system, ET1C2: between the first external top and an active edge of the calibration signal following the first external top, count a first number Cc1 of periods of the HF signal, and deduce therefrom a first time offset T1 between the first external top and the active front of the calibration signal according to the first external top (T1 = Phfx Cc1), ET1C3: between the first external top and the second external top, count a number Cc2 of periods of the calibration signal Pcal, ET1C4: between the second external top and an active edge of the calibration signal following the second external top, count a second number Cc3 of periods of the HF signal, and deduce a second time shift T3 between the second external top and the active front of the calibration signal according to the second external top (T3 = Phf × Cc3), ET1C5: determine the calibration parameter M by the relation M = ((Tm - T1 + T3) / Cc2) / Pref where Tm is the measurement time between the first external top and the second external top, T1 is the first time offset , T3 is the second time offset, Cc2 is the number of periods of the calibration signal counted during the measurement duration during step ET1C3 and Pref is the reference period for the calibration signal.

In a variant, the step ET1C1 can comprise the following substeps, consisting of: ET1C11: measure a test duration by counting a number of test N0 of periods of the calibration signal, and produce a fifth test top and a sixth test top at the start and end of measurement of the test duration, ET1C12: between the fifth test top and the sixth test top produced during step ET1C11, count a third number Cc4 of periods of the HF signal, and ET1C13: calculate the duration Phf of the period of the HF signal by the relation Phf = Pref × N0 / Cc4, where Pref is the duration of a reference period, N0 is the number of tests and Cc4 is the third number counted during step ET1C12.

The invention also relates to an electronic device for a watch, an electronic device suitable for implementing a method as described above. The electronic device is characterized in that, in addition to the time base and the adjustment circuit described above, it also includes an auto-calibration circuit arranged for, from a first external top and a second external top received from an external system and distant by a measurement duration Tm corresponding to a reference number Nref of reference periods Pref for a periodic calibration signal Scal derived from the time measurement signal Sosc and having a frequency calibration calibration Fcal equal to the natural frequency or to a predetermined fraction of the natural frequency, determine a calibration parameter representative of a ratio between a calibration period equal to the inverse of the calibration frequency and the reference period, then determine a value of the constant inhibition parameter as a function of the calibration parameter, the reference period and the period d ’Preset inhibition.

Additional features of the method for determining a constant parameter of an inhibition value according to the invention and of the electronic device according to the invention are mentioned in the dependent claims and can be taken alone or in any combination possible.

As will be detailed later in the description, the invention can be implemented simply by using electronic devices already present in a watch, the only essential external elements being two tops which must be supplied to the watch by a external reference time base. Thus, the invention is particularly advantageous because it requires very few means for its implementation.

Brief description of the figures

The invention will be described below in more detail with the aid of the accompanying drawings, given by way of non-limiting examples, in which: <tb> Fig. 1 <SEP> represents a perspective view of an electronic watch and of an electronic device used to implement a method according to the invention, <tb> Fig. 2 <SEP> represents a functional diagram of an electronic device of a watch according to fig. 1, <tb> Figs. 3 to 5 <SEP> represent chronograms representative of modes of implementing the method according to the invention.

Detailed description of the invention

Referring to FIG. 1, the electronic watch 10 comprises a time display device 18, in the example shown an analog type display device comprising needles driven by a stepping motor (not shown). Alternatively, the display device may be of the digital type.

The watch also includes an electronic device 20 comprising a signal receiver 16. The signal receiver 16 is configured to communicate with an external system 12. The communication between the signal receiver 16 of the watch and the external system 12 can be considered by any known means, for example via an optical link, a wired electrical link, a magnetic link by magnetic signals generated by a coil, a radio frequency link, etc.

The signal receiver 16 is configured to receive from the external system 12 an external signal containing at least two distant tops of a measurement duration Tm, extract the tops from the external signal and transmit the tops. According to one embodiment, the external signal received by the signal receiver is a periodic signal of very precise frequency. This is the case for example if the external system is a rubidium atomic clock emitting a periodic external signal of precise frequency or if the external system is an element of a constellation of satellites (Galileo, GPS, Glonass, etc.) a periodic signal of precise frequency. In these cases, the signal receiver is configured to extract from the periodic external signal two distant tops of duration Tm, the two tops corresponding to active edges of the periodic external signal, the two tops being able to be successive or not. According to another embodiment, the external signal is a signal comprising only two signals and signal receiver 12 is configured to extract the two signals from the external signal. This is the case, for example, if the external system is a device comprising a very precise clock (eg a measuring device equipped with an atomic clock) or if the external system comprises an external device (eg an electronic device general public such as a smartphone 36 - fig. 1) coupled to a satellite network to receive a periodic signal of precise frequency.

[0034] FIG. 2 details the electronic device of the watch comprising the signal receiver 16, a microcontroller 21 as well as an internal time base 24.

The internal time base 24 comprises an oscillator 26, for example a quartz oscillator, which provides a time measurement signal Sosc of specific natural frequency Fosc, and a clock circuit 28 arranged downstream of the oscillator 26 which receives the signal Sosc on a first input and which supplies on a first output a clock signal Sh at the running frequency Fhor of the electronic watch.

According to one embodiment (not illustrated in detail), the clock circuit is a frequency divider 28 consisting of 15 frequency divider stages by 2 associated in cascade, thus making it possible to pass from a frequency signal Sosc approximately equal to 32 768 Hz at a signal Sh of frequency substantially equal to Fhor = 32 768 / (2 <15>) = 1 Hz. This signal Sh is sent across the coils of the stepper motor of the display device of the watch, in order to drive the hands of the time display device. According to another embodiment, the clock circuit is a divider by 4 circuit, consisting of 2 frequency divider stages by two partners in cascade. The signal Sh produced by the internal time base in this case has a frequency Fhor substantially equal to 32,768 / (2 <2>) = 8192 Hz.

The clock circuit also produces an internal periodic signal Sint derived from the time measurement signal Sosc. This internal signal Sint is involved in the generation of the clock signal Sh.

The electronic device 20 also includes a circuit 32 for adjusting the average operating frequency of the electronic watch. The adjustment circuit 32 notably comprises a memory 33 configured to store at least one constant value for the inhibition value (or a constant inhibition parameter) and more generally coefficients of a polynomial having the temperature as variable and defining a variable muting value depending on the temperature. The setting circuit 32 provides a Sinh inhibition signal to a second input of the clock circuit 28.

The control circuit 32 acts on an internal signal Sint * in the clock circuit. In the example of a clock circuit consisting of a frequency divider with 15 stages of division by two, the adjustment circuit 32 acts preferentially between the output of the first stage and the input of the second stage of the divider circuit of frequency, on the internal Sint * signal with a frequency close to 16,384 Hz and derived from the Sosc signal which has a frequency close to 32,768 Hz for a quartz oscillator. A programmed number of pulses at the input of the second stage of the divider circuit 28 is for example deleted every 60 s, corresponding to an inhibition period Cinh, to form the internal signal Sint which is therefore an internal signal inhibited while the signal Sint * which corresponds to it outside of the time zones of inhibition is therefore an internal signal not inhibited. It will be noted that, if the adjustment circuit is deactivated, the signals Sint * and Sint are then entirely similar and have exactly the same frequency. A frequency of 16,384 Hz corresponds to a Pint period of 1/16,384 = 61.035 µs. Reduced to the inhibition period of 60s, the resolution of the inhibition adjustment is thus equal to Pint / Cinh = 61.035 µs / 60s = 1.017 × 10 <–> <6> = 1.017 ppm (parts per million), which is equivalent at 0.088 s / d (second per day).

According to the invention, the internal time base also produces a calibration signal Scal derived from the time measurement signal Sosc produced by the oscillator and of frequency Fcal. In the examples described below in relation to FIGS. 3 - 5, the calibration signal is derived from the internal Sint * signal available at the output of the first stage of the frequency divider and is defined by this Sint * signal. Thus, in the example considered, its frequency Fcal is equal to Fosc / 2, ie close to 16,384 Hz. In other examples, the calibration signal can be equal to the signal Sosc produced by the oscillator, or equal to signal Sh produced by the clock circuit, or equal to any other signal derived from the time measurement signal Sosc and having a frequency which is a fraction of the natural frequency Fosc. If necessary, during the implementation of the process, account will be taken of the relationship between the frequency Fcal of the calibration signal and the internal frequency of the internal signal Sint * (not inhibited) on which the adjustment circuit acts. In the context of the invention, the calibration signal is used for the measurement of a value representative of the difference between the Pose period of the time measurement signal Sosc and a corresponding setpoint period.

According to the invention, the electronic device of the watch also includes an auto-calibration circuit 34 configured to determine a constant inhibition parameter for adjusting the average operating frequency of the electronic watch, by setting implements a method according to the invention comprising the following steps, consisting in: ET1: from a first external top and a second external top received from a system external to the watch and distant by a measurement duration (Tm) corresponding to a reference number (Nref) of reference periods (Pref) for a periodic calibration signal (Scal) derived from the time measurement signal (Sosc) and having a calibration frequency (Fcal) derived from the natural frequency of the oscillator, determine a representative calibration parameter (M) a ratio between a calibration period (Pcal) equal to the inverse of the calibration frequency (Fcal) and the reference period (Pref), and ET2: determine a value of the constant inhibition parameter as a function of the calibration parameter.

The calibration parameter is chosen in the examples which follow equal to the Pcal / Pref ratio; the calibration parameter is thus a measurement of the period Pcal of the watch calibration signal relative to the reference period Pref. If the calibration signal is directly derived from the time measurement signal Sosc (without undergoing the action of the adjustment circuit), then the period of the calibration signal is a multiple of the period of the signal Sosc produced by the oscillator and the calibration parameter is a measure of the period of the Sosc signal relative to the corresponding setpoint period. Recall that the period of a signal is the inverse of the frequency of said signal, so that Fref / Fcal = Pcal / Pref.

In the examples which follow, the determination of the constant inhibition parameter (ET2) from in particular the calibration parameter is not detailed, this having been dealt with previously.

Finally, for the sake of simplification, in all the numerical examples which follow: the oscillator has a natural frequency Fosc close to a set frequency equal to 32,768 Hz, the oscillator is not thermo-compensated, so that the constant muting parameter is the constant muting value to be stored in the adjustment circuit, the calibration signal has a frequency Fcal equal to the frequency Fint of the internal signal Sint * (not inhibited) on which the adjustment circuit will act, equal to Fosc / 2, therefore close to 16,384 Hz; thus, for such a calibration signal, the reference period Fref = 1/16 384 = 61.03516 µs, and the reference number Nref = 16 384 × Tm, Tm being the measurement duration (these numerical values are not sure that non-limiting examples of the more general scope of the invention).

The reference number Nref and / or the measurement duration Tm can be stored in a memory of the self-calibration circuit. As a variant, the reference number and / or the measurement duration can be supplied to the watch by the external system (reference clock or external device coupled to a reference clock), in particular before the first external top or after the second top external.

In a first example of implementation of the invention, step ET1 comprises the following steps, consisting in: ET1A1: between the first external top and the second external top, count a number Ca of periods of the calibration signal, and ET1A2: calculate the calibration parameter by dividing the reference number Nref by the number of periods counted Ca.

In an operational implementation, step ET1A1 is carried out with a counter whose conventional operation is shown diagrammatically by the timing diagrams of FIGS. 3a - 3c: on a first rising edge 101 (first external top) of the external signal (fig. 3a), the counter is activated and counts the active edges (here the rising edges from 103 to 104) of the calibration signal (fig. 3b), on a second rising edge 102 (second external top) of the external signal, the counter produces a number Ca of counted periods of the calibration signal (fig. 3c) from the start of a period Pi until the end of 'a Pca period.

In the digital example chosen (Fref = 16,384 Hz), if the measurement duration is chosen equal to 1 s, the number Nref of reference periods is equal to Nref = 16,384. If, between the two tops external 101, 102 (rising edges) distant from Tm = 1 s, the counter counts Ca = 16 386 periods, then the frequency of the calibration signal is equal to Fcal = 16 386 Hz, i.e. a calibration frequency Fcal derived from the frequency clean of the oscillator a little higher than the reference frequency Fref. The Pcal period of the calibration signal is equal to 1/16386 = 61.0277 µs. The calibration parameter M of the watch, which here corresponds to the relative value of the period of the oscillator in relation to its set period, is equal to M = Pcal / Pref = Nref / Ca = 16 384/16 386 = 0.9998779, and the relative error over the period is 1 - M, i.e. 122 × 10 <6> = 122 ppm. In other words, the calibration period is 122 ppm shorter than the reference period.

In this mode of implementation, the measurement of the offset between the natural period of the oscillator and the associated setpoint period is carried out exclusively by counting the periods of the calibration signal derived from the Sosc signal, ie in the example a calibration signal of frequency Fcal = 16 384 Hz (2 <14> Hz), with the precision of the oscillator close to about 100 ppm. The resolution of the measurement is therefore equal to the duration of a period (very close to 1/2 <14> s) of the calibration signal whose pulses are counted, divided by the measurement duration. Thus, for a measurement duration of 1 s, the resolution of such a measurement is of the order of (1/2 <14>) / 1 s = 61 ppm = 1925 s / y. For a measurement time of 100 s, the resolution is improved by a factor of 100, i.e. (1/2 <14>) / 100 s = 0.61 ppm = 19.25 s / y. For a measurement time of 3600 s (1 hour), the resolution is improved by a factor of 3600, i.e. (1/2 <14>) / 3600 s = 16.95 ppm = 0.535 s / y. It is thus noted that, according to this first embodiment, a measurement period of the order of an hour is required, to reach a resolution of 0.535 s / y, of the order of magnitude of the resolution of the adjustment circuit by inhibition which is for example of the order of 0.1175 s / y for a high precision watch.

In a second example of implementation of the invention, step ET1 comprises the following steps, consisting in: ET1B1: count, between the first external top 201 and the second external top 202, a first number Cb1 of periods of a high frequency HF signal, ET1B2: count a second number Cb2 of periods of the HF signal, between a third internal top 203 and a fourth internal top 204 distant by a calibration duration Tcal corresponding to the reference number Nref of periods of the calibration signal Pcal and calculated from the start of a first pulse Pi until the end of a PNref pulse of the periodic calibration signal (see Fig. 4b which shows the periodic calibration signal and the pulses considered), and ET1B3: calculate the calibration parameter by dividing the second number counted Cb2 by the first number counted Cb1.

In an operational implementation, the steps ET1B1 and ET1B2 are carried out using at least one counter and a high frequency generator, detailed below.

In one example, the HF generator can produce an HF signal with a frequency of 1 MHz, a frequency approximately 60 times higher than the frequency of the watch calibration signal. The absolute resolution of such an HF generator is equal to a period of the HF signal divided by the total duration of the measurement. Thus, for a measurement over 1 s, the resolution is equal to (1/10 <6>) / 1s = 1 ppm, which corresponds to a resolution of 31.536 s / y. If the measurement is extended for 100 s, the resolution is divided by 100 either (1/10 <6>) / 100 s = 0.01 ppm or 0.315 s / y. If the measurement lasts 300 s (5 min), the resolution reaches (1/10 <6>) / 300 s = 0.00333 ppm or 0.105 s / y, which is very close to the intrinsic resolution of the adjustment circuit (0.1175 s / y). The use of the HF generator in place of the quartz oscillator thus makes it possible to achieve an accuracy at least as important as in the previous embodiment, in a much shorter time.

The first step ET1B1 is in a way a step of calibrating the HF generator 22, by measuring the actual frequency Fhf of the HF generator at the time of the measurement. This takes into account the low accuracy and instability of the HF generator. The second step ET1B2 is then a measurement of the actual frequency of the quartz oscillator of the electronic device of the watch. The third step ET1B3 finally makes it possible to determine the calibration parameter.

In a digital example, during step ET1B1, a number Cb1 = 1,050,000 periods Phf of the HF signal is counted over the measurement duration Tm = 1 s defined by the first and second external tops 201, 202 distant from the measurement duration Tm = Nref × Pref = Cb1 × Phf. During step ET1B2, a number Cb2 = 1,049,911 is counted over the calibration time Tcal defined by the third and fourth ticks 203, 204 distant from the calibration time Tcal = Nref × Pcal = Cb2 × Phf. As Cb2 / Cb1 = 1,049,911 / 1,050,000 = 0.999915238, the calibration time is shorter than the measurement time; it follows that the period of the quartz oscillator is a little shorter than the expected set period for this oscillator. It is therefore necessary to "slow down" the internal time base by inhibition. The calibration parameter M is equal to Cb2 / Cb1 = 0.999915238 and the relative error over the period is equal to 1 - Cb2 / Cb1 = 1 - 0.999915238 = 0.00008476 or 84.76 ppm.

In the example above, the measurement was made over a period Tm = 1 s. As a variant, the measurement can be made over a longer measurement duration, for example Tm = 10 s, to gain a factor of 10 in precision.

In another variant, the steps ET1B1 to ET1B3 can be repeated several times (possibly with different measurement durations), for example repeated 100 times for a measurement duration of between 1 and 2 s. A measurement time of 1 to 2 s is short enough for the HF generator to be stable over the measurement time. In this case, we will systematically calculate the ratio Cb2 / Cb1 at the end of each step ET1B3 then we will realize (step ET4) an average (Cb2 / Cb1) avg of the ratios (Cb2 / Cb1) calculated in successive steps ET1B3 to determine a value average of the calibration parameter then the average correction to be made (1 - (Cb2 / Cb1) avg). This also improves accuracy, in particular thanks to the fact that the HF generator is recalibrated more frequently, which reduces the impact of its possible lack of stability.

The steps ET1B1 and ET1B2 can be carried out simultaneously, the self-calibration circuit in this case comprises two counters, both clocked by the HF signal supplied by a high frequency HF generator of the electronic device of the watch, for example the microcontroller clock. One of the counters is activated / deactivated by the external reference signal and the other counter is activated / deactivated by the watch calibration signal. As a variant, the steps ET1B1 and ET1B2 are executed successively (cf. the timing diagrams 4a – 4d) by a single counter clocked by the high frequency HF signal, the result Cb1 of the 1st count (step ET1B1) being in this case temporarily stored for use (step ET1B3) at the end of the second count Cb2 (step ET1B2).

In a third example of implementation of the invention, the step ET1 of determining the calibration parameter comprises the following steps, consisting in: ET1C1: determine the actual duration Phf of a period of a high frequency HF signal generated by an HF generator internal to the electronic watch between two tops provided by the internal time base or the external system, ET1C2: between the first external top 301 and an active edge 303 of the calibration signal following the first external top, count a first number Cc1 of periods of the HF signal, and deduce therefrom a first time offset T1 between the first external top 301 and the active edge 303 of the calibration signal following the first external top: T1 = Phf × Cc1, ET1C3: between the first external top 301 and the second external top 302, count a number Cc2 of periods of the calibration signal Pcal, ET1C4: between the second external top 302 and an active edge 304 of the calibration signal following the second external top 302, count a second number Cc3 of periods of the HF signal, and deduce therefrom a second time offset T3 between the second external top 302 and the active front 304 of the calibration signal according to the second external top: T3 = Phf × Cc3, ET1C5: determine the calibration parameter M by the relation M = ((Tm - T1 + T3) / Cc2) / Pref, where Tm is the measurement time between the first external top 301 and the second external top 302, T1 is the first time offset, T3 is the second time offset, Cc2 is the number of periods of the calibration signal counted during the measurement duration Tm during step ET1C3 and Pref is the reference period for the calibration signal.

In the example shown in Figs. 5a - 5f, step ET1C1 comprises the following substeps, consisting of: ET1C11: measure a test duration by counting a number of tests (N0 = 10) of periods of the calibration signal, and produce a fifth test top 305 and a sixth test top 306 respectively at the start and end of measurement of the test duration, ET1C12: between the fifth test top 305 and the sixth test top 306 produced during step ET1C11, count a third number Cc4 of periods of the HF signal, and ET1C13: calculate the duration Phf of the period of the HF signal by the relation Phf = Pref × N0 / Cc4, where Pref is the duration of a reference period, N0 is the number of tests and Cc4 is the third number counted during step ET1C12.

In a digital example, the external system (the reference clock) supplies (fig. 5a) two external tops 301 and 302, distant from the measurement duration Tm, in example 10s. The calibration signal (fig. 5b) of frequency Fcal (in the example of the order of 16,384 Hz) derived from the frequency of the quartz oscillator, is the signal whose exact period is sought to be determined relative to the reference period.

In step ET1C2, the periods of the HF signal are counted between the first external top (rising edge 301) and a rising edge 303 following the calibration signal distant from the first time offset T1 and at most by one period of the calibration signal, i.e. at most 1/16 384 = 61.035 µs. If the HF signal at 1 MHz is accurate to within 10%, the duration of 61.035 µs results in a maximum of 67 periods of the HF signal. In a numerical example, Cc1 = 50.

In step ET1C3, the periods of the calibration signal are counted (Cc2) between the two external tops (rising edges 301, 302) distant from the measurement duration Tm. In fig. 5f, the start of a period of the calibration signal is identified by a rising edge, and all the periods of the calibration signal started between the first external top and the second external top are counted. In a numerical example, Cc2 = 163,851.

In step ET1C11 (fig. 5e), a number of test N0 of periods of the calibration signal are counted; a fifth test top 305 and a sixth test top 306 are produced at the start and end of counting the number N0. In step ET1C12 (fig. 5d), between the fifth top 305 and the sixth top 306, a third number Cc4 of periods of the HF signal is counted. The steps ET1C11 and ET1C12 can be carried out in parallel, the tops produced during the step ET1 Cl 1 activating and deactivating the counting performed in the step ET1C12. In the example shown in fig. 5d, 5e, N0 = 10 periods of the calibration signal are counted between the active edge P1 of rank 1 and the active edge P11 of rank P11, the active edge of rank P1 being here the first active edge 303 of the calibration signal after the first external top (active front 301). The number N0 can be different, for example equal to 50 or 100. It must be sufficient for the precision sought for the measurement of the period of the HF signal. The N0 periods could also be counted between the active fronts of rank 2 and 12, or 3 and 13, etc. It is preferable, however, to perform step ET1C1 (including steps ET1C11 to ET1C13) just before or just after step ET1C2, so as to take into account as little as possible the low precision and a possible temperature drift of the HF generator during of the completion of step ET1C2.

In a numerical example, N0 = 10 and Cc4 = 665. As a first approximation, the duration of a period of the frequency calibration signal Fcal (very close to Fref) is equal to the duration Pref of a period of reference signal i.e. 1/16 384 = 61.0352 µs, and N0 periods have a duration of 610.352 µs. The duration Phf of a period of the HF signal is thus equal to Phf = 610.352 / 665 = 0.9178 µs, ie a frequency of 1.089 MHz. Note that the approximation made above is sufficient to obtain the desired final precision. Indeed, the duration N0 × Pref is known with the uncertainty about the frequency of the signal delivered by the quartz oscillator, an uncertainty which, by design of the quartz oscillator, is between 0 and 200 ppm. This uncertainty is negligible compared to the resolution of the high frequency counting over N0 periods of the calibration signal because, for a counting at 1 MHz on N0 = 10 periods of a signal at 16 384 Hz corresponding to a duration of 10 × (1 / 16,384) = 610 µs, the uncertainty is equal to 10 <–> <6> / 610 x 10 <–6> = 0.001639, or 1639 ppm. The resolution of high frequency counting over N0 periods of the internal clock signal is itself negligible compared to the resolution of high frequency counting over a single period of the calibration signal; indeed, for a counting at 1 MHz over 1 period of a signal at 16 384 Hz corresponding to a duration of 1 × (1/16 384) = 61 µs, the uncertainty is equal to 1/67 = 0.0147 or 14,700 ppm, 67 being the maximum number of periods counted between the rising edge 101 of the reference signal and the rising edge 102 of the internal clock signal during step ET1C2.

In step ET1C4, the periods of the HF signal are counted between the second external top (rising edge 302) and a rising edge 304 following the calibration signal distant from the second time offset T3 and at most one period of the calibration signal, i.e. at most 1/16 <384 = 61 µs. If the HF signal at 1 MHz is accurate to within 10%, the duration of 61 µs results in a maximum of 67 periods of the HF signal. In a numerical example, Cc3 = 53 corresponding to a time shift T3. For the sake of precision, step ET1C1 can be repeated (not shown in FIGS. 5a - 5f) just before or just after step ET1C4, in order to take into account a possible drift of the period Phf of the HF signal between 1st top 301 and 2nd top 302 of the reference signal.

The actual period Phf = 0.9178 μs of the HF signal obtained in step ET1C1, makes it possible to precisely determine the time offsets T1 and T3. T1 = Cc1 × Phf = 50 × 0.9178 µs = 45.9 µs, and T3 = Cc3 × Phf = 53 × 0.178 µs = 48.6 µs. The actual duration T2 of Cc3 = 163,851 periods of the calibration signal can then be calculated: T2 = Tm - T1 + T3 = 10 s - 45.9 µs + 48.6 µs = 10.0000027 s. The duration of a period of the calibration signal is therefore equal to 10.0000027 / 163.851 = 61.031075 µs and the frequency of the calibration signal is equal to 16.3851 / 10.0000027 = 16.385.0956 Hz. The parameter of calibration Pcal / Pref is equal to 61.031075 / 61.03516 = 0.99993313. The relative deviation of the calibration period from the reference period is equal to 1 - Pcal / Pref = 66.87 × 10 <–6> = 66.87 ppm. This difference can also be calculated by (16,385.0956 - 16,384) / 16,384 = 66.87 × 10 <–6> = 66.87 ppm.

The uncertainty of this measurement on Tm = 10 s is essentially generated by twice the resolution of the counter clocked by the high frequency HF signal, ie 2 × (1/10 <6>) / 10 = 2 × 10 <–> <7>, i.e. 0.2 ppm. This error is proportional to the duration Tm of the measurement. Thus, by choosing Tm = 100 s, the error is lowered to 0.02 ppm.

The invention also relates to an electronic device suitable for implementing the method described above. The electronic device includes an internal time base 24 and an adjustment circuit 32 as described above. According to the invention, the electronic device also comprises an auto-calibration circuit 34 arranged for, from a first external top and a second external top received from an external system and distant by a measurement duration Tm corresponding to a reference number Nref of reference periods Pref for a periodic calibration signal Scal derived from the time measurement signal Sosc and having a calibration frequency Fcal equal to said natural frequency or to a predetermined fraction of said frequency own, determine a calibration parameter representative of a ratio between a calibration period equal to the inverse of the calibration frequency and the reference period, then determine a value of the constant inhibition parameter as a function of the calibration parameter, of the reference period and the predefined inhibition period.

The external system can be a reference clock external to the watch. The external system can also be a device external to the watch comprising (or coupled to) an external reference clock. The external system produces an external reference signal comprising at least the first external top and the second external top. The electronic device also comprises a reception circuit 16 arranged to receive the external reference signal and transmit the first external top and the second external top to the self-calibration circuit.

In variants, the self-calibration circuit 34 can be connected to the internal time base 24 of the watch in order to be able to receive the calibration signal from the oscillator 26 or from the clock circuit 28. The circuit auto-calibration can also be arranged to deactivate the adjustment circuit.

According to one embodiment, the self-calibration circuit 34 may include a first counter. In a first variant, the first counter is arranged to count a number of periods of the calibration signal between the first external top and the second external top, to perform the step ET1A1 for example. In a second variant, the first counter can be arranged to measure a predefined duration (Tcal, T0) by counting a predefined number (Nref, N0) of periods of the calibration signal, to measure the calibration duration Tcal during the step ET1B2 for example or to measure the test period during step ET1C13 for example.

The first counter can also be arranged so that, when used to measure a duration, produce a start top and an end of measurement top. Thus, for example when it is used to perform the step ET1B2, the first counter can produce the third internal top 303 and the fourth internal top 304 respectively at the start and at the end of the measurement of the calibration time (Tcal) . Or, when it is used to perform the step ET1C13, the first counter can be used to produce the fifth test top 305 and the sixth test top 306 respectively at the start and at the end of the measurement of the duration of test (T0).

Also, the self-calibration circuit may include at least one second counter arranged to count periods of a high frequency HF signal. The second counter can for example be used to count periods of the HF signal: between the first external top and the second external top, for example to perform the step ET1B1, and / or between the third internal top and the fourth internal top, for example to perform the step ET1B2, and / or between the fifth test top and the sixth test top, for example to carry out step ET1C12, and / or between the first external top and an active front of the calibration signal following the first external top, for example to perform the step ET1C2, and / or between the second external top and an active edge of the calibration signal following the second external top, for example to perform step ET1C4.

Alternatively, the self-calibration circuit may include two counters arranged to count periods of the HF signal. It is thus possible to carry out two steps simultaneously, for example steps ET1B1 and ET1B2, or else to chain two successive steps such as steps ET1C2 and ET1C12 without delay.

The self-calibration circuit can also include a calculation circuit arranged to determine the calibration parameter as a function of periods counted by the first counter and / or by the second counter, depending on the implementation of the method of l 'invention.

The electronic device of the watch may also include a high frequency HF generator, for example an RC type oscillator, arranged to produce the high frequency HF signal. The HF signal is used to clock the second counter.

According to a practical embodiment, the first counter and / or the second counter and / or the HF generator of the self-calibration circuit are respectively a first counter and / or a second counter and / or a generator HF of the microcontroller.

In practice, the microcontrollers used in the watchmaking field often have an internal high frequency oscillator, for example of the RC type (resistance / capacitor). It is an oscillator without external resonator, whose frequency is imprecise (generally of the order of +/– 10%) and whose frequency is unstable, sensitive in particular to temperature. Such an oscillator is mainly used to run the software associated with the electronic device of the watch at a speed significantly higher than that of the quartz oscillator. The RC oscillator is generally used intermittently to save the watch's energy. It can therefore also be used as a high frequency generator for an additional function such as the self-calibration of the watch according to the invention.

Watchmaking microcontrollers also generally include one or more counters that can be used to count periods or measure durations. These counters are generally used occasionally, they can be used in addition for the implementation of a self-calibration according to the invention.

In an example of practical implementation, the electronic device of the watch may consist of a first integrated circuit in which the internal time base (24) and the adjustment circuit (32) are encapsulated, and d a second integrated circuit comprising the self-calibration circuit and the microcontroller.

Legend of figures

[0081] <tb> Sosc <SEP> periodic signal produced by the natural frequency oscillator Fosc (eg Fosc = 32,772 Hz for a setpoint frequency Fosc * = 32,768 Hz), and of Pose period <tb> Sint <SEP> internal signal from the clock circuit; signal derived from the Sosc signal; signal on which the control circuit acts during its generation; frequency not inhibited Fint, and period not inhibited Pint <tb> Sh <SEP> running signal (or clock signal) supplied by the clock circuit; average operating frequency Fhor (set frequency: Fhor * for example equal to 1 Hz or 8192 Hz), <tb> Scal <SEP> calibration signal derived from Sosc; of frequency Fcal (ex. Fcal = Fosc, Fosc / 2 or Fint), and of period Pcal <tb> Fref, Pref: <SEP> frequency and reference period which are associated with the calibration signal <tb> Nref <SEP> number of reference periods Pref predicted during the measurement duration Tm, which is determined by an external reference time base <tb> Sinh <SEP> inhibition signal supplied by the control circuit to the clock circuit <tb> Cinh <SEP> period (or cycle) of inhibition <tb> HF signal <SEP> high frequency signal, Fhf frequency, Phf period <tb> 16 <SEP> signal receiving circuit <tb> 18 <SEP> display device <tb> 20 <SEP> electronic device <tb> 21 <SEP> microcontroller <tb> 22 <SEP> HF generator of the microcontroller <tb> 24 <SEP> internal time base <tb> 26 <SEP> oscillator <tb> 28 <SEP> clock circuit, for example a frequency divider <tb> 32 <SEP> control circuit <tb> 33 <SEP> memory <tb> 34 <SEP> auto-calibration circuit <tb> 101, 102, 201, 202, 301, 302: <SEP> tops provided by the external system <tb> 203, 204: <SEP> third and fourth internal tops <tb> 303, 304: <SEP> active edges of the calibration signal, following an active edge of the signal supplied by the external clock <tb> 305, 306: <SEP> test tops provided by the calibration signal <tb> Tm: <SEP> measurement time determined by an external reference time base <tb> Tcal: <SEP> calibration time <tb> T0: <SEP> test duration

Claims (25)

1. Method for determining a constant parameter of an inhibition value, or constant inhibition parameter, for the adjustment of an average running frequency (Fhor) of an electronic watch comprising an electronic device comprising: - an internal time base (24) comprising an oscillator (26) for measuring time and a clock circuit (28), the oscillator for measuring time having a natural frequency (Fosc) and being arranged to supply a signal periodic time measurement (Sosc) having said natural frequency (Fosc), the clock circuit being arranged to receive the time measurement signal (Sosc) and to supply a clock signal (Sh) having the average frequency walking (Fhor), An adjustment circuit (32) for the mean operating frequency (Fhor) comprising a memory (33) storing at least said constant inhibition parameter, the adjustment circuit being arranged to inhibit, by predefined inhibition period and as a function of at least the constant inhibition parameter, one or more periods in the generation of an internal periodic signal (Sint) in the clock circuit involved in the generation of the clock signal (Sh) so that the mean running frequency is more precise, the internal periodic signal being derived from the time measurement signal, the method for determining the constant inhibition parameter being characterized in that it comprises the following steps, consisting in: - ET1: from a first external top and a second external top received from a system external to the watch and distant by a measurement duration (Tm) corresponding to a reference number (Nref) of periods of reference (Pref) for a periodic calibration signal (Scal) derived from the time measurement signal (Sosc) and having a calibration frequency (Fcal) derived from the natural frequency, determine a calibration parameter (M) representative of a ratio between a calibration period (Pcal), equal to the inverse of the calibration frequency (Fcal), and the reference period (Pref), and - ET2: determine a value of the constant inhibition parameter as a function of the calibration parameter. 2. Method according to claim 1 in which the calibration parameter determined in step ET1 makes it possible to calculate a calibration value Vcal = [1 - (Pcal / Pref)] · Cinh / Pint where Pcal is the calibration period, Pref is the reference period of the internal periodic signal, Pint is the period of the internal periodic signal, inhibited or not inhibited, or a setpoint period for this internal periodic signal, and Cinh is the predefined inhibition period. 3. Method according to claim 2 wherein, depending on whether the periodic calibration signal is derived from the internal periodic signal inhibited or not, the calibration value Vcal is respectively either a correction value of the inhibition value and it makes it possible to correct the constant inhibition parameter, ie an instantaneous value for the inhibition value and it makes it possible to determine the constant inhibition parameter. 4. Method according to one of the preceding claims, in which the constant inhibition parameter is: - in the absence of thermo-compensation, the inhibition value; or - a constant coefficient of a mathematical relationship calculating the inhibition value as a function of the temperature. 5. Method according to one of the preceding claims in which the periodic calibration signal (Scal) is derived from the internal periodic signal (Sint), characterized in that it also comprises an initial step (ET0) consisting in deactivating the circuit for setting. 6. Method according to one of the preceding claims, in which the step ET1 of determining the calibration parameter comprises the following steps, consisting in: - ET1A1: between the first external top (101) and the second external top (102), count a number (Ca) of periods of the calibration signal, and - ET1A2: calculate the calibration parameter by dividing the reference number (Nref) by the number of periods counted (Ca). 7. Method according to one of claims 1 to 5 in which the step ET1 of determining the calibration parameter comprises the following steps, consisting in: - ET1B1: count, between the first external top (201) and the second external top (202), a first number (Cb1) of periods of a high frequency HF signal generated by an HF generator internal to the electronic watch, - ET1B2: count a second number (Cb2) of periods of the HF signal, between a third internal top (203) and a fourth internal top (204) distant by a calibration duration (Tcal) corresponding to the reference number (Nref) periods of the calibration signal (Pcal), and - ET1B3: calculate the calibration parameter by dividing the second counted number (Cb2) by the first counted number (Cb1). 8. Method according to claim 7 in which the steps ET1B1 and ET1B2 are carried out: - simultaneously, or - successively, the result of step ET1B1 being temporarily stored for use during step ET1B3. 9. Method according to one of claims 7 to 8 wherein the steps ET1B1 to ET1B3 are repeated several times then, during a step ET1B4, an average of the calibration parameters calculated during the successive steps ET1B3 is carried out to determine a value average of the calibration parameter. 10. Method according to one of claims 1 to 5 in which the step ET1 of determining the calibration parameter comprises the following steps, consisting in: - ET1C1: determine the duration (Phf) of a period of a high frequency HF signal, generated by an HF generator internal to the electronic watch, between two tops provided by the internal time base or the external system, - ET1C2: between the first external top (301) and an active edge (303) of the calibration signal following the first external top, count a first number (Cc1) of periods of the HF signal, and deduce a first time offset (T1 ) between the first external top (301) and the active front (303) of the calibration signal following the first external top (T1 = Phf × Cc1), - ET1C3: between the first external top (301) and the second external top (302), count a number (Cc2) of periods of the calibration signal (Pcal), - ET1C4: between the second external top (302) and an active edge (304) of the calibration signal following the second external top (302), count a second number (Cc3) of periods of the HF signal, and deduce a second offset (T3) time between the second external top (302) and the active edge (304) of the calibration signal following the second external top (T3 = Phf × Cc3), - ET1C5: determine the calibration parameter (M) by the relation M = ((Tm - T1 + T3) / Cc2) / Pref where Tm is the measurement time between the first external top (301) and the second top (302 ) external, T1 is the first time offset, T3 is the second time offset, Cc2 is the number of periods of the calibration signal counted during the measurement duration during step ET1C3 and Pref is the reference period for the signal calibration. 11. The method of claim 10 in which the step ET1C1 comprises the following substeps, consisting in: - ET1C11: measure a test duration by counting a number of tests (N0) of periods of the calibration signal, and produce a fifth test top (305) and a sixth test top (306) at the start and end of measurement the duration of the test, - ET1C12: between the fifth test top (305) and the sixth test top (306) produced during step ET1C11, count a third number (Cc4) of periods of the HF signal, and - ET1C13: calculate the duration (Phf) of the period of the HF signal by the relation Phf = Pref × N0 / Cc4, where Pref is the duration of a reference period, N0 is the number of tests and Cc4 is the third number counted during step ET1C12. 12. The method of claim 11 wherein steps ET1C11 and ET1C12 are carried out simultaneously. 13. Method according to one of claims 11 or 12, wherein the step ET1C1 is carried out just before or just after the step ET1C2. 14. Method according to one of claims 10 to 13, wherein the step ET1C1 is repeated just before or just after the step ET1C4. 15. Electronic device incorporated in an electronic watch for implementing a method according to one of the preceding claims, comprising: - an internal time base (24) comprising an oscillator (26) for measuring time and a clock circuit (28), the oscillator for measuring time having a natural frequency (Fosc) and being arranged to supply a signal periodic time measurement (Sosc) having said natural frequency (Fosc), the clock circuit (28) being arranged to receive the time measurement signal (Sosc) and to supply a clock signal (Sh) having the average walking frequency (Fhor), - an adjustment circuit (32) of the average operating frequency (Fhor) comprising a memory (33) storing at least said constant parameter, the adjustment circuit being arranged to inhibit, by predefined inhibition period and as a function of '' at least the constant inhibition parameter, one or more periods in the generation of a periodic signal internal (Sint) to the clock circuit involved in the generation of the clock signal (Sh) so that the average frequency of on (Fhor) is more precise, the internal signal being derived from the time measurement signal (Sosc), characterized in that it also comprises an auto-calibration circuit (34) arranged for, from a first external top and a second external top received from an external system and distant by a measurement duration (Tm) corresponding to a reference number (Nref) of reference periods (Pref) for a periodic calibration signal (Scal) derived from the time measurement signal (Sosc) and having a calibration frequency (Fcal) equal to the said natural frequency or at a predetermined fraction of said natural frequency, determining a calibration parameter representative of a ratio between a calibration period equal to the inverse of the calibration frequency and the reference period, then determining a value of the constant inhibition parameter as a function of the calibration parameter, the reference period and the predefined inhibition period. 16. Electronic device according to claim 15 also comprising a circuit (16) for receiving an external reference signal comprising at least the first external top (101, 201, 301) and the second external top (102, 202, 302) , the reception circuit (16) being arranged to receive the external reference signal and transmit the first external top and the second external top to the auto-calibration circuit. 17. Electronic device according to claim 15 or 16 in which the auto-calibration circuit (34) is connected to the internal time base (24) of the watch in order to be able to receive the calibration signal from the oscillator (26) for measuring time or the clock circuit (28). 18. Electronic device according to one of claims 15 to 17 wherein the self-calibration circuit is also arranged to be able to deactivate the adjustment circuit. 19. Electronic device according to one of claims 15 to 18 wherein the auto-calibration circuit (34) comprises a first counter arranged to count a number of periods of the calibration signal between the first external top and the second external top or to measure a predefined duration (Tcal, T0) by counting a predefined number (Nref, N0) of periods of the calibration signal. 20. Electronic device according to claim 19, in which the first counter is also arranged for: - produce a third internal top (303) and a fourth internal top (304) respectively at the start and at the end of the measurement of a calibration time (Tcal), or - produce a fifth test top (305) and a sixth test top (306) respectively at the start and at the end of the measurement of a test duration (T0). 21. Electronic device according to one of claims 15 to 20 in which the self-calibration circuit also comprises at least a second counter arranged to count periods of a high frequency HF signal: - between the first external top and the second external top, and / or - between the third internal top and the fourth internal top, and / or - between the fifth test top and the sixth test top, and / or - between the first external top and an active front of the calibration signal following the first external top, and / or - between the second external top and an active front of the calibration signal following the second external top. 22. Electronic device according to one of claims 19 to 21 in which the self-calibration circuit also comprises a calculation circuit arranged to determine the calibration parameter as a function of periods counted by the first counter and / or by the second counter. 23. Electronic device according to one of claims 21 to 22, also comprising a high frequency HF generator, in particular an RC type oscillator, arranged to produce the high frequency HF signal. 24. Electronic device according to claim 23 in combination with claim 19 wherein the first counter and / or the second counter and / or the high frequency HF generator of the auto-calibration circuit are respectively a first counter and / or a second counter and / or HF generator of the microcontroller (21). 25. Electronic device according to one of claims 16 to 24 consisting of a first integrated circuit in which the internal time base (24) and the adjustment circuit (32) are encapsulated, and of a second integrated circuit comprising the auto-calibration circuit and a microcontroller.