DE1673774C - Electronic clock with pointer setting device - Google Patents

Description

The invention relates to an electronic watch with a high-frequency electrical signal emitting Clock generator, a frequency divider connected to it, consisting of several divider stages and a display device controlled therefrom with time hands.

Various clocks of this type are known, for example tower, stand, pocket and even clocks Wristwatches whose accuracy is far greater than that of purely mechanical or electromechanical ones Clocks. In a known watch, there is a high level of accuracy thanks to a second reference clock generator guaranteed, which is switched periodically to the clock and a rate correction device controls in the form of a zeroing device, soft the given by the display device Time display replaced by one corresponding to the time imposed by the clock.

In other known clocks, especially those which should be easily transportable, like pocket watches or wristwatches, depends on the accuracy In contrast, it depends exclusively on the quality of the clock generator used. F.s are extraordinary exact clock known, namely quartz oscillating gates, which can easily be locked into a constant oscillation frequency and with which one can get a Accuracy can be obtained, with the deviations essentially only from the temperature fluctuations depend. The accuracy of such clocks is essentially due to defects in the time display.

In particular if the display device contains an electromechanical converter that is controlled by the Vt) Hi frequency divider coming pulses t'.esUuert is closely related to the above defects

Jessen's insensitivity to harmful external influences to which he may be exposed (e.g. Accelerations or external magnetic fields) together.

An improvement in the accuracy of such clocks is therefore only possible under the condition that special care is taken in the construction of the display device What is expended is particularly skilled craftsmanship and high constructive Requires effort.

The object of the invention is to avoid the disadvantages set out above one resulting in particular from mechanical inadequacies in the time display device To determine deviation in the course of the display device from the correct value and for the time display switch off or make it ineffective.

This task is given by the claim I specified Invention solved.

Appropriate and advantageous equipment This invention can be found in the subclaims.

The advantages of the Gung correction device according to the invention are obvious. The effort for such a device is by far by the in the construction of the display device saved expenses offset.

The object of the invention is based on a preferred embodiment, which in the The drawing is shown schematically and supplemented by block circuit diagrams and function diagrams, described in more detail below. It shows F i g. 1 is a block diagram of the clock, FIG. 2 is a schematic view of the clock from FIG above,

Fig. 3 is a section along the line III-III in Fig. 2,

F i g. 4 is a circuit diagram of an embodiment of the electronic frequency divider of the FIG. clock shown,

Fig. 5, 6 and 7 circuit diagrams of different stages of the in FIG. 4 shown frequency divider in individual representation,

8 shows an electromechanical converter with inonostable relay,

F i g. 0 a drive circuit for a monostable relay,

Fig. 10 oscillograms showing the operation of the in Fig. 9 explain the circuit shown,

11 is a circuit diagram of a gear correction device and

Fig. 12 oscillograms showing the operation of the in Fig. 11 explain the device shown.

The electronic clock whose constructional details from FIGS. I and 3 are shown, 1 is iunktiousmaßig in Fig. Datgestellt. It consists of a quartz oscillator C), which emits a high-frequency signal Vo to a frequency divider Z) A /. This frequency divider ZM /, for example with an integrated circuit, divides the frequency of the signals Vo / .. B. to I Hz and sends the pulses Vo low frequency to a time indicator IT with liiiem eUktrouiei little converter Rb and its Antticb-.kiei; / ·. '/ {And a Riideivveik, committing ms ilen Il iilem r, in, Ii, by means of which the respective seconds, minutes and hours are moved. How l "\\\. I icn% it tier oscillator O, the frequency divider DM and the Aitunzeiger ΙΓ parallel to the Hilli-IL · P, where the positive pole is on earth. In addition, the clock noen has a rate correction device CP , which controls and corrects the position of the wheels s, m, h . For this purpose it periodically receives a control signal SC from the frequency divider DM and a display signal SI from the time indicator and sends a correction signal SCC to the converter Rb.

As shown in FIG. 2 can be seen, the electronic circuits of the oscillator OA, the frequency divider EB, EC and EC, the correction device CC and the driver ER for the converter Rb, which are designed as integrated semiconductor circuits, attached to a common carrier plate Su and with each other and with the the two elements P1 and P 2 of the battery P are connected via lines not shown for the sake of clarity. The quartz crystal Q, which is cast in insulating compound with its connections, is arranged under a coil Lo (FIG. 3) which, together with it, forms an oscillator circuit ao, which is not shown in detail.

The electromagnetic transducer Rb drives by alternately engaging its two spare wheel with pawls arms a gear 1 (FIG. 2 and 3), is arranged on the axis of a pinion 2, the above "5, a further gear wheel 3, the Sekunuenzeigerrad s and a to the gear 3 arranged pinion 4 moves the minute hand wheel m. The hour hand wheel h is driven via a gear train from ULiii on the axis of the minute hand wheel m , the gear wheel 8 and the pinion 10 arranged on its axis 9. In this respect, it is a classic gear train. The pointer can be set by means of a gear train MW which engages the gear wheel 8 and the outer parts of which are not shown.

In addition, the watch contains a rate correction device which is independent of that described above

"- * ~ ^: · -» '- l'i-ompi'hnniKchen

direction, aie unaoiiau & ig <w u „. v,

The time display device is, with electromechanical elements, namely a control disc k aut an axle 11, which is driven by a drive device (not shown) from the gear train in such a way that it rotates every 64 seconds. At its periphery ", the disk k two projections vl and ν 2, representing the two movable 45 electrodes, which pass twice in 64 seconds to the connected to the circuit CC electrodes. Q Another electrode for producing a capacitive coupling with serves for the disk k , is attached to the carrier plate Su at a distance from the disk k on in such a way that it always covers a part of the disk k.

The oscillator O contains a resonator of particularly high quality. r. B. a quartz, the section AT. whose resonance frequency is very high, for example 55 *> MHz. Alternatively, the oscillator could also contain a different type of resonator, such as e.g. B- acoustically vibrating element anyway.

The circuit of the frequency divider shown in Fig. 4 has 21 stages of three different types So pen. EA (Fig. 5), BB (Fig. 6), EC (Fig. 7) uiu in particular a Uiiigangsstufe EA I for the division of holier frequencies, ten levels EUl to ElIl for the high and medium frequencies and / eh: levels EC 12 to EC 21 6 for low Frequeiizei) How I · hervoigeht from Fig., the level / V / 1 two F.injVängc el and / t, respectively connected to the negative pole of the battery en P via the resistor / and your output ν of the oscillator O connected

5 6 *

are. The two outputs bl and rl dc ι stage EAl follow the magnetic attraction of the stop 15

are each on the control electrodes of the two on the permanent magnet 14 n.

Transistors TdI and Td2, which are connected in series to the bat- The mechanical counting process, ie the shifter / 'gcs. Are held, and form a decoupling way of moving the gctiiebcs, comes by means of the hingsl.reis of the ice type. The output of the Ent- 5 armature 12 comes about. The two arms 13 'and 13 /> knpplungskreiscF on the one hand at the input / 2 of the armature 12 each carry pawls wechscl- EB 2 following stage and on the other hand, as to engage one in the teeth of the gear. 1 Feed line LA. Such a monostable relay is controlled by a single output of the frequency divider. 9 shows examples dl to d \\ and are separated by the entl opp- sake of a circuit serving this purpose, lungslieisc of a second type, each of three of these kids contains a coil Rft to drive transistor in Td 3. Td4, TdS and a capacitor of the monostable relay and works with pulses Cdi besil / t. It can be seen from Fig. 4 that Td3 has only one polarity. Fr is connected to the frequency and Cd 3 is connected in series to the feed line LA 15 measured Fip Output o21 of the stage and that TdA and TdS are in series at the Bat- EClX and on the other hand at point b "of the voihcrpeterie Γ . In addition, the respective upstream stage /.""20 are connected, which in Fig. 7 outputs dl to rfll of the levels EBl to Eöll with to s marry and in I ig. 9 represented as a point 620 is the Steueielektiodcn the transistors Td3 and TdS Further, this circuit comprises two transistors of the decoupling circuit TEIB dei following stage EB w and Tc 17, which in series to battery dei / 'Heverbunden. A second supply line LA 'is located on the gene of the lying to the output at the battery input of stage FB 11. Transistor The ten stages / T12 to ECU of the switched paiallel to a Kondensatoi (VIl in Figure 7. The ^\;... Getting Connected point of 7V16 and the type shown consist of a first input Te 17 is connected to the control electrode of a third Tran gang g 12 to g 21, which is connected to the feed line LA ', 25 sistor 7el8 connected to the coil R6 of the relay and a second Input / 12 to / 21, which is connected in series. 7 <»18 as well as Rb wei output of a decoupling circuit, which decouples the individual stages EC fed by the battery P. Each the operation of the circuit According to Fig. 9, this coupling circuit consists of the two transistors Tdft and TdT with the aid of the graphic representations in Fig. IC, each of which is explained with a 30. Fig. 10 shows several oscilloscope capacitors Cd6 and Cdi in series to the Sp icograms, each of which is connected to the course of the following chip line LA ' , the input of voltages indicating: TdI is at the output of Td6 . The outputs al2! / “<· _ J; -ο · .——— _λ “ . ... ..

until all Hegen at the entrances of the Tran- * ^g "d _cr Sm? en ΓΓΐ /? ^a £ P. ^ts Pf, f itung L, 4

sistors Td 6 of the following decoupling circuits. As 35 Tdlere "* ^{8" shown}

otherwise from Fig. 4th is the stage. ,, _ie '

ESIl from the EC-U stage through a decoupling »7« - the voltage at the input terminal /

management circuit separated, which consists only of the capacitor _{r of} the stage EC19 of the divider;

Cd6 and the transistor Td 6. Va 19, = the respective voltage at the input of the

The mode of operation of the individual stages of the Fre- 40 VaIO, = first transistor (7Vl, point "a", Fig. 7)

quenzteilers EA, EB, EC, which in the Fi g. 5, 6 and 7 ^Va2 l = of levels EC 19, EClO or ECU des

are shown, will not be described in detail. Divider;

Suffice it to say that stage EA 1 (Fig. 5) _a VbIO - the voltage at point b " (Fig. 7) of the

Reduction ratio of 4: 1 between the hre- stage EC 20 of the divider

sequence of the input signals Vo of the oscillator O at 45 Vu = the voltage at point m of the circle

Input / 1 and the frequency of the voltage pulses _{according to} F i g. 9 ·

at its output rl enables. Each of the stages EB _vs , ■ _c _,

and EC has a reduction of 2: 1 of the respective * '~ ^ J ^ ™ ^{g m point} ' of ^{the circle}

Signal frequency at its input. ⁸ "

The mode of operation of the arrangement according to FIG. 4 50 In the case according to FIG. 10 it was assumed that this should not be described in detail either. The voltage impulses required for the drive should suffice that the frequency divider at being Vi, the same frequency as Fa21 at the Ausnem output must have a signal with the frequency 1 Hz from the reducer, but be careful, as I said , for the control of the electrical current times must be as long as the impulses of the mechanical converter are required. This converter 55 main supply voltage Vg '. Therefore the control is in Fig. 8 on the basis of a monostable relay represented by the Tiansistois 7V17 at point 6 "dei, which drives a gear. It could also consist of a bistable for each stage EC 20 and that of the transistor TeU at the The pulses T'620 make 7> 17 conductive and Ia-In the relay according to FIG 14s a pair of poles that work together with the fixed coil R 6 of the relay from the control electrode, which means that it is practically zero and therefore TcIS The two magnets are powered on an armature 12. When a pulse T'a21 occurs there is solidified, which is angled on the pivot axis; el3, which is rotatably mounted in no pulse t'i> 20 (Fig. 10) on the circuit board (not shown) board 65 txodi 7rl7, and the capacitor (VIl discharges .A magnetic The stop 15 limits the possible 7V16. who is in charge. Under the condition ¹ that 7th stable heating of the armature 12 is sufficiently long with a power pulse duration of 7V16 (signal J'e21) from interruption of the current * through the coil R 6. to (VIl in the desired time

(ο

to discharge, the transistor Te 18 is conductive and lets the current through the drive coil R 6 of the relay. The capacitor Cell remains discharged until a new pulse Vb 20 occurs, which charges the capacitor again and consequently blocks transistor Je 18; Current can no longer flow through the coil Λ 6.

As already mentioned at the beginning, the watch described also has a rate correction device CP (FIG. 1), the electromechanical components of which have already been described (FIGS. 2 and 3). The operation of this device is as follows:

The position of the wheel value ^{1 is} determined at periodic intervals by means of a signal which is supplied by additional frequency divider stages connected downstream of the output of the frequency divider (Fig. 4) and checks whether the test signal and a reference signal corresponding to that position of the wheel train coincide which the gear train would have to assume if the gear train was properly driven by the relay. If an incorrect position is determined, a correction circuit acts on the time display in order to correct its position and in this way prevent a possible accumulation of counting errors over a longer period of time. These errors in the gear train can result from damaging accelerations or external magnetic fields, for example from incorrect movements of the relay parts.

F i g. 11 shows such a correction device. This has a control disk K , which is driven by the gear train and performs one revolution in 64 seconds. The disk K has at its periphery two protrusions vl, ν2, which are diametrically opposite and movable two electrodes form, two electrodes with the solid was should cooperate.

These two fixed electrodes is and is extending corresponds to about an angular range of at least two successive displacements of the disc K, and electrically in each case articulated at the connection point of two series circuits of a transistor and a capacitor C12, Γ19 or C13, T 20th Between each of the two electrodes be or be and the corresponding capacitor C12 or C13, the circuit has an ohmic contact (yl> / 2) which is applied to a p-layer diffused into an η-conducting crystal. The control electrode of T 19 is connected to contact / 2 and Γ20 to / 1.

11 shows several frequency divider stages EC20 to EC26, of which stages EC20 and EC 21 represent, for example, the last two of the Tefler stages shown in FIG. The five additional stages EC22 to EC26 serve to divide the frequency from 1 Hz at the output α 21 of the stage EC21 to V «Hz at the output a26 of the stage EC26. Each stage EC22 to EC26 likewise has a decoupling circuit according to FIG. 4, which, however, has been omitted for the sake of simplicity.

The control and corrector circuit also consists of two transistors T21 and Γ22, which are connected in series with a capacitor C14 or ClS via the output terminals α 20 and α21 of the two last stages (EC20, EC21) of the frequency divider. The control electrodes of Γ21 and Γ22 are connected to the outputs of transistors Γ20 and Γ19, respectively. Furthermore, this circuit has the in FIG. 2 shown drive circuit R 6, T16, C16, T 24, T 23 of the monostable relay. The control electrode of the transistor T13 is connected to the point blO of the stage EC 19, while Γ24 is at the output of Γ22. A transistor Γ25 is parallel to C16 between the negative pole of battery P and the input of Γ 26. The circuit also has a transistor Γ 27, which is connected in series with a capacitor C17 across the output α 20 of stage EC 20,

ίο whereas the control electrode of Γ 27 is at the output of transistor TIl and the output of Γ27 is connected to the control electrode of 725. A transistor 7 "29 is connected to a capacitor C18 in

. Row on the battery, the output of T 29 being at the coupling electrode q (at point o) (Fig. 2 and II). A transistor TIS lies between the negative pole of the battery P and the point o, and the control electrode of T 28 lies at the output a 26 of the additional frequency divider stage EC 26. How

ac is apparent from Fig. 11, a capacitor C19 is between the negative pole of the battery P and the input (point n) of the transistor 7 "29. Two further transistors 730, Γ 31 are connected in series to the battery P, the output of Γ 31 is connected to the input of Γ 29. Finally, the circuit also has a transistor Γ 32, which is in series with a capacitor C 20 at the output α 21 of stage EC 21 of the frequency divider, the output of Γ32 with the control electrode of Γ 30 is connected, while the control electrodes Γ31 and Γ32 are at the output al6 of the stage EC26 .

The rate control of the gear train is carried out at periodic intervals of 32 seconds by means of a signal Vq which feeds the coupling electrode q , the duration of the signal determining the display and correction period.

The signal Vq is obtained in the following way:

It is assumed that at the time in

the two signals Va 21 and Va 26 appear simultaneously at the corresponding frequency divider stages (Fig. 12), the capacitor C18 charged, the capacitor C19 discharged, the transistor Γ29 conductive and therefore the electrode σ is at zero potential (Vq = 0) and the transistors Γ28, Γ30, 7/31 and Γ 32 are blocked.

At the moment in which the signal Va 26 occurs simultaneously with the signal Va 21, the transistors 28, Γ 31 and Γ 32 are conductive, with the result that

so 1. the capacitor C18 discharges, so that the point o and the electrode q assume the negative potential of the battery P (first pulse edge in Fig. 12),

2. the signal VaIl flows through the transistor Γ32 to ground, the transistor Γ30 remains blocked and the capacitor C19 sieves, charges via Γ31,

3. the point has zero potential if the Capacitor C19 is charged and transistor Γ29 is blocked.

At the end of the pulse Va 26, the transistors Γ28, 7 * 31 and Γ32 are blocked again, and the circuit emitting the signal Vq remains in its state with a discharged capacitor C18 and a charged capacitor C19 until the next pulse of the signal VaIl arrives a second after the first, obviously no corresponding one

Signal Val6 occurs because its frequency is 32 times low-zero, whereby the transistor at the control electrodes

riger is. This has the following effect: ren Γ21 and T22 also have a zero potential

, - * ,,. . ^ ₁ . _Λ ...... -, and these transistors remain blocked. Since the

1. The capacitor C19 discharges; Transistor Γ21 is blocked, a pulse VaIO,

2. the transistor Γ19 becomes conductive; the point ο _{5 comes from the output a2} 0 of the stage EC20, the «r maintains the potential zero and the capacitor _{transistor Τ} control so that this becomes conductive C 18 charges, whereby the electrode q _{and the occurrence of the} same pulse Va 20 genal- at the negative to the potential of the battery control electrode of the transistor Γ 25 prevents was ten so now ER- zero potential _{that this remains locked the} i _mpu i _se Va 21 and ^nält ίο Vb 20 can therefore freely the drive circuit

The alternating charging and discharging of the relay R 6 feed, which then by means of the tran capacitors C18 and C19 cause these sistors Γ 23, T 24, Γ 26 and the capacitor C16 to form a voltage pulse that corresponds to the one described above Way forms the signal Vu bil signal Vq , the pulse duration of which is the period end. The drive of the relay R 6 thus takes place in the duration of the impulses VaIl , in the present case in the intended manner.
dea case of a second, while the period duration

of the Vq signal corresponds to that of the Val6 signal. The clock is moving forward.

speaks i.e. 32 seconds in the described embodiment. - In case of accidental movement of the movement

When assembling the clock, the disk A: ao is the disk k, for example, in the through in such an angular position that the position shown by the lines z2-z2. Vl actually entbeweglichen electrodes and ν2 the solid electron speaks each position in which the fixed electrode is trodes se2 and is overlap at the moment, not from one of the projections from the left or ν2 überin the q the electrode, the signal Vq receives covers is a Action. This procedure is je- (line zl-zl in Fig. 11). If the drive of the wheel can only be determined when one of the two electrodes v1 or ν2, which can be moved properly by the relay , acts, ie when the disk k is covered. With such a position of the disk k considering the selected reduction ratio, a negative potential occurs in a capacitive way only makes exactly one revolution in 64 seconds, at point j 1.

the electrode q holds two pulses Vq at every turn. Transition at the contacts / 1 when it has rotated 180 ° and / 2 and can only be recharged if

In the event that the disc * is contrary to when the transistors T 19 or Γ 20 are conductive.
If the movable electrode ν 2 is not the fixed disk, in which the electrodes ν 1 and ν 2 overlap in the electrode ie2, the signal Vq occurs neither position of the line Z2-z2 when the signal Vq am Point / 2 is still on the control electrode of T 19 at electrode q , a procedure of the on, so that this remains blocked and the condenser gear train, based on the reference position zl-zl, sator C12 remains discharged. From this it follows that which this gear train on Grand of the counting of the 40 signal Vq arrives at the control electrode of Γ 22 take pulses Vm received from the relay Rb and makes it conductive, while Γ 21 should as a result of the. conductive state caused by the signal Vq

A position of the disk in which the electrodes of the transistor Γ20 remain blocked due to a lack of voltage at its ν 1 and ν 2 in the direction of the line z3-z3 when the control electrode arrives.
fen of the Vq signal at the electrode are q, 45 corresponds If Γ22 is conductive, the signal passes Vail speaks a follow up of the gear train, not related to the transistor Γ 24, which consequently geauf dieBezugssfellungzl-zl. remains locked. The signal Va 20 cannot use the

In the following it will now be described how the Er capacitor C17 get to the transistor Γ 25, averaging the position of the disc * at the time of because T27 is conductive at this moment, because the arrival of the control pulse Vq at the electrode 50 its control electrode same signal Va 20 via trode? and how the correction device receives C14 because T 21 is blocked
the clock reacts to this determination. As a result, C16 remains discharged and the An

The drive circuit of the relay Rb cannot work while

A. The clock is working correctly. the control electrode of T26, via which in the conductive]

55 state the current through coil R 6 of Rc

During normal operation of the clock, the flows remain at zero potential, which prevents a conductor disk K in the angle of the transistor shown in Fig. 11,
position (Zl-Zl) at the same time as the elec- In this way one obtains the oppression

trode q receives an impulse Vq through the sym- a impulse Vm, whereby the random occurrence metric alignment of vl and ν2 occurs which is compensated again on 60 of the clockwork,
capacitive path to the disk K at the same time on the segments let and let C. The clock slows down,
on. Both control electrodes of the transistors Γ19
and T20, which are at points / 1 and / 2, respectively. This case is used to explain this case, in addition to having a negative potential, which means that FIG. 11 also shows FIG. The disk, the capacitors C12 and C13 are charged after the clockworks slowing down, and the output voltages of the transistors with their projections v1 and ν2, for example, remain that indicated by the lines3- * 3 (FIG. 11)

11th

only detectable when one of the moving electrodes of the electrode is opposite in such a position of the disc

KasasÄÄ

Elec

Λ wira aas

Kasaas

As before, the

When the movable electrode and ίο

is

receives so that

NEN, which is accordingly blocked and opened alternately by the signal Va 20.

As can be seen from Fig. 11, T25 is connected in the same way as Γ 24 in parallel to C16, which it can discharge by opening in the same way as Γ 24. However, the signal Va 20 has twice the frequency of Va 21, and at the beginning of the first second these two signals are in phase

(Fig. 12).

In Fig. 12, Vu denotes the pulse at point u during the discharge of the capacitor C16 via the transistor T 24. Vu denotes the pulse at the same point u during the discharge of the same capacitor C16 via the transistor Γ 25.

If the two signals Fa20 and Fa 21 occur at the same time, Γ 24 and Γ 25 are simultaneously conductive and C16 is discharged in practically the same way as if only one of the two transistors were conductive. The relay is driven in a perfectly normal way by a synchronous double signal Vu-Vu , which differs in no way from the simple signal Vu with a frequency of 1 Hz, which occurs as long as the clock is running correctly.

At the second occurrence of the pulse Va 20, the stage EC 21 does not also generate a signal Va 21, so that only T 25 becomes conductive, which leads to the generation of an additional drive pulse Vu for the relay, this pulse being between two normal drive of the relay corresponding impulses was inserted.

- In this way it is possible to follow the Uhi by one step by inserting an additional compensate borrowed drive pulse.

For this purpose 2 sheets of drawings

Claims (4)

Claims: I. Electronic clock with a clock emitting high-frequency electrical signals, a frequency divider connected to it, consisting of several divider stages and a display device controlled by it with tick pointers, characterized by a rate correction device, the 1. a detector (CP) for periodic comparison of the Position of the time hand (s, m, /;) with a reference position corresponding to a correct clock rate obtained from a count of signals (Sc) supplied by the frequency divider (DM) and 2. to generate a reference position corresponding to a possible deviation between these two positions with the correct sign Discriminator signal (.Src) contains a switch stage (IR Y Rb), which connects the time pointer with a Zvvisihcnstufc in the frequency divider in the case of a sign of the discriminator signal corresponding to a lag jo of the time pointer and thus accelerates its I to and corresponds to an advance of the time pointer The sign of the discriminator signal temporarily interrupts the connection between the frequency divider and the time indicator and thus stops it until its lead is eliminated (Fig. I). 1. Flektronic clock according to claim 1, characterized in that the rate correction device (CP, ER Rb) contains two channels fed alternately with the discriminator signal (See) , each of which is assigned to one of the two unpredictable signs of the discriminator signal and one of two electronic switches ( T 19, Γ22; 7 20, Γ21), of which the switch (T 19, T21) assigned to an advance of the time indicator (s, m, h) generates a feed pulse (Vu) for the drive (R 6 ) suppressed for the time indicator and the switch (7 "20, TU) assigned to a lag of the time indicator, with the appropriate sign of the discriminator signal, an additional feed pulse (Vu ') is supplied to the drive of the time indicator (FIGS. 1, 11 and 12). Electronic clock according to claim 1 or 2, characterized in that the detector (CP) is a signal source (EC 20 to EC 26) controlled by the frequency divider (DM ) for control signals with a frequency below the frequency of the signal emitted by the frequency divider (DM) , two fixed electrodes (ve I and ve 2), each connected to an information channel and arranged on both sides of a fictitious axis (z 1-z 1) assigned to the reference position, and at least one electrode (A) opposing these and moving relative thereto, which complies with is electrically connected to the signal source for the control signals and kinematically connected to the time hands (.v, in, / 1) and their angular position relative to the fictitious axis each time a control signal occurs, indicating a possible deviation in the position of the time hands by that caused by the counting of the Signals emitted by the frequency divider define reference position disappears (Fig. I and 11). 4 Electronic clock according to claim 1 or 2, characterized in that the detector (CP) has a signal source (EClQ to ECId) controlled by the frequency divider (DAi) for control signals with a frequency below the frequency of the signals emitted by the frequency divider (DM), two electrically connected and diametrically opposite one another on a kinematically connected to the time hands (s, m, Ii) and in the period between two successive control signals with the correct rate of the time hand (s «ι Λ) executing a rotation of 180 ° around its axis ( K) arranged electrodes (r 1, v 2) and two each with one information channel associated and diametrically opposite each other along with rotation of the circular disc (K) from disposed on said electrodes (vl, ν 2) continuous circular path arranged fixed electrodes (whether, sei) , the drive of the circular disk (K) having a movable electrode (vl, v2) in each case when a control signal occurs konek'ein passage of the time hands (s, m, h) each exactly opposite a fixed electrode (sei, sei) or, in the case of leading or lagging, the time hand (s, in, Ii) by a corresponding angle in or against its direction of rotation can be displaced opposite (Fig. 1 and 11).