EP0204851A2 - Electric watch - Google Patents

Abstract

The invention relates to a watch which can be corrected in its time display by a time signal transmitted by radio and having a mechanical, especially analog, time display. It is proposed that the display error be corrected by means of an assigned electronic circuit arrangement, by temporarily accelerating the progression if it is determined from the time signal that the time display is running slow, and by temporarily retarding or even stopping the progression of the hand mechanism if it is determined from the time signal that the time display is running fast. Computer circuits are assigned to the watch with correctable time display, by means of which circuits the nominal time discrepancies determined by the time signal can be converted into the number of pulses to be omitted or taken into account in order to correct the fast or slow running of the watch. The invention is designed principally for application in utility watches. To this end, the structural elements of the circuit arrangements for the radio receiver, for the correction of the time display and for time-keeping on the one hand are assembled with the watch mechanism on the other hand to form a common integrated structural unit which can be fitted in the housings of a wide variety of utility watches. <IMAGE>

Description

The invention relates to an electric watch according to the preamble of claim 1.

The purpose of the invention is to improve the accuracy and the reliability of the time display of clocks in common use.

In electrical time service systems, it is known, depending on a time signal transmitted from the outside, for example from a central station, on the wire or radio path every hour or daily to correct the electrical master clock in its display status, if necessary. For this purpose, a solenoid coil is energized via a circuit arrangement, which thereby acts electro-dynamically on a permanent magnet attached to the pendulum of the master clock and, depending on the switched current direction and current intensity, causes a more or less strong acceleration or deceleration of the pendulum oscillation, so that the present error of a pre- or lag in the time display can be gradually compensated. However, this known arrangement for correcting the time display is less suitable for table and wall clocks in common use. It is spatially expansive and also requires maintenance from time to time. In particular, it cannot be used for table clocks that change according to their location.

The invention is therefore based on the object of creating a clock to correct its deviations for civil use, which is relatively simple in construction and easy for the layman to use.

The invention solves the stated problem by the measures according to the characterizing part of claim 1. Possible further developments and refinements of the invention are covered in the subordinate claims.

The invention is illustrated in the accompanying drawings in the form of exemplary embodiments and explained in the following description.

• Figur 1 die schematische Darstellung eines ersten Ausführungsbeispieles der Erfindung;
• Figur 2 die schematische Darstellung eines zweiten Ausführungsbeispieles der Erfindung;
• Figur 3 ein Uhrwerk nach der Erfindung in schematischer Darstellung in einer Seitenansicht;
• Figur 4 das Uhrwerk in der schematischen Darstellung nach Fig. 3 in einer Ansicht von hinten.

Show it:

• Figure 1 is a schematic representation of a first embodiment of the invention;
• Figure 2 is a schematic representation of a second embodiment of the invention;
• Figure 3 shows a clockwork according to the invention in a schematic representation in a side view;
• Figure 4 shows the clockwork in the schematic representation of FIG. 3 in a view from behind.

1 shows the radio receiver of the watch according to the invention, which preferably receives the time signal wirelessly every hour on the hour via the antenna 1a. The radio receiver 1 is a permanently tuned transistor receiver, which is supplied by the dry battery that also powers the clockwork.

The radio receiver 1 is switched on at the hour by the mechanical clockwork or an electronic control circuit assigned to it from shortly before to shortly after the hour in order to be ready for reception and transmission of the time signal. Continuous operation of the radio receiver 1 is conceivable, but is unsuitable in view of the power consumption associated with it, which loads the common supply battery.

The time signal received by the radio receiver 1 is now fed to the electronic converter 2, through which it is processed and fed to the digital circuits 3 and 4.

The digital circuits 3 and 4 are electronic storage circuits in which the time signal processed by the electronic converter 2 is temporarily stored, specifically the hourly value in the digital circuit 3 and the second value of the time signal in the digital circuit 4. The digital circuits serve to represent the hours and seconds, which are defined by the time signal and which are at the outputs 3a and 4a, respectively are represented as binary bit groups for hour and second.

The digital circuits 3 and 4 now face the outputs 5a of the clockwork 5 and 6a of an electronic counter 6. The outputs 5a are connected by a control device assigned to the clock and emulate the hour display 1-12 of the clockwork 5 in the form of a 4-digit group of bits at the outputs 5a. For example, the hourly numbers 1-12 can be represented by a bundle of 4 lines a - c, which can be assigned by the control device of the clockwork 5 according to a binary code. This assignment changes with the change of each hour display according to the selected code of the control device.

The stepping motor of the clockwork 5 is advanced by the oscillator circuit 8 controlled by the control quartz 7 via the frequency divider 9, preferably at a second rate. Via an output 9c of the frequency divider 9, the electronic counter 6 is preferably also controlled with secondary pulses or advanced in its count. The electronic counter 6 has a counting range of one hour, i.e. So from 36oo seconds. The counting process starts again from 1 after every full hour. Together with the output 9c of the frequency divider 9 connected to the feed line 10, the outputs 9a, 9b of the frequency divider 9 leading to the stepping motor of the clockwork 5 are also pulsed.

The continuation of the second hand of the clockwork 5 thus takes place synchronously with that of the electronic counter 6, only that the second hand makes 6, 6o full revolutions on the dial of the clock 5 during a full counting process of the electronic counter. The count of the electronic counter 6 and the position of the second hand of the clockwork 5 are synchronized with one another in such a way that the counting process of the electronic counter 6 begins at the position 6 ₀ (12) of the second hand of the clockwork 5 and its counting process at the position 59 of the second hand, ie ended at his count of 3599. The count of the electronic counter 6 is shown encoded at the outputs 6a.

The electronic counter 6 can be reset to the initial count for seconds 4 in the event of a time signal arriving every hour or daily on the hour after detection and storage of a deviation via the feed line 17 from the digital circuit. In this way, a constant synchronization between the count of the electronic counter 6 and the time signal can be achieved.

To achieve synchronism between the storage status of the electronic counter 6 and the position of the second hand of the clockwork 5 during commissioning, a preferably manually actuated control contact 11 is now provided, which via a circuit arrangement 12 and leads 13, 14 with the inputs 6b and 9d of the electronic counter 6 and the frequency divider 9 is connected.

The inputs 6b and 9d are so-called control inputs, the electronic counter 6 of which is reset when it is connected, and its counting process and the stepping motor 5 continue to be interrupted for the duration of the connection.

The synchronization is carried out in such a way that when position 6 ₀ (12) is reached, the setting button 11, which is arranged at a location accessible on the watch case, is actuated by the second hand of the clockwork 5. The clockwork 5 stops immediately. The minute and hour hands of the clockwork 5 are now set to the pointer position corresponding to the synchronization time, for example by means of an adjusting button. When the synchronization occurs, for example after the telephone, the actuation of the control contact 11 is ended. The second hand of the clockwork 5 continues its step movement and the electronic counter 6 starts its counting process from zero. For the time being, the second hand of the clockwork 5 and the electronic counter 6 remain tied. The same applies analogously to the minute hand.

Comparator circuits 15, 16 for the hours (15) and the seconds (16) are now assigned to the digital circuits 3 and 4 on the one hand and the clockwork 5.5a and the electronic counter 6 on the other hand.

The comparator circuits 15, 16 monitor the digital assignments of the outputs 3a, 4a and 5a, 6a. They take effect at the moment of the incoming time signal from the radio receiver 1 and determine a possible deviation between the time signal and the pointer position of the clockwork 5. The monitoring is carried out separately according to hours (15) and seconds (16). Is determined, a deviation in comparing the hours (15), the determined difference is transferred via the feed line 18 to a computing stage 19, which multiplies the determined difference hours with 36 ₀₀ to reach a second value. The product is forwarded digitally via the feed line 20 to an addition stage 21, which adds the product of the computer stage 19 to the second difference determined in the comparator circuit 16, which is fed to the addition stage 21 in digital form via the feed line 22. Under normal operating conditions, however, only seconds values from the comparator circuit for seconds 16 are generally transmitted to the addition stage 21, if a deviation can be determined at all.

In this case, a zero product of the multiplier circuit 19 is added to the second values transmitted by the comparator circuit 16 in the addition stage 21, and the sum is then transmitted to a further computer circuit 24 via the feed line 23.

The purpose of the computer circuit 24 is to use the determined deviation of the time display to define that number of pulses which is to be temporarily applied to the stepper motor - in the case of a detected retardation with an increased frequency and in the case of a detected advance with a reduced frequency - in order to correct the deviation .

• a) bei Voreilung:
  
  wobei je nach Anzahl der erfaßten Potenzglieder eine mehr oder weniger genaue Ermittlung der Impulszahl n_K erfolgt. Eine genaue Ermittlung der Impulszahl n_K ergibt sich aus der Konvergenz der vorstehenden Potenzreihe
  
  oder aus einem dieser gleichwertigen mathematischem Ausdruck
• b) bei Nacheilung:
  
  wobei sich auch hier die genaue Anzahl der Impulse n_K aus der Konvergenz der vorstehenden Potenzreihe ergibt:
  
  oder aus einem dieser gleichwertigen mathematischem Ausdruck Hierbei bedeuten jeweils:
  • T_f der Wert der festgestellten Abweichung
  • f_N die normale Fortstellfrequenz des Schrittmotors (5)
  • f_K die erhöhte bzw. verringerte Fortstellfrequenz des Schrittmotors (5) (Korrekturfrequenz).

This pulse number n _K , which is to be transmitted temporarily with a correction frequency, is determined by the computing circuit using the following approach:

• a) with advance:
  
  depending on the number of power elements detected, a more or less precise determination of the number of pulses n _K takes place. A precise determination of the pulse number n _K results from the convergence of the power series above
  
  or from one of these equivalent mathematical expressions
• b) in case of lag:
  
  the exact number of pulses n _K resulting from the convergence of the power series above:
  
  or from one of these equivalent mathematical expressions:
  • T _{f is} the value of the deviation found
  • f _N the normal continuation frequency of the stepper motor (5)
  • f _{K is} the increased or decreased output frequency of the stepper motor (5) (correction frequency).

As can be seen from these formulas, depending on the direction of the discrepancy found - whether leading or lagging - the difference T _{f is converted} differently to the number of pulses n _K. The values of the deviation T _f on pulse numbers n _K implemented by the computer circuit 24 in accordance with these formulas are stored in a correction memory 25.

The different correction frequencies f _K are expediently taken from stages of the frequency divider 9, so that the correction frequencies are in a ratio of 2 ⁿ to the normal extension frequency f _{N of} the stepping motor (5).

For example, for the purpose of correcting a lag in the time display, a frequency that is 2 ² or 2 ³ higher is advantageously tapped at the frequency divider 9, while for correcting an advance a frequency that is lower by a factor of 2 ¹ or 2 ^{2 is} tapped at the frequency divider 9, the divider stages of which are expanded accordingly for this purpose. Tapping the correction frequencies f _K from divider stages of the frequency divider 9 other than the stage corresponding to the normal propagation frequency f _N has the advantage, among other things, of the synchronicity of the individual frequency pulses of the individual divider stages in relation to one another.

This synchronicity is important for the switching processes from the normal continuous frequency f _N to the correction frequencies f _K and vice versa.

As the frequency is increased for the purpose of continuing a lag, the pulse-pause ratio of the pulse is expediently changed, with the aim of increasing the pulse length. This is advantageously done in that outputs of the frequency divider stages are used for controlling the stepping motor (5) without superpositions with the outputs of frequencies which are higher in frequency. In this way, the greatest possible pulse width is achieved.

To control and process the correction processes, the correction network is assigned a correction circuit 26, via which the functional sequences can be determined.

A sign discriminator circuit is assigned to the comparator circuits 15, 16. The sign signal, which characterizes the direction of the deviation, is transmitted to the correction circuit 26 via the feed line 27. From there, the computer circuit 24 is instructed via the feed line 28 by which parameter the absolute second value of the deviation transmitted via the feed line 23 is to be multiplied before it is stored or stored in the correction memory 25.

The correction circuit 26 also determines the type of the correction frequency f _K ) which - depending on the sign criterion transmitted via the feed line 27 - is to be effective for the upcoming correction process.

After the correction frequency f _{K has been switched} on to the stepper motor (5), the storage of the correction memory 25 is calculated via the feed line 29. After the number of n _K correction pulses determined by the assignment in the correction memory 25 has been administered, the correction circuit 26 switches the stepping motor (5) back to the normal value of the stepping frequency f _N , with which the operation of the stepping motor (5) is continued.

Correcting a lead T _F by pulsing the stepping motor (5) with a lower frequency f _K than the normal indexing frequency f has the advantage that an interruption in the indexing of the clock is avoided, it is only slowed down. A viewer of the watch during a correction period is therefore not confused by a stationary second hand.

However, in order to correct an advance for a pulse number n _K corresponding to this deviation, it is also possible to completely interrupt the pulsing of the stepping motor (5), ie to switch it off completely. This interruption is also offset against the storage of the correction memory 25. In this case, however, the storage on this becomes a correction of the advance with n _K = T _F. f _N calculated, ie the calculation process for the calculation circuit 24 is easier to carry out than was the case with the previously described methods for correcting an advance. Here, too, the stepping motor (5) is influenced via the correction circuit 26, which is connected to the frequency divider 9 via the feed lines 3 aa, 3 ob. In this case, however, the progression of the second hand of the watch remains interrupted for the duration of the correction process. However, since longer correction processes rarely occur, such a temporary interruption in the advancement of the second hand is acceptable.

After the correction process has ended, the storage on the correction memory 25 is deleted if it has not already been canceled by counting during the calculation. The correction memory 25 is then available again for the next correction process.

Figure 2 shows another embodiment of the invention. While in FIG. 1 the comparator circuit for hours 15 is acted upon directly by the clockwork 5 as a control device via the feed line 5a, the feed line 5a representing a bundle of lines which e.g. of contacts of the clockwork 5 is wired according to a specific digital control code, an electronic counter 40 is provided in FIG. 2, which is connected via a feed line 41 by an hourly actuated control device, e.g. a contact of the clockwork 5, one unit at a time. A reset is made once a day to an initial count, e.g. 1. This reset takes place e.g. shortly before 1 a.m. In this way, synchronization between the hourly state of the clockwork 5 and the electronic counter 4o is achieved once a day, in the event that a deviation between the time display and the electronic counter 4o should have occurred for some reason.

The arrangement according to FIG. 2 has the advantage of a considerably simpler construction of the clockwork 5. For example, only one contact (41) is required for advancing the electronic counter 4o and one contact (42) for its synchronization.

In the arrangement according to FIG. 1, on the other hand, 4 contacts are necessary, for this the pointer position on the comparator circuit for the hours 15 is inevitably displayed, so that no deviation can occur.

In Figures 3 and 4, a clockwork 5 according to the invention is shown as an assembly unit. The actual clockwork 5 is applied to a printed circuit board 51 which also encloses the entire electronics of the electrical clock according to the invention. So on the back 52 of the printed circuit board 51 ferrite coils 53, 54 and a trimmer 55 are provided for fixed tuning. An integrated circuit 56 includes the receiver circuit for the radio receiver 1 together with the required capacitances and resistors.

In the two integrated circuits 58, 57, the electronic circuits for the stepper motor drive and the described correction network of the electric clock according to the invention are combined. The dry cell 59 is used for the common supply of all switching and control circuits. It is held on the rear side 52 of the printed circuit board 51 by battery terminals 59a, 59b and is electrically connected to the circuits.

A control quartz 6o with a capacitance 61, in cooperation with the / integrated circuit 58, serves as the time standard for the electric clock with the aim of maintaining the time keeping between the individual time signals.

They form with the oscillator 7,8 of the clock (Fig. 1, Fig. 2).

Printed conductor tracks 63 are provided on the front side 62 of the printed circuit board 51, with which the described electronic components 53-58; 6 ₀ , 61 are soldered.

On the extension 65a of the hour tube 65, a coding disk 66 is applied, which, in cooperation with contact springs 67 attached to the front 62 of the printed circuit board 51 and connected to conductor tracks 63, form a sliding contact device 7o, which serves as a control device (5, 5a; 42).

Here, the sliding contact device 7o can comprise a plurality of contacts 66, 67 representing the time display of the hours immediately after a digital code, which e.g. directly control the comparator circuit for hours 15 (FIG. 1).

However, the sliding contact device 7o can also be used to synchronize the electronic counter 4o via the feed line 42, which is carried out once a day, preferably between 0:00 and 1:00 (FIG. 2).

In the circuit arrangement according to FIG. 2, the clockwork 5 is assigned a further contact, operated once an hour, for the hourly switching of the electronic counter 4o, which is connected to the latter via the feed line 41.

This contact cannot be seen in FIGS. 3 and 4, it is expediently arranged inside the clockwork 5 and actuated there via a minute shaft (68).

On the hour tube 65, the minute wave 68 and the second wave 69, the hour, minute and second hands (not shown) serving for the time display are applied.

According to an expedient embodiment of the invention, the printed circuit board 51 (FIGS. 3, 4) can also be designed as a substrate plate of a thick-film circuit, the electronic circuits and components enclosed in the integrated circuits 56 to 58 in the embodiment according to FIGS the thick film circuit are detected.

According to another expedient embodiment of the invention, the correction network of the watch is controlled by a microcomputer, which in particular takes on the function of the correction circuit 26. The functional sequence of the correction game is controlled via a program entered into the microcomputer, and one or the other component of the correction network can also be included in the computer program with regard to its function. In particular, the function of the computing circuits can be taken over by the microcomputer and its peripherals.

A small ferrite rod antenna added to the watch can be used as the antenna for the receiving part 53-56 of the radio receiver 1 of the watch according to the invention, which antenna is attached to the printed circuit board 51 and is also connected to the conductor tracks 63 thereof. In the case of metal cases, a conductive connection between the input circuits of the receiver circuit (1) and the metal parts of the watch case is sufficient to achieve a sufficient input level.

According to a further embodiment of the invention, a time switching device is assigned to the electric clock, which briefly switches on the time signal receiver, in particular radio receiver 1, for the upcoming time signal transmission until the end of the time signal transmission. In this way, a noticeable saving in electricity is achieved with the common supply battery 59.

It is expedient to assign this time switching device to the clockwork 5, since the drive by the stepper motor (5) ensures sufficient reserves of force for / actuating a switch. This assignment also has the advantage that the switch is inevitably synchronized with the pointer position and deviations or incorrect positions cannot occur from this side. This energy-saving, short-term switch-on has the disadvantage, however, that if larger time deviations occur, e.g. 30 minutes or more, the clock can no longer be activated by the clock.

Such deviations occur only rarely, e.g. after a battery failure or battery change, but they must then be correctable.

For this purpose, according to the invention, a further, electronically operating time switch device is assigned, which becomes effective over a longer period of time when the clock is no longer connected to the time signal.

According to FIG. 1, a feed line 5c is provided for this purpose, which leads from the clockwork 5 to a logic circuit 46. Via this logic circuit 46, the radio receiver 1 is switched on via the feed line 46a shortly before to shortly after the time signal, with the endeavor that the radio receiver 1 is ready for operation and reception when the time signal arrives.

An electronic counter 45 is continuously switched by the clockwork 5 every hour via a line bundle 5b. Each time the time signal is received, the electronic counter 45 is reset by the comparator circuit for the hour 15 via the lead 15a. If there is no more signal reception because the radio receiver 1 is no longer connected in a character-synchronized manner due to larger deviations in the time display, the counter 45 reaches an increased count, which switches on the radio receiver 1 via the feed line 4Sa, the logic circuit 46 and the feed line 46a initiates and maintains for a longer period of time, as long as until another time signal reception and thus a synchronization of the time display from the clockwork 5 and thus also a reset of the time switching device 45 can occur.

In the circuit arrangement according to FIG. 2, the electronic counter 45 can be controlled further via a feed line 41a from the pulse line 41 of the clockwork mechanism 5, which also controls the electronic counter 40.

The circuit diagrams according to FIGS. 1 and 2 are schematic diagrams in which only the modules necessary for understanding the function are listed. Less significant details of the circuits have not been shown for the sake of clarity.

The clock according to the invention is independent of the position. All the circuit arrangements required for the corrective measures can be combined with the clockwork to form a closed structural unit, which simplifies the clock assembly and the clockwork also for smaller clocks, e.g. Alarm clock and style clocks, can be used.

Only a few contacts are required on the clockwork to display the entire time display (seconds, minutes and hours) as electrical data, reducing interference and, above all, reducing costs.

Claims (30)

1. The time independently displaying electric clock with analog mechanical time display, preferably by pointer-operated pointer, which can be adjusted by a time signal transmitter, in particular a radio transmitter wirelessly administered time signals in the event of a deviation in the time display to the correct display status, with an assigned circuit arrangement an advance of the time display determined when the time signal is transmitted is delayed and, if the delay is determined, there is an acceleration in the continuation of the device for the time display, characterized in that that the watch has a control device (5a; 4 ₀ , 41; 65a, 66, 67) which can be controlled by the clockwork (5) and which shows the hands 1 - 12 of the hour hand at n outputs (Sa, 4oa) in the form of a coded digital electrical signal assigned. 2. Electric clock according to claim 1, characterized in that the time display of the clock is actuated by a stepper motor (5) controlled by an electronic oscillator (7, 8) via a frequency divider (9); that for the electrical representation of the pointer position of the minute and hour hands of the clock (5) a further control device in the form of its count at outputs (6a) as a coded, digital electrical signal representing electronic counter (6) is provided, which the minutes and hours of counts each opened hour after seconds, and is associated with a frequency divider (9) for controlling the electronic oscillator (7, 8) which also serves to continue the electric stepping motor (5). 3. Electric clock according to claim 2, characterized in that the adjustable by the clock for digital reproduction of the time display after hours and seconds control devices (5a, 65a - 67; 6), each of the time signal generator (1) adjustable digital circuitry (3, 4th ) are assigned, by means of which the transmitted time signal can also be represented digitally in terms of hours (3) and seconds (4) at outputs (3a, 4a). 4. Electric clock according to claim 3, characterized in that the adjustable by the clock control devices (5a, 65a - 67; 6) and the associated, from the time signal (1) adjustable circuitry (3, 3a; 4, 4a) comparator circuits ( 15, 16) for the hours (15) and the seconds (16) are assigned, by means of which, from the counts of the control devices (5a, 65a-67; 6) on the one hand and the digital circuit arrangements (3, 4) on the other hand, those at the moment of When the time signal arrives, there is a discrepancy between the time signal and the time display. 5. Electric clock according to claim 4, characterized in that the comparator circuits (15, 16) is assigned an electronic sign discriminator, by which, depending on the direction of the detected deviation, an output signal representing the sign (27) can be administered. 6. Electrical clock according to claim 4 or 5, characterized in that the determined deviation of the time display from the time signal is recorded in an electronic correction memory (25). 7. An electrical clock according to one of claims 1-6, characterized by such a logical or functional combination of the circuit arrangements (5, Sa; 6, 6a; 3, 3a; 4, 4a) which are concerned with the determination, storage and processing of an existing deviation ; 15, 16; 19, 21, 24, 25) of the clock with each other or with an associated correction circuit (26) and the control circuit (7, 8; 9) for the stepper motor (5), that when the lagging movement of the clockwork mechanism is found the stepper motor (5) has a step frequency that is higher than the normal step frequency can be extended and that the pulse sum additionally administered compared to the normal step sequence of the stepper motor of this increased step frequency can be offset against the occupancy of the correction memory (25), and that after administration of an additional pulse sum corresponding to the occupancy of the correction memory (25) to the stepper motor (5) whose step frequency can be reset to the normal value. 8. Electrical clock according to one of claims 1-6, characterized by such a logical or functional combination of the circuit arrangements (5, Sa; 6, 6a; 3, 3a; 4, 4a) which are concerned with the determination, storage and processing of an existing deviation ; 15, 16; 19, 21, 24, 25) of the clock with each other or with an assigned correction circuit (26) and the control circuit (7, 8; 9) of the stepper motor (5), that when the advance movement of the pointer mechanism has been determined Watch the stepper motor (5) can be acted upon with a step frequency, which is either reduced or equal to zero compared to the normal frequency and that the sum of pulses not administered compared to the normal step sequence of the stepper motor (5) can be offset against the occupancy of the correction memory (25) and that hei one of the error memory sum of the step motor (5) corresponding to the assignment of the correction memory (5) whose step frequency can be reset to the normal value. 9. Electric clock according to claim 2, characterized. that a manually operable control contact (11) is provided on the clock, which is connected via a circuit arrangement (12) to the electronic counter (6) and to the control and drive circuit (7, 8; 9) of the stepping motor (5) that the electronic counter (6) is reset and the pulsing of the stepping motor (5) is prevented while the actuating contact (12) is actuated. 1 ₀ . The electric watch according to claim 1, characterized in that the control device is formed for the hour by an adjustable electronic time meter (4 ₀₎ provided by the movement (5) of the clock associated with the first switching device (5, 41) every hour by one unit fortstellbar and can be set to a specific count by a second switching device (5, 42) assigned to the clockwork (5) of the clock. 11. An electric watch according to claim 1, characterized in that the control device assigned to the watch for the hour is a switching device (65a, 66, 67) through which the coded digital signal (5a) representing the display status of the hour hand can be administered at n-outputs is. 12. Electrical clock according to claim 1 ₀ or 11, characterized in that the switching device by the clockwork (5, 65, 65a) of the clock operable contacts (66, 67) is formed. 13. Electric clock according to claim 12, characterized in that the contacts are designed as sliding contacts (67) which are assigned to the conductor tracks of a printed coding disk (66) and which are movable relative to one another by the clockwork (5). 14. Electric clock according to claim 4, characterized in that the comparator circuit for the hours (15) is assigned a computer circuit (19) by which the deviation of the hours determined by the comparator circuit (15) can be multiplied by 3600. 15. Electrical clock according to claim 14, characterized in that the comparator circuit for the seconds (16) and the computer circuit (19) is assigned an addition circuit (21) through which the two determined second values of the deviation can be added. 16. Electric clock according to one of claims 4, 14 and 15, characterized in that a computer circuit (24) is assigned, by means of which the value of the time deviation Tf determined after seconds with a lag with the factor

or with lead by the factor

each time one or more terms of this power series can be multiplied by the number n _{K of} the pulses required for the correction the correction frequency f _K to move, where f _{N is} the normal Fort adjusting frequency and f _K is the increased or decreased Fort adjusting frequency of the stepping motor (5). 17. Electric clock according to claim 16, characterized in that the factor of the computer circuit when lagging through the convergence

and in advance by convergence

is formed. 18. Electric clock according to claim 3 or 4, characterized in that the adjustable by the time signal (1) digital circuit arrangement for the hour (3) by an absolute hour signal transmitted by the time signal to the relevant hourly value and the adjustable by the time signal (1) digital Circuit arrangement for the second (4) can be set to a fixed second value by a relative second signal transmitted during a time of the incoming time signal. 19. Electric clock according to claim 7 or 8, characterized in that the step frequency of the stepper motor (5) can be changed by a factor of 2 ⁿ and that with the switching of the step frequency of the control pulses for the stepper motor (5) to a higher correction frequency (f _K ) on the pulse generator (9), the pulse-pause ratio of the control pulses is switched to a percentage-larger pulse width. 2 ₀ . Electric clock according to one of Claims 1 to 19, characterized in that a microprocessor circuit is used to carry out the individual control processes within the correction network (9, 25, 26). 21. An electric watch according to claim 2, characterized in that the electronic counter (6) can be continued in steps of a second and has a counting range of 3600. 22. Electrical clock according to claim 2, characterized in that the electronic oscillator (7, 8) is a quartz oscillator (7). 23. Electrical clock according to claim 1 or 2, characterized in that the oscillator (7, 8) with frequency divider (9) and stepper motor (5), the time signal receiver (1) and the correction network (9, 25, 26) has a common supply battery (59) is assigned. 24. Electrical clock according to one of claims 1-23, characterized in that the individual circuit groups of the clock are combined to form one or more integrated circuits (56-58) which together with the receiver circuit (53-56) for the time signal on one common printed circuit board (51) carrying the clockwork (5) are applied. 25. Electrical clock according to claim 24, characterized in that the common supply battery (59) on the printed circuit board (51) is applied. 26. An electrical watch according to claim 24, characterized in that the integrated circuits (56-58) are at least partially designed as a thick film circuit applied to the printed circuit board (51) forming the substrate. 27. Electrical clock according to claim 24, characterized in that on the printed circuit board (51) of the clockwork (5) a ferrite antenna is arranged and connected to the conductor tracks. 28. Electrical clock according to one of claims 1 - 27, characterized in that the electrical clock is assigned a time switching device (5, 5c) by which the receiver circuit (1) can be switched on from shortly before to shortly after the arrival of the time signal. 29. An electrical clock according to claim 28, characterized in that the clock is an electrical counter circuit (45) which can be switched on by a time pulse generator (5, 5b; 5, .41, 41a) and can be switched back by the time signal (1 - 3, 15, 15a). , is assigned, by means of which the receiver circuit is continuously switched on after reaching a certain count when the time signal has not arrived. 3 ₀ . Electric clock according to claim 28, characterized in that the time switching device (5c) is assigned to the clockwork (5) and can be actuated by it.

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