EP0052884A1 - Timepiece comprising a division ratio adjustable divider chain - Google Patents

Abstract

The timepiece includes a low frequency oscillator serving as time base and arranged to feed a first chain of frequency dividers having an adjustable division rate in order to display the time and a high frequency oscillator feeding a second chain of frequency dividers. During an imprecise period established by the first chain (3) reference pulses from the second chain (7) are counted thereby to establish a binary value (HF-DF) representing the amount of imprecision of the first chain in respect of the reference. This value is transferred into a memory in order to correct directly or indirectly the division rate of the first divider chain. There is thus obtained an oscillator having the stability of a high frequency oscillator but with energy consumption only slightly exceeding that of a low frequency oscillator.

Description

The invention relates to a timepiece comprising a low-frequency oscillator as a time base supplying a first chain of frequency dividers with adjustable division ratio for displaying the time and a high-frequency oscillator supplying a second chain of frequency dividers frequency.

Such an arrangement is known from the publication EP 0 015 873. In this publication, a high-frequency crystal oscillator is claimed which, in order to reduce the current consumption, comprises a circuit equipped with a crystal oscillator low frequency, means for producing a correction signal which is used to control a programmable frequency divider and an electronic switch for periodically interrupting the high frequency quartz oscillator.

It is known in fact that a high-frequency quartz oscillator of 1 MHz or more has a temperature and aging stability which is more favorable than that of a conventional low-frequency quartz oscillator at 32 kHz. On the other hand, this high-frequency quartz oscillator with the frequency divider which is linked to it has a substantially higher current consumption, which requires frequent battery replacements. Thus, the invention cited above proposes an oscillator which has all the advantages of a high-frequency oscillator but whose consumption does not exceed that shown by a low-frequency oscillator. To achieve this, the cited publication uses an electronic switch which periodically activates (every 15 minutes) for a relatively short time (16 seconds) the HF oscillator. The signals emitted by the HF and LF oscillators feed each of the secondary frequency dividers which each produce at their output a signal whose period is approximately 16 seconds. These two signals feed a beat generator, the output result of which corresponds to the difference existing between the LF period to be set and the HF reference period. This difference is then used to correct the division ratio of the main frequency divider. Thus, in this system, every 15 minutes we question the division ratio of the main divider and, in the case where the frequency of the low-frequency oscillator has varied, we correct said division ratio by a signal from a learning circuit consisting of a beat generator.

The system whose operation has just been recalled has several drawbacks. The first is to require several secondary frequency dividers, which complicates the construction. Then to transform the signals from the HF and BF oscillators to produce a beat, instead of using them directly as they exist in binary form, which decreases the precision. Finally, that of not taking into consideration that, for cost price reasons, the HF quartz can be roughly adjusted around a nominal frequency, in which case means must be used to memorize the existing difference.

While avoiding the above drawbacks, the present invention proposes to regulate the running of the timepiece comprising a frequency divider with the adjustable division ratio by adjustment means which appear in the claims.

The invention will be better understood in the light of the description which follows and of the drawings which show by way of example an embodiment allowing the adjustment of the running of the timepiece.

• Figure 1 is a block diagram of the timepiece adjustment system according to the invention.
• FIG. 2 is an explanatory diagram of the operation of the logic control circuit which appears in FIG. 1.
• FIG. 3 is a detailed diagram of the servo control logic as it appears in block 10 of FIG. 1.
• FIG. 4 is a diagram showing the behavior of the chain of HF dividers during a LF adjustment period.

Figure 1 shows how the timepiece object of the invention is arranged. It includes a low-frequency oscillator, generally with quartz crystal 1, which attacks via an inhibition circuit 2 a chain of frequency dividers 3. Inhibition circuit and chain of dividers together form a system with adjustable ratio. In known timepieces and if the frequency of the LF oscillator is of the order of 33 kHz, it will take fifteen divisors by two to obtain a frequency of 1 Hz at the display control output (1 s) to display the time (HMS). Here chain 3 is extended by ten additional dividers to provide additional outputs at 4.8 and 1024 seconds. Thus in the example given, the chain 3 totals twenty-five binary divisors. At the input of chain 3, the inhibition circuit 2 is controlled by blocks 4 and 18 which make it possible to suppress a certain proportion of the pulses supplied by the time base and thus to lower the command frequency of the actuating motor. display up to the desired value.

This technique is known; it has been sufficiently explained for example in the statements of inventions CH 534 913, 554 015 and 570 651 so that it is not necessary to return to it here. However, it will be recalled that the adjustment by feedback on an inhibition circuit or on the frequency divider no longer requires mechanical adjustment of the time base and the stability of the assembly is no longer affected since it can be go from an adjustment trimmer.

FIG. 1 also shows that the arrangement comprises, in addition to the oscillator BF, a second high-frequency oscillator 5, generally with quartz crystal, which, through a NOR gate 6, feeds a second chain of frequency dividers 7. In the example, this second chain comprises eleven dividers by two and the HF oscillator is equipped with a quartz at 4 MHz. The figure also shows that the HF oscillator is capable of being engaged or triggered periodically by the line OS, that the NOR gate 6 receives on its second input a signal BL capable of blocking or unblocking the chain 7 and that said chain can be reset through the RC line. The binary word that is found at the output of the chain 7 consists, in the example chosen, of eleven bits which can be transferred by line 8 into a first memory 9 when a transfer order Tt is given to said memory 9.

The signals OS, BL, RC and Tt come from a logic servo control circuit 10 itself controlled by signals 11 to 15 coming from the division chain 3. As will appear below, the binary content memory 9 is used, during the normal running of the timepiece, to adjust the division ratio of the chain of dividers 3, either directly or indirectly via a comparison circuit 16 which compares the content of the first memory 9 with the content of a second memory 17.

In order to improve the precision of the timepiece, without increasing its consumption, a system is proposed according to the invention where the frequency controlled by a BF quartz is periodically controlled by a frequency controlled by an HF quartz more stable in temperature. Means are implemented so that outside of the control periods the HF circuits are triggered.

ce qui est incompatible avec une durée de vie raisonnable de la pile.In patent CH 570 651, already cited above, the pulses of the frequency to be corrected are counted during a standard period external to the watch. As here, we want this standard signal to be inside the watch, we could consider replacing the external standard with an internal standard supplied by an HF quartz. However, as the adjustment precision is proportional to the number of pulses counted during the standard period, the latter would be long for a low frequency to be adjusted. It would therefore follow that the operating time of the HF oscillator and the dividers which follow it would be much too long and would result in excessive consumption for the adjustment precision considered. For example and to fix ideas, if we want to discern a frequency difference of 0.06 ppm or 1/2 ²⁴ (which allows a walking precision of 31.1 - 10 ⁶ seconds / year x 0.06 - 10- ⁶ = 1.86 seconds / year), it will take 2 ²⁴ reference pulses. However, if it is the number of cycles of the LF oscillator (32 kHz = 2 ¹⁵ ) which is measured during the reference period provided by the HF oscillator, the measurement will last ₂ ² 4/2 ¹⁵ '= ₅₁ 2 seconds. If we admit, on the other hand, that the consumption of the HF oscillator plus that of the division chain is of the order of 15 _f A (oscillator only 5 pA) and that in this case we neglect the consumption due to the start-up time of the oscillator (approximately 2 s), the increase in average consumption caused only by the measurement system and for a control period of 1024 s will be

which is incompatible with a reasonable battery life.

ce qui est parfaitement acceptable. En fait, le gain théorique sur la consommation se trouve être dans le rapport des fréquences en présence soit f(HF) / f(BF), ici égal à 4 - 10⁶ / 32 - 10⁴ = 128, alors que le gain réel n'est que de 7,5 / 0,068 = 110 car on doit tenir compte de la consommation de l'oscillateur HF pendant son temps de démarrage.According to the invention and to reduce the operating time of the HF circuits, a period controlled by the frequency is measured, by means of reference pulses generated by the HF oscillator or quartz. BF to be corrected. The difference is measured by counting the number of reference pulses contained in the period to be corrected. In other words, the division chain on which the measurement is made is not the one whose value must be corrected, but the reference measured by means of a false period. Using the example given in the previous paragraph and for the same required accuracy of 0.06 ppm, we will measure during a false LF period a number of reference cycles supplied by an HF quartz (for example 4 MHz = ₂ ²² ) and the measurement will last 2 ^{24/2 22} = 4 seconds. Assuming the same servo period of 1024 s, the same consumptions of 5 µA for the HF oscillator alone, 15 µA for the HF circuits and a start-up time of 2 s for the oscillator, increasing the average consumption caused by the measurement system will be reduced to

which is perfectly acceptable. In fact, the theoretical gain consumption is found to be in the ratio of frequencies in the presence or f (HF) / f (BF), here equal to 4 - 10 ^6/32 - 10 ⁴ = 128, while the actual gain is only 7.5 / 0.068 = 110 because we must take into account the consumption of the HF oscillator during its start-up time.

As we have seen, the system which is the subject of the invention requires a BF oscillator which is the time base used for displaying the time for which it is a question of correcting the imprecision and an HF oscillator which serves to reference for. making this correction. Each of the oscillators is followed by a chain of frequency dividers and we consider here a purely digital correction system. If we designate by X (in ppm) the total frequency deviation presented by the LF oscillator and by Y (in ppm) the desired precision, the number of necessary adjustment steps N ₁ will be N ₁ = X / Y. The number of bits necessary to carry out these steps will be d ₁ = log ₂ N ₁ , d _l giving the number of dividing stages of the HF chain. As regards the adjustment period, the number of steps N ₂ to consider for a step to have Y ppm will be N ₂ = 1 / Y and the number of bits necessary, representing the number of divider stages of the chain BF will be d ₂ = log ₂ N ₂ . Finally, if we designate by f (BF) min the lowest frequency that the LF oscillator can have, the total adjustment period (inhibition) in seconds will last 2 ^d2 / f (BF) min. An application to a concrete example of relationships that just given will be discussed later.

• 1) Au temps t₀, l'oscillateur HF est mis en marche (signal OS) pendant une durée t₁- t₀ assez longue pour permettre sa stabilisation (2 s).
• 2) Au temps t_l, la chaîne de division HF est débloquée (signal BL) en même temps que lui est supprimée sa remise à zéro (signal RC). Dès cet instant t_l, on procède à la mesure proprement dite en comptant le nombre d'impulsions de référence délivrées par la chaîne HF et ceci pendant une période prédéterminée t₂-t₁ fournie par le diviseur BF (4 s).
• 3) A la fin de ladite période prédéterminée, au temps t₂, on b1 oque les diviseurs HF (signal BL) et on stoppe l'oscillateur HF (signal OS).
• 4) Après un court laps de temps de durée t₃ - t₂ (30 us) qui tient compte du temps de propagation de l'effet de blocage, on transfert au temps t₃ le contenu des diviseurs HF dans la première mémoire 9 (signal Tt) pendant une durée t₄ - t₃ (60 µs).
• 5) Enfin, après une courte durée de sécurité t₅ - t₄ (30 µs), on remet à zéro la chaîne HF au temps t₅ (signal RC).

We will now refer to the diagram in FIG. 2 which explains the operation of the system. The chain 3 delivers at the output of its last divider a servo signal fa which is transmitted for example every seventeen minutes (1024 s). Each control cycle fa begins with a measurement cycle fm which is broken down into five successive phases (see time lines t of the diagram):

• 1) At time t ₀ , the HF oscillator is switched on (signal OS) for a time t ₁ - t ₀ long enough to allow its stabilization (2 s).
• 2) At time t _l , the HF division chain is released (signal BL) at the same time as its reset is deleted (signal RC). From this instant t _l , the actual measurement is carried out by counting the number of reference pulses delivered by the HF chain and this for a predetermined period t ₂ -t ₁ supplied by the LF divider (4 s).
• 3) At the end of said predetermined period, at time t ₂ , b1 oque the HF dividers (signal BL) and stop the HF oscillator (signal OS).
• 4) After a short period of time t ₃ - t ₂ (30 us) which takes into account the propagation delay of the blocking effect, the content of the HF dividers is transferred to time t ₃ in the first memory 9 ( signal Tt) for a period t ₄ - t ₃ (60 µs).
• 5) Finally, after a short safety time t ₅ - t ₄ (30 µs), the HF chain is reset to zero at time t ₅ (signal RC).

The same measurement cycle will start again at time t ₆ where the duration t ₆ - t ₀ (1024 s) is found to represent the control cycle.

The values in seconds given above in parentheses are an example and do not limit the scope of the invention for which other values could be chosen without departing from the subject of the invention. The same remark applies to certain numerical values which will be given later.

As shown in FIG. 1, the signals OS, RC, BL and Tt come from the logic circuit of the servo control 10 and are the result of the combination of the signals fa, fm, fos, f _R o and ft coming of the BF 3 chain. These are represented at the top of the diagram in FIG. 2.

Figure 3 shows a possible arrangement to achieve this combination. The diagram presented consists of elementary logic circuits: inverters, NOR and NAND gates, flip-flop, which form the content of block 10 shown in FIG. 1. It contains the signals fa, fm, fos, f _R o and ft applied to the respective inputs 15, 14, 13, 12 and 11. Those skilled in the art will understand, without explanations being given here, how the arrangement of the various logic circuits is made to reach the signals RC, BL, OS and Tt present at the output of the block. In addition to the cycles fa and fm mentioned above, there is the signal fos (4 s) which represents the starting cycle of the HF oscillator and the frequencies f _R o (8 kHz) and ft (16 kHz ) which ensure the transfer times (60 µs) and safety times (30 µs).

It is understood that it is necessary, during the measurement of the reference pulses, to prevent any inhibition. To do this, the inhibition period is determined by the signal fi (whose duty cycle is 1) from the chain 3 and acting on the inhibition command 18 as shown in Figure 1. The inhibition is executed when this signal is in state 0, which is the case for only half a period. At the start of the other half-period during which no other inhibition takes place, periodically corresponds the start of a control period fa which is also the start of a measurement. This coincidence is automatic because the inhibition signal fi is generated by the same division chain 3 which also generates the servo signal fa.

To illustrate what has just been said, we will now take a practical case. A BF quartz is used, the lowest frequency of which is 2 ¹⁵ = 32,768 Hz. To this are added the usual tolerances such as for example the machining precision, the aging and the drift due to the temperature which total 115 ppm. If an accuracy of 0.06 ppm is desired (which, as we saw above, allows a running accuracy of 1.86 seconds / year), the number of necessary adjustment steps N ₁ will be N ₁ = 115 / 0.06 ≅ 1900. To carry out these steps, the number of bits required will be d ₁ = log ₂ 1900 = 11 which is the number of dividers in the HF chain. Regarding the adjustment period, the number of steps to consider for a step to have 0.06 ppm will be N ₂ = 1 / 0.06 - 10 ^-6 = 16.6 - 106 and the number of dividers of the BF chain will be d ₂ = log ₂ 16.6. 10 ⁶ = 24. Finally, since the lowest frequency presented by the LF oscillator is 2 ¹⁵ Hz, the total inhibition period will last 2 ^{24/2 15} = 512 seconds. To the twenty-four dividers of chain 3, necessary for the functioning of the system _teme (the signal emitted by the twenty-fourth acting on the inhibition command 18), is added a twenty-fifth (1024 s) which every seventeen minutes causes a servo cycle to restart.

The diagram in Figure 4 shows what happens during the duration of the period to be corrected. This period, originating from the chain B _F , begins at time t _{l as} soon as the signal BL goes to state 0 and stops at time t _{2 as} soon as said signal returns to state 1. From time t _l , the HF chain starts to count the pulses emitted by the HF oscillator. FIG. 4 shows the signals present at the output (HF ₁ to HF ₅ ) of five successive dividers of the HF chain (which normally includes eleven in the example cited here). To make the diagram explicit, it will be understood that it was necessary to choose another time scale to represent in superposition the LF period (4 s) and the HF pulses whose lowest frequency, after eleven divisions, is still 4 kHz. . At a certain time (time t _x ), all the HF divisors are at 0 and this before the period to be corrected BL is over. This is due to the fact that an HF quartz with more distant tolerances (for example + 140 to + 4140 ppm) has been chosen than the tolerances for BF quartz (for example +60 to + 100 ppm). From this instant t _x , the HF chain will start a counting cycle again, which will be interrupted at time t ₂ . At this moment, the logical state of all the HF divisors is a measure of the difference separating the moment (t _x ) when all the HF divisors have passed through 0 and that when the period to be corrected ends (t ₂ ). In the figure, the five dividers shown have the binary value 00110 when the chain counting stops. This value is temporarily retained by the chain 7 before being transferred by the line 8 from time t ₃ to the first memory 9, as shown in FIG. 2.

There is now available at the output of memory 9 a binary value corresponding to the difference between the period BF to be corrected and the reference period HF. We will call this value difference BF - HF.

Theoretically, one could imagine that the HF oscillator delivers an exact nominal frequency. In this case, the BF - HF difference could be used to act directly on the inhibition control circuit 4, as is proposed by the Swiss inventories cited above.

In reality, whatever means we take to adjust the HF quartz as close as possible to its nominal frequency, there will always remain a difference between this nominal value and the real value. Furthermore, to simplify the manufacturing operations, one can even think of using very roughly adjusted HF quartz. In this case, we propose to group them by categories. For each of these categories, the difference between the real value produced by the second divider and the nominal value that said second divider would produce if it were supplied by a signal of nominal frequency is measured. This difference or standard value which will be called HF - Nom difference. is introduced once and for all by line 19 in a second memory 17 (which can be a non-volatile memory, if one wishes to keep its information during a battery change). It is arranged so that the output of the memory 17 has a binary value which is expressed with bits of weight identical to those from the first memory 9. It is therefore possible to compare the difference BF - HF with the HF difference - Nom. in a subtractor circuit 16 so as to obtain a binary signal at the output of the subtractor which represents the difference BF - Nom. to act on the inhibition control circuit 4.

We thus managed to fine-tune the progress of the timepiece. This adjustment is made periodically and automatically by means which are internal to the timepiece. No external intervention is necessary except of course that which consists, during the manufacture of the watch, of memorizing once and for all the difference existing between the HF quartz chosen and the nominal frequency that this quartz should give.

It will be noted that the system described is applicable to any type of oscillator. In the case where the drift of the BF oscillator would be greater than that given by a quartz (here 115 ppm), it would suffice to increase the number of dividers of the HF chain. In the current state of the art, however, it would be difficult to envisage an HF oscillator other than the one whose reference frequency would be given by a quartz.

Claims (7)

1. Timepiece comprising a low-frequency oscillator (1) as a time base supplying a first chain (3) of frequency dividers with adjustable division ratio for displaying the time and a high-frequency oscillator (5) supplying a second chain (7) of frequency dividers, characterized in that, periodically, servo means are operated to count in binary form, for a predetermined period (BL) provided by the first chain of dividers, a number d 'reference pulses delivered by the second chain of dividers to produce a binary value (BF - HF) representing the deviation of the first chain from a reference, said value being transferred into a first memory (9) to correct , during normal operation of the timepiece, the division ratio of said first chain of dividers. 2. Timepiece according to claim 1, characterized in that the first chain of dividers comprises an inhibition circuit (2) on which acts said binary value (BF - HF) to adjust its division ratio. 3. Timepiece according to claim 1, characterized in that said binary value (BF - HF) is compared with a standard value (HF - Nom.) Contained in a second memory (17), the result of the comparison ( BF - Nom.) Acting on the first chain (3) of dividers to correct its division ratio. 4. Timepiece according to claim 3, characterized in that said comparison is carried out in a subtractor circuit (16). 5. Timepiece according to claim 3, characterized in that the high-frequency ocillator (5) produces a real signal roughly adjusted around a nominal frequency and that the standard value (HF - Nom.) Contained in the second memory comprises the binary value of the difference between the real value produced by the second chain of dividers and the nominal value that said second chain of dividers would produce if it were supplied by a signal of nominal frequency. 6. Timepiece according to claim 1, characterized in that the control means comprise a logic control circuit (10) whose inputs (11 to 15) are connected to certain outputs (fa, fm, fos, f _R o, ft) of the first chain of dividers, choose _s ies to ensure, in an established order, the starting or stopping of the high-frequency oscillator, the blocking or unblocking of the second chain of dividers, the resetting of said second chain and the transfer of said binary value in the first memory. 7. Timepiece according to claim 6, characterized in that the servo means are arranged to traverse a cycle extending from time t ₀ to time t ₆ in which, at time t _o , corresponding to the state zero of all the dividers composing the first chain (3), the high-frequency oscillator is started (OS), at time t ₁ . the second chain (7) of dividers is activated (BL) to count the reference pulses delivered by the high-frequency oscillator (5) for a predetermined duration t ₂ - t _l supplied by the first chain of dividers, at time t ₂ the second chain of dividers is blocked (BL) at the same time as the high-frequency oscillator (5) is stopped (OS), at time t ₃ the content of the second chain (7) of dividers is transferred (Tt) in the first memory (9) for a duration t ₄ - t ₃ , at time t ₅ the second chain (7) of dividers is set to zero (Rc) and at time t ₆ the same cycle begins again.

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