EP1114357A1 - Electronic timepiece comprising a time indicator based on a decimal system - Google Patents

Abstract

The present invention relates to an electronic timepiece allowing the display of at least one first time related data item (H1) conventionally based on the Hour-Minute-Second system, and at least one second time related data item (H2) based on a decimal system in which the time is divided at least into thousandths of a day. For this purpose the timepiece according to the present invention includes generating means (14) which, from auxiliary control pulses (IL) originating from the time base (2), allow second control pulses (I2) to be supplied allowing said second time related data item (H2) to be formed and displayed.

Description

 ELECTRONIC TIMEPIECE HAVING A TIME INDICATION

BASED ON A DECIMAL SYSTEM

The present invention relates to an electronic timepiece allowing the display of several time indications. More particularly, the present invention relates to a timepiece allowing the display of at least a first and a second time indication, the first time indication being based on the Hour-Minute-Second system (hereinafter HMS) .

It is already known from the prior art, electronic timepieces allowing the display of a plurality of time indications. These timepieces, commonly known as "universal timepieces", are typically provided to allow the display of a time indication representative of universal time and one or more time indications representative of local time corresponding to different time zones. This multitude of time indications can generate risks of confusion for the user when they are read and generally requires that means be provided making it possible to clearly identify what each of the time indications displayed relates to.

An object of the present invention is thus to propose an electronic timepiece allowing the display of at least a first and a second time indication, and by means of which the user can not clearly and quickly identify and differentiate the time indications. displayed.

To this end the present invention relates to an electronic timepiece allowing the display of at least a first and a second time indication, said first time indication being based on the Hour-Minute-Second system, this piece of timepiece comprising a time base delivering pulses to a frequency divider circuit comprising N binary division stages and delivering first control pulses making it possible to form and display said first time indication, this timepiece being characterized in that said second time indication is based on a decimal system in which time is divided at least into thousandths of a day, this timepiece further comprising generation means adapted to deliver, from auxiliary control pulses from said base of time, second control pulses making it possible to form and display said second time indication.

The solution recommended by the present invention thus makes it possible to clearly differentiate the first time indication from the second by the fact that the first and second time indications are based on different systems.

Indeed, the conventionally used H-M-S system consists in dividing the day into 24 hours, 1 hour being divided into 60 minutes, and 1 minute into 60 seconds. A division of time based on the decimal system consists in return of dividing the day, no longer according to the conventional scheme mentioned above, but successively, in tenths of a day (equivalent to 2.4 hours or 144 minutes), themselves divided into hundredths of a day (equivalent to 14.4 minutes or 864 seconds), then in thousandths of a day (equivalent to 86.4 seconds), etc. In particular, by choosing a division of time in thousandths of a day, the second time indication requires only three digits ("000" to "999") to be displayed and is thus clearly distinguished from a conventional time indication based on the system. HMS typically displayed in "HH: MM" format. The risks of confusion when reading the time indications are thus greatly reduced.

The atypical format of the second time indication is for example particularly suitable for displaying a universal time to which the user can clearly refer without confusing it with a conventional time indication relating to the time zone in which he is located.

The decimal system is also an interesting alternative to the H-M-S system conventionally in force because it eliminates the conversion problems inherent in the H-M-S format. This alternative is moreover more logical and comprehensible for the already customary user of the decimal system.

In order to form a time indication based on the HMS system, electronic timepieces commonly comprise a time base, typically a quartz oscillator delivering pulses at a determined frequency equivalent to a binary power, for example 32768 Hz. A circuit frequency divider, composed of a succession of N binary division stages (flip-flops) connected in cascade, is coupled to the time base so as to deliver control pulses whose frequency is reduced by a factor of 2. Typically, this frequency divider circuit is composed of N = 15 binary division stages, so that the frequency of the pulses delivered by the time base is reduced to 1 Hz. In electronic timepieces allowing the display of several separate time indications, these control pulses are thus used to control the respective displays of these time indications.

In order to form the second time indication based on the decimal system chosen, it is a priori possible to periodically perform an arithmetic operation of conversion of a conventional time indication based on the H-M-S system. This trivial solution consists, in other words, in providing conversion or calculation means dedicated to this task. However, it will be noted that this solution is not suitable for use in a timepiece because it will preferably be sought to provide means making it possible to directly generate control pulses making it possible to form and display the second time indication based on the system. decimal.

In order to produce control pulses making it possible to form a time indication based on a decimal system in which time is divided at least into thousandths of a day, it is necessary to generate these at least at a frequency of 1 / 86.4 Hz or a decimal multiple of this frequency, i.e. 1 / 8.64 Hz for a division into ten thousandths of a day, 1 / 0.864 Hz for a division into one hundred thousandths of a day, etc. In practice, it will be chosen to generate the second control pulses either at a frequency of 1 / 86.4 Hz or at a frequency of 1 / 8.64 Hz, higher frequencies can nevertheless be chosen depending on the case.

A trivial solution to this problem consists in providing an additional time base making it possible to deliver pulses at a specific frequency corresponding to a multiple of the desired frequency, for example 10O00 Hz. A frequency divider circuit having for example an equivalent division ratio at 86,400 would thus generate control pulses at a frequency of 1 / 8.64 Hz. This trivial solution thus involves the use of two chains of distinct divisions (time base + frequency divider circuit) to display the first and second time indications. We will however try to limit the number of components necessary to produce the control pulses and in particular to use only one time base, and preferably a base time clock, that is to say a time base delivering pulses at a frequency equivalent to a binary power.

According to the present invention, the timepiece is advantageously adapted to derive the control pulses from the first and second time indications from the same time base. To this end, it includes generation means adapted to deliver, from auxiliary control pulses originating from the time base, the second control pulses making it possible to form and display the second time indication. The timepiece can thus be particularly adapted to derive, from pulses at 1 Hz from the time base at the output of the frequency divider circuit, second control pulses having a frequency of 1 / 86.4 Hz so to form a second hourly indication to the thousandth of a day, and this despite the fact that the division ratio of these frequencies is not whole. Another advantage of the present invention thus lies in the fact that a single time base is used to generate the different control pulses of the first and second time indications and that it is consequently possible to adapt the electronics of a conventional timepiece so that it allows the display of a time indication based on the decimal system.

Other characteristics and advantages of the present invention will appear on reading the detailed description which follows, given with reference to the appended drawings given solely by way of example and in which:

- Figure 1 shows a simplified block diagram of a timepiece constituting a first embodiment of the present invention;

- Figure 2 shows a simplified block diagram of a timepiece constituting a second embodiment of the present invention;

- Figures 3a and 3b show plan views of timepieces according to the present invention illustrating different possibilities of displaying time indications;

- Figure 4 shows a flowchart of implementation of a first alternative embodiment of the generation means for delivering the control pulses for the display of the time indication based on the decimal system; - Figure 5 shows a second alternative embodiment of the generation means for delivering the control pulses for the display of the time indication based on the decimal system; - Figures 5a to 5c show examples of application of the second alternative embodiment of the generation means 14 illustrated in Figure 5;

- Figure 6 shows a third alternative embodiment of the generation means for delivering the control pulses for the display of the time indication based on the decimal system; and

FIG. 6a presents an example of application of the third alternative embodiment of the generation means 14 illustrated in FIG. 6.

There is shown in Figure 1, in the form of a simplified block diagram, a timepiece constituting a first embodiment of the present invention. This timepiece includes in series a time base 2, typically formed of a quartz oscillator, a frequency divider circuit 4 comprising N binary division stages 4.1 to 4.N and delivering first control pulses l _{1 f} and first display means 6 controlled by the first control pulses l A quartz oscillator typically delivering pulses at a frequency of 32,768 Hz and a frequency divider circuit comprising N = 15 stages of binary division will be used, so that producing first control pulses ^ having a frequency of 1 Hz. In the following description, the above-mentioned numerical values will be used as an example.

The first display means 6 are controlled by the first control pulses ^ and are arranged in a conventional manner so that they allow the formation and display of a first time indication H-, based on the H-M-S system.

The timepiece according to the present invention further comprises generation means 14 delivering second control pulses l ₂ whose frequency is determined by the decimal division adopted, that is for example 1 / 86.4 Hz in the case where a division into thousandths of a day is adopted. These generation means 14 are controlled by auxiliary control pulses l _L from the time base 2 and delivered, in this embodiment, at the output of one of the binary division stages 4.1 to 4.N of the circuit frequency divider 4, this stage being indicated by the reference 4.L and being able to be chosen from the set of binary division stages 4.1 to 4.N. It will be noted that the frequency of the auxiliary control pulses l _{L is} equivalent to the frequency of the pulses delivered by the time base 2 reduced by a factor 2 ^L. Variant embodiments of the generation means 14 will be presented in more detail in the remainder of this description.

In series with the generation means 14, second display means 16 are connected. These second display means 16 are controlled by the second control pulses l ₂ and are arranged so that they allow training and display of a second time indication H ₂ based on the decimal system.

There is shown in Figure 2, in the form of a simplified block diagram, a timepiece constituting a second embodiment of the present invention. This timepiece comprises in series, the time base 2, the frequency divider circuit 4, the first and second display means 6 and 16, as well as the means 14 for generating second control pulses l ₂ .

This timepiece further comprises N ^* additional binary division stages 4.N + 1 to 4.N + N ^* connected following the frequency divider circuit 4. The generation means 14 are controlled by auxiliary pulses of command l _L also issued from time base 2 and delivered, in this embodiment, at the output of the additional binary division stages 4.N + 1 to 4.N + N ^* . It will be noted that the frequency of the auxiliary control pulses l _{L is} equivalent, in this case, to the frequency of the pulses delivered by the time base 2 reduced by a factor 2 ^{N + N *} .

The embodiments illustrated in FIGS. 1 and 2 thus allow the display of a first time indication H ₁ based on the HMS system, and of a second time indication H ₂ based on the decimal system. In these two embodiments, the second control pulses l ₂ are thus generated from auxiliary control pulses l _L coming from time base 2.

It will be noted that the timepiece according to the present invention further comprises correction means allowing the adjustment of the different time indications. These correction means have not been described here and are not shown in FIGS. 1 and 2. Those skilled in the art will nonetheless know how to make these correction means so that they make it possible to adjust each time indication adequately. . It will further be noted that the embodiments shown in Figures 1 and 2 are not limiting. In particular, additional display means can also be provided so as to allow the training and display of additional time indications based on the HMS system or the decimal system.

It will also be noted that a person skilled in the art will be able to produce the display means 6 and 16 in an adequate manner. It will be noted in particular that these can advantageously be produced in the form of an analog display with needles controlled by electromechanical means or in the form of a digital display. By way of example, FIGS. 3a and 3b show plan views of timepieces according to the present invention illustrating different possibilities for displaying the time indications H ^ and H ₂ . As illustrated in FIG. 3a, the first display means 6 of the first time indication H ₁ can be produced in the form of a digital display allowing, for example, the display of the time indication ^ according to a conventional format "HH: MM".

Alternatively, these first display means can for example comprise, as shown in FIG. 3b, first and second hands driven by electromechanical means (not shown) and allowing the display of the hours and the minutes respectively.

The second display means 16 of the second time indication H ₂ are advantageously formed, as illustrated in FIGS. 3a and 3b, of a digital display comprising, in this example, 3 digits so as to allow the display of the second time indication H ₂ in thousandths of a day. These second display means 16 can however also be produced in the form of an analog display with needles driven by electromechanical means in a similar manner to the first display means 6 illustrated in FIG. 3b.

Will now be described with the aid of Figures 4 to 6 different alternative embodiments of the generation means 14 for delivering the second control pulses l ₂ according to the present invention. It will be recalled that, depending on the case under consideration, either for example a division into thousandths (86.4 seconds) or alternatively into ten thousandths (8.64 seconds) of day, the second control pulses l ₂ must be delivered at a frequency of 1 /86.4 Hz or 1 / 8.64 Hz respectively. It will also be recalled that it will be considered in the following description, without limitation, that the time base 2 typically delivers pulses at a frequency of 32,768 Hz so that N = 15 stages of binary division 4.1 to 4.15 are used to deliver the first control pulses ^ at a frequency of 1 Hz.

The auxiliary control pulses l _L are used, according to the present invention, to generate the second control pulses l ₂ . The frequency of the auxiliary control pulses l _L is determined by the binary division stage at the output of which these are delivered. According to the first embodiment described in FIG. 1, this frequency thus equals the frequency of the pulses delivered by the time base 2 reduced by a factor 2 ^L. According to the second embodiment described in FIG. 2, this frequency is equivalent to the frequency of the pulses delivered by the time base 2 reduced by a factor 2 ^{N + N.}

The ratio of division of the frequency of the auxiliary control pulses _L by the frequency of the second control pulses l ₂ defines a numerical value corresponding to the average number of auxiliary control pulses l _L to be counted to generate a control pulse l ₂ . Since the frequency of the pulses delivered by the time base 2 is typically equivalent to a binary power, the division ratio defines a non-integer numerical value due to the decimal division of the day. It will be noted that it is not possible to count a non-integer number of auxiliary control pulses l _L. Consequently, in the context of the present invention, the integers n and n + 1 are respectively defined directly below and above the aforementioned division ratio. These integers n and n + 1 thus correspond respectively to the integers directly lower and greater than the average number of auxiliary control pulses l _L to be counted to generate a control pulse l ₂ .

So that the second control pulses l ₂ are generated at an average frequency corresponding to the desired frequency, for example 1 / 86.4 Hz or 1 / 8.64 Hz, n and n + 1 auxiliary control pulses l _L are thus successively counted according to a determined counting sequence.

This counting sequence is formed by a succession of counting operations of n and n + 1 auxiliary control pulses l _L. The division ratio defined above determines the period as well as the number of counting operations at the end of which the second control pulses ₁₂ are generated at the desired average frequency. This counting sequence is further preferably formed so that the deviations generated during the counting sequence are minimized.

By way of example, in the case where the second control pulses l ₂ are generated at an average frequency of 1 / 86.4 Hz from auxiliary control pulses l _L at 1 Hz, that is to say in the case where the generation means 14 are connected to the output of the last binary division stage 4.N of the frequency divider circuit 4 (according to the first embodiment presented in FIG. 1), the frequency division ratio is equivalent to 86.4. The generation means 14 are thus arranged to successively count n = 86 and n + 1 = 87 auxiliary control pulses l _L.

The division ratio further defines that 5 control pulses l ₂ must be generated during a period of 432 seconds. In this case, the counting sequence, repeated 200 times over a period of 24 hours, is thus formed of a succession of 5 counting operations. In this case, n = 86 and n + 1 = 87 auxiliary control pulses l _L are counted 3 and 2 times respectively during the 432 seconds, so that the average frequency at which the second control pulses are delivered l ₂ is thus equivalent to 1 / 86.4 Hz.

So that the deviations generated during the counting sequence are reduced to a minimum, the 5 control pulses l ₂ are preferably generated according to the following counting sequence:

86-87-86-87-86 In this case, it will be noted that the maximum deviation generated during the counting sequence is thus limited to +/- 0.4 seconds, i.e. of the order of 0.5% of the period of the second control pulses l ₂ .

Similarly, in the case where the second control pulses l ₂ are generated at an average frequency of 1 / 86.4 Hz from auxiliary control pulses l _L at 1/8 Hz, that is to say in the case where the generation means 14 are connected to the output of N ^* = 3 additional binary division stages (in accordance with the second embodiment presented in FIG. 2), the frequency division ratio is equivalent to 10.8. The generation means 14 are thus arranged to successively count n = 10 and n + 1 = 1 1 auxiliary control pulses II- The division ratio further defines that 5 control pulses l ₂ must be generated during a period of 432 seconds. In this case, the counting sequence, repeated 200 times over a period of 24 hours, is thus formed of a succession of 5 counting operations. In this case, n = 10 and n + 1 = 1 1 auxiliary control pulses l _L are counted 1 and 4 times respectively during the 432 seconds, so that the average frequency at which the second pulses are delivered command l ₂ is thus equivalent to 1 / 86.4 Hz.

So that the deviations generated during the counting sequence are reduced to a minimum, the 5 control pulses l ₂ are preferably generated according to the following counting sequence:

1 1 -1 1 -10 -1 1 -1 1 In this case, it will be noted that the maximum deviation generated during the counting sequence is thus limited to +/- 3.2 seconds, i.e. of the order of 4% of the period of the second control pulses l ₂ .

Similarly, in the case where the second control pulses l ₂ are generated at an average frequency of 1 / 8.64 Hz from auxiliary control pulses l _L at 1 Hz, that is to say in the case where the means of generation 14 are connected to the output of the last binary division stage 4.N of the frequency divider circuit 4 (according to the first embodiment presented in FIG. 1), the frequency division ratio is equivalent to 8.64. The generation means 14 are thus arranged to successively count n = 8 and n + 1 = 9 auxiliary control pulses l _L. The division ratio further defines that 25 control pulses ₁₂ must be generated over a period of 216 seconds. In this case, the counting sequence, repeated 400 times over a period of 24 hours, is thus formed of a succession of 25 counting operations. In this case, n = 8 and n + 1 = 9 auxiliary control pulses l _L are counted 9 and 16 times respectively during the 216 seconds, so that the average frequency at which the second control pulses are delivered l ₂ is thus equivalent to 1 / 8.64 Hz.

So that the deviations generated during the counting sequence are reduced to a minimum, the 25 control pulses ₁₂ are preferably generated according to the following counting sequence: 9-8-9-9-8-9-8 -9-9-8-9-9-8-9-9-8-9-9-8-9-8-9-9-8-9 In this case, it will be noted that the maximum deviation generated during the counting sequence is thus limited to +/- 0.48 seconds, ie of the order of 5.5% of the period of the second control pulses l ₂ .

In general, it will be seen that the choice of auxiliary control pulses l _L determines on the one hand the precision with which the second control pulses l ₂ are generated, and on the other hand the size of the registers / counters necessary for counting of auxiliary control pulses l _L.

Different alternative embodiments of the generation means 14 based on the aforementioned principle will now be described.

FIG. 4 presents a flowchart for implementing the generation means 14 constituting a first alternative embodiment according to the present invention. According to this first variant, these generation means 14 can advantageously be produced in the form of an integrated circuit comprising a programmed microprocessor. Those skilled in the art will be able, from the indications provided here, to carry out the programming of the microprocessor, so as to make it execute the functions described.

Referring to the flowchart illustrated in FIG. 4, the counting sequence begins at the block indicated by the reference 400. In block 402, a counter register COMPT is incremented at each auxiliary control pulse l _L. This counter register COMPT comprises a number of bits sufficient to allow the counting of at least n + 1 auxiliary control pulses l _L. By way of example, to allow the counting of n + 1 = 87 auxiliary control pulses l _L , this counter register COMPT comprises at least 7 bits.

A first test is performed at block 404 so as to check whether the value of the counter register COMPT has reached the value n. The counter register COMPT is incremented at block 402 at each auxiliary control pulse l _L as long as the value of the latter is less than the value n, this being indicated by the affirmative output of test block 404.

When the value of the counter register COMPT reaches the value n, represented by the negative output of the test block 404, a second test is then carried out at block 406 so as to check whether the value of the counter register COMPT has exceeded the value n. The negative output of test block 406 leads to the third test indicated in block 408. At this stage, it is checked, according to the counting sequence, whether the counter register COMPT must be stopped at the value n. If necessary, a control pulse l ₂ is generated at block 410, ie after the counting of n auxiliary control pulses l _L. Otherwise, the counter register COMPT is incremented in block 402 and, following the affirmative result of the test executed in block 406, the control pulse l ₂ is then generated in block 410, ie after the counting of n + 1 pulses control auxiliaries

II-

Following the generation of the control pulse l ₂ in block 410, the counter register COMPT is initialized in block 412 and the process begins again in block 400. In order to carry out the test indicated in block 408, a table representative of the counting sequence and consequently comprising as many entries as there are counting operations.

Preferably, this table includes binary values representative of the counting operation to be performed, either for example the binary value "0" if it is necessary to count n auxiliary control pulses l _L or the binary value "1" whether to count n + 1 auxiliary control pulses l _L. In this case, a binary word comprising as many bits as counting operations easily makes it possible to produce the table representative of the counting sequence. However, the use of a table representative of the counting sequence is not necessary in all cases. As will be seen below with the aid of various exemplary embodiments, certain alternatives and simplifications may indeed be envisaged.

It will also be mentioned that the process described above is preferably executed in phase with the current value of the second time indication H ₂ so as to ensure that the counting sequence is not offset with respect thereto. Use will therefore preferably be made of a register containing the value of the second time indication H ₂ being displayed so as to determine which is the appropriate counting operation to be performed.

In particular, in the case where a table is used, the register containing the value of the second hourly indication H ₂ being displayed makes it possible to define an indexing value of the various entries of the table by a simple calculation of the modulo. Modulo obviously means the arithmetic operation giving the remainder of a division by a determined number.

In the case already mentioned above where the second control pulses l ₂ are generated at an average frequency of 1 / 86.4 Hz from auxiliary control pulses l _L at 1 Hz, it will be recalled that the counting sequence is preferably determined so that 5 control pulses l ₂ are generated according to the following counting sequence: 86-87- 86-87-86

This counting sequence can thus be represented by a table with 5 entries, preferably produced using the following 5-bit binary word:

"0 1 0 1 0" Referring again to FIG. 4, the test carried out in block 408 is thus carried out by searching for the corresponding value in the table.

Preferably, a register containing the value of the second time indication H ₂ being displayed, or at least the value (0 to 9) of the thousandths of days displayed, will be used. A modulo-5 operation on the value of this register thus makes it possible to obtain an indexing value (0 to 4) of the table. In this example, an alternative to using a table consists in directly using the result of the modulo-5 operation on the register containing the value of the thousandths of days displayed. It can be seen, in this example, that the counting operations with n = 86 and n + 1 = 87 are alternated. Consequently, it is possible to determine whether to count n auxiliary control pulses l _L by checking whether the result of the modulo-5 operation is even. Respectively, it is determined whether to count n + 1 auxiliary control pulses l _L by checking whether this result is odd. In the case already mentioned above where the second control pulses l ₂ are generated at an average frequency of 1 / 86.4 Hz from auxiliary control pulses l _L at 1/8 Hz, it will be recalled that the counting sequence is preferably determined so that 5 control pulses l ₂ are generated according to the following counting sequence:

1 1 -1 1 -1 0-1 1 -1 1 This counting sequence can thus be represented by a table with 5 entries, preferably produced using the following 5-bit binary word:

"1 1 0 1 1" In this case also, a register containing the value of the thousandths of days displayed will preferably be used, in order to obtain by an operation of modulo-5 an indexing value (0 to 4) of the table. In the case already mentioned above where the second control pulses l ₂ are generated at an average frequency of 1 / 8.64 Hz from auxiliary control pulses l _L at 1 Hz, it will be recalled that the counting sequence is preferably determined so that 25 control pulses l ₂ are generated according to the following counting sequence:

9-8-9-9-8-9-8-9-9-8-9-9-8-9-9-8-9-9-8-9-8-9-9-8-9 This counting sequence can thus be represented by a table with 25 entries, preferably produced using the following 25-bit binary word: "1 0 1 1 0 1 0 1 1 0 1 1 0 1 1 0 1 1 0 1 0 1 1 0 1 "

Referring again to FIG. 4, the test carried out in block 408 is thus carried out by searching for the corresponding value in this table.

Preferably, a register containing at least the value (0 to 99) of the thousandths and ten-thousandths of days displayed will be used. A modulating operation on the value of this register thus makes it possible to obtain an indexing value (0 to 24) of the table.

FIG. 5 illustrates a second alternative embodiment of the generation means 14 making it possible to deliver the second control pulses l ₂ .

As shown in FIG. 5, these generation means 14 comprise a primary counter 141 arranged to count n auxiliary control pulses l _L , and means 142 for inhibiting the primary counter 141. The inhibition means 142 are controlled by the auxiliary control pulses l _L and are located upstream of the primary counter 141 so as to periodically inhibit a determined number of auxiliary control pulses l _L at the input of the latter. The second control pulses l ₂ are delivered to the output of the primary counter 141.

The inhibition means 142 preferably comprise a secondary counter 144 arranged to count m auxiliary control pulses l _L , a detection logic circuit 146 coupled to the different stages of the secondary counter 144 so as to detect k intermediate states of the latter (chosen from states 0 to m-1) during which the auxiliary control pulses l _L are inhibited, as well as an AND logic gate, indicated by the reference 148, comprising 2 inputs, one being inverted and connected to the output of the logic detection circuit 146 and the other receiving the auxiliary control pulses l _L. The inhibition means 142 thus make it possible to periodically inhibit, that is to say during a period when m pulses l _L are delivered, k auxiliary control pulses l _L upstream of the primary counter 141.

When one of the k intermediate states is detected by the logic detection circuit 146, the latter thus sends back an inhibition signal blocking the output of the logic gate AND for the duration of an auxiliary control pulse l _L so that the primary counter 141 does not "see" this pulse and does not count it.

Preferably, the k intermediate states will be chosen so that they are equidistant from each other, this so as to minimize the deviations generated.

In FIG. 5a, a first example of the second variant of embodiment presented in FIG. 5 has been illustrated, applied in the case where the second control pulses l ₂ are generated at an average frequency of 1 / 86.4 Hz from of auxiliary control pulses l _L having a frequency of 1 Hz, ie in the case where the generation means 14 are connected to the output of the last binary division stage 4.N of the frequency divider circuit 4 (in accordance with the first mode shown in Figure 1). It will be recalled that the division ratio between the frequency of the auxiliary control pulses l _L and the frequency of the second control pulses is equivalent in this case to 86.4. The primary counter 141 is thus formed of a counter by n = 86. It follows that 2 auxiliary pulses of command L _L must be inhibited during the period (432 seconds) when 432 auxiliary pulses of command L _L are delivered, that is, for simplicity, 1 pulse out of 216. For this purpose, the counter secondary 144 is formed by a counter by m = 216 and the detection logic circuit 146 is arranged to detect k = 1 intermediate state (chosen from states 0 to 215) of the secondary counter 144 during which an auxiliary control pulse l _L is inhibited upstream of the primary counter 141. During a period of 432 seconds, the primary counter 141 thus "sees" only 430 pulses. 5 control pulses l ₂ are thus delivered to the output of the primary counter 141 during a period of 432 seconds, ie at the average frequency of 1 / 86.4 Hz. The counter by 86 can easily be achieved by means of a 7-bit binary counter arranged to be initialized after 86 impulses. Likewise, the counter by 216 requires an 8-bit counter arranged so as to be initialized after 216 pulses.

In FIG. 5b, a second example of the second alternative embodiment presented in FIG. 5 has been illustrated, applied in the case where the second control pulses l ₂ are generated at an average frequency of 1 / 86.4 Hz from d auxiliary control pulses l _L having a frequency of 1/8 Hz, that is to say in the case where the generation means 14 are connected to the output of N ^* = 3 additional binary division stages (in accordance with the second embodiment presented in Figure 2).

It will be recalled that the division ratio between the frequency of the auxiliary control pulses l _L and the frequency of the second control pulses is equivalent in this case to 10.8. The primary counter 141 is thus formed of a counter by n = 10. It follows that 4 auxiliary command pulses l _L must be inhibited during the period (432 seconds) when 54 auxiliary command pulses l _L are delivered, or, for simplicity, 2 pulses out of 27. For this purpose, the counter secondary 144 is formed in this case of a counter by m = 27 and the detection logic circuit 146 is arranged to detect k = 2 intermediate states of the secondary counter 144 (preferably chosen to be equidistant from states 0 to 26) during which a auxiliary control pulse l _L is inhibited upstream of the primary counter 141. During a period of 432 seconds, the primary counter 141 only "sees" 50 pulses. 5 control pulses l ₂ are thus delivered to the output of the primary counter 141 during a period of 432 seconds, ie at the average frequency of 1 / 86.4 Hz.

In this example, the counters by 10 and by 27 thus require counters 4 and 5 bits respectively.

In FIG. 5c, a third example of the second alternative embodiment presented in FIG. 5 has been illustrated, applied in the case where the second control pulses l ₂ are generated at an average frequency of 1 / 8.64 Hz, ie 25 pulses during a period of 216 seconds, from auxiliary control pulses l _L having a frequency of 1 Hz, that is to say in the case where the generation means 14 are connected to the output of the last stage of binary division 4 .N of the frequency divider circuit 4 (in accordance with the first embodiment presented in FIG. 1). It will be recalled that the division ratio between the frequency of the auxiliary control pulses l _L and the frequency of the second control pulses in this case is equivalent to 8.64. The primary counter 141 is thus formed of a counter by n = 8. It follows that 16 auxiliary pulses of command L _L must be inhibited during the period (216 seconds) when 216 auxiliary pulses of command L _L are delivered, that is, for simplicity, 2 pulses out of 27. For this purpose, the counter secondary 144 is formed by a counter by m = 27 and the detection logic circuit 146 is arranged to detect k = 2 intermediate states of the secondary counter 144 (preferably chosen equidistant from states 0 to 26) during which an auxiliary pulse of command l _L is inhibited upstream of the primary counter 141. During a period of 216 seconds, the primary counter 141 only "sees" 200 pulses. 25 control pulses l ₂ are thus delivered to the output of the primary counter 141 during a period of 216 seconds, that is to say at the average frequency of 1 / 8.64 Hz.

In this example, the counters by 8 and by 27 thus require counters 3 and 5 bits respectively.

It is noted that numerous examples of the second variant embodiment, which cannot all be presented here, can still be produced. It will be noted that the frequency of the auxiliary control pulses l _L defines the precision at which the second control pulses l ₂ are delivered. In fact, the higher the frequency of the auxiliary control pulses l _L , the greater the precision at which the second control pulses l ₂ are delivered. However, it will be noted that this in return involves the use of counters comprising a large number of stages.

FIG. 6 illustrates a third alternative embodiment of the generation means 14 making it possible to deliver the second control pulses l ₂ . As shown in Figure 6, these generation means

14 include a primary counter 241 arranged to count n + 1 auxiliary control pulses l _L , and initialization means 242 ^′ coupled to the primary counter 241. The second control pulses ₁₂ are delivered to the output of the primary counter 241 and are used to control the initialization means 242 so as to periodically initialize the primary counter 241 with a value k corresponding to a complementary number of auxiliary pulses of command l _L. The initialization means 242 preferably comprise a secondary counter 244 arranged to count m second control pulses l ₂ and an initialization circuit 246 coupled to the different stages of the primary counter 241 so as to periodically initialize the latter, that is to say 5 say after m pulses l ₂ have been delivered, with a value k corresponding to the additional number of auxiliary control pulses l _L necessary for the primary counter 241 to deliver the second control pulses l ₂ at the appropriate average frequency.

Thus, periodically after the generation of m pulses of the Remote Control l ₂ , the primary counter 241 is initialized with a value k so as to compensate for the missing auxiliary control pulses l _L.

In FIG. 6a, an example of the third variant presented in FIG. 6 has been illustrated, applied in the case where the second control pulses l ₂ are generated at an average frequency of 1 / 86.4 Hz to 1 5 from auxiliary control pulses l _L having a frequency of 1 Hz, ie in the case where the generation means 14 are connected to the output of the last binary division stage 4.N (4.15) of the frequency divider circuit 4 (in accordance with first embodiment presented in FIG. 1).

It will be recalled that the division ratio between the frequency of the 20 auxiliary control pulses l _L and the frequency of the second control pulses in this case is equivalent to 86.4.

The primary counter 241 is thus formed of a counter by n + 1 = 87. It follows that the latter must be initialized every 432 seconds with a starting value k = 3 corresponding to the complementary number of auxiliary pulses of command l _L. To this end, the secondary counter 244 is formed of a counter by m = 5 and the initialization circuit 246 is arranged to inject the value k = 3 in the first two stages of the primary counter 241 as a starting value.

During a period of 432 seconds, the primary counter 241 thus counts 435 pulses. 5 control pulses l ₂ are thus delivered to the output of the primary counter 241 during a period of 432 seconds, that is to say at the average frequency of 1 / 86.4 Hz.

In this example, the counters par 87 and par 5 require counters 7 and 3 bits respectively.

Finally, it will be noted that several modifications and / or improvements 35 can be made to the timepiece according to the present invention without departing from the scope thereof. It will thus be recalled in particular that additional display means can be provided so as to allow training and the display of additional time indications based on the HMS system or the decimal system.

Claims

1. Electronic timepiece allowing the display of at least a first (H ^ and a second time indication (H ₂ ), said first time indication (H ^ being based on the Hour-Minute-Second (HMS) system, this timepiece comprising a time base (2) delivering pulses to a frequency divider circuit (4) comprising N binary division stages (4.1 to 4.N) and delivering first control pulses (^) making it possible to form and displaying said first time indication (H.,), this timepiece being characterized in that said second time indication (H ₂ ) is based on a decimal system in which time is divided at least into thousandths of a day, this timepiece further comprising generation means (14) adapted to deliver, from auxiliary control pulses (l _L ) from said time base (2), second control pulses (l ₂ ) allowing to train and display said second time indication (H ₂ ).

2. Electronic timepiece according to claim 1, characterized in that said auxiliary control pulses (l _L ) are delivered to an output of one (4.L) of the binary division stages (4.1 to 4.N ) of said frequency divider circuit (4).

3. Electronic timepiece according to claim 1, characterized in that said auxiliary control pulses (l _L ) are supplied to an output of N ^* additional binary division stages (4.N + 1 to 4.N + N ^* ) connected following said frequency divider circuit (4) upstream of said generation means (14).

4. Electronic timepiece according to claim 2 or 3, characterized in that said generation means (14) are arranged to successively count the auxiliary control pulses (l _L ) according to a counting sequence formed by counting operations of n and n + 1 auxiliary control pulses (l _L ) succeeding each other in a determined order so that said generation means (14) deliver the second control pulses (l ₂ ) at an average frequency making it possible to form said second indication hourly (H ₂ ) based on the decimal system, n being an integer directly less than the division ratio of the frequency of said auxiliary control pulses (l _L ) by the frequency of said second control pulses (l ₂ ).

5. Electronic timepiece according to claim 4, characterized in that said operations of counting n and n + 1 auxiliary control pulses (l _L ) follow one another in a determined order so that the second auxiliary control pulses ( l ₂ ) are delivered with minimum deviations.

6. Electronic timepiece according to claim 4 or 5, characterized in that said counting sequence is included in a table comprising as many entries as there are counting operations.

7. Electronic timepiece according to claim 6, characterized in that said table is formed of a binary word in which the binary value "0" indicates that it is necessary to count n auxiliary control pulses (l _L ) and the binary value "1" indicates that n + 1 auxiliary control pulses (l _L ) should be counted.

8. Electronic timepiece according to claim 6 or 7, characterized in that the entries of said table are indexed by means of a register containing a value of said second time indication (H ₂ ).

9. Electronic timepiece according to claim 4 or 5, characterized in that said counting operations of n or n + 1 auxiliary control pulses (l _L ) are determined by means of a register containing a value of said second time indication (H ₂ ).

10. Electronic timepiece according to claim 2 or 3, characterized in that said generation means (14) comprise a primary counter (141) arranged to count n auxiliary control pulses (l _L ), and means for inhibition (142) of said primary counter (141) arranged to periodically inhibit k auxiliary control pulses (l _L ) upstream of said primary counter (141), so that the latter delivers the second control pulses (l ₂ ) to a average frequency for forming said second time indication (H ₂ ) based on the decimal system, n being an integer directly less than the division ratio of the frequency of said auxiliary control pulses (l _L ) by the frequency of said second control pulses (l ₂ ).

1 1. Electronic timepiece according to claim 10, characterized in that said inhibition means (142) comprise a secondary counter (144) arranged to count m auxiliary control pulses (l _L ), a detection logic circuit (146) coupled to said secondary counter (144) so as to detect k intermediate states of the latter, and an AND logic gate (148) comprising 2 inputs, one being inverted and connected to an output of said detection logic circuit (146) and the other receiving said auxiliary control pulses (l _L ), said detection logic circuit (146) returning an inhibition signal blocking the AND logic gate (148) when one of the k intermediate states is detected, so that an auxiliary control pulse (l _L ) is inhibited upstream of said primary counter (141 ).

12. Electronic timepiece according to claim 11, characterized in that said k intermediate states are chosen so as to be equidistant from each other.

1 3. Electronic timepiece according to claim 2 or 3, characterized in that said generation means (14) comprise a primary counter (241) arranged to count n + 1 auxiliary control pulses (l _L ), and initialization means (242) coupled to said primary counter (241) and arranged to periodically initialize said primary counter (241) with a value k corresponding to a complementary number of auxiliary control pulses (l _L ), so that said counter primary (241) delivers the second control pulses (l ₂ ) at an average frequency making it possible to form said second time indication (H ₂ ) based on the decimal system, n + 1 being an integer directly greater than the division ratio of the frequency of said auxiliary control pulses (l _L ) by the frequency of said second control pulses (l ₂ ).

14. Electronic timepiece according to claim 13, characterized in that said initialization means (242) comprise a secondary counter (244) arranged to count m second control pulses (l ₂ ) and an initialization circuit ( 246) coupled to said primary counter (241), said secondary counter (244) supplying every m second control pulses ( ₁₂ ) a signal to said initialization circuit (244) so that said primary counter (241) is initialized with a k value.

1 5. Electronic timepiece according to any one of claims 1 to 14, characterized in that said generation means (14) deliver said second control pulses (l ₂ ) at an average frequency of 1 / 8.64 Hz.

16. Electronic timepiece according to any one of claims 1 to 14, characterized in that said generation means (14) deliver said second control pulses (l ₂ ) at an average frequency of 1 / 86.4 Hz.