DE2654305A1 - Setting circuit for electronic timepiece - using setting pulses with variable pulse train frequency altered in stages - Google Patents

Abstract

The setting circuit is for an electronic timepiece with an oscillator, a frequency divider and a counter network, supplying signals to a digital display. The circuit uses setting pulses with a variable pulse train frequency, fed into the counter network. A setting pulse generator automatically supplies a variable setting pulse train frequency after selection of the time setting operation. The pulse train frequency may be varied in stages and the setting pulse generator pref. comprises a voltage-controlled oscillator (20). The control input (21) of the latter is coupled to a time constant circuit (R1, C) the capacitor (C) of which is bypassed by a setting switch (S) for normal running of the timepiece.

Description

Circuit arrangement for setting electronic clocks

The present invention relates to a circuit arrangement for setting of electronic clocks with a frequency divider from a frequency standard controlled time unit counter and with one controlled by the time unit counters, especially digital, time display arrangement in the case of actuating pulses with variable Pulse repetition frequency can be fed into the time unit counter.

The basic structure of an electronic watch, like him, for example from 11Funkschau »(46), October 1974, pages 859 to 862 has become known, shows Pig. f. An oscillator 1 serving as a frequency standard is converted into a frequency divider Time unit counter, d. i.e., hour counter, minute counter and, if applicable, seconds counter controlled, which are included in level 3. Level 3 may still contain corresponding decoders and driver stages, the counting values of the Level 3 included time unit counters in a digital display, for example a liquid crystal display.

In order to be able to set such an electronic clock, the in the stage. 3 included time unit counters regardless of the pulses supplied via the frequency divider can be advanced. To this Purpose, an adjusting device is provided, which generates control pulses that in the time unit counters are fed in.

If during an adjustment process not just for a specific minute but must also be set to a specific hour, the repetition frequency must be the The actuating impulses must be sufficiently large at least for the hour setting process, otherwise very long times would be required to set the clock. It is already fundamental known to make the repetition frequency of the actuating pulses variable, the repetition frequency for setting on a certain minute relatively small and for setting on a certain hour is correspondingly greater.

From DT-OS 2 025 710 an adjusting device for an electronic Clock has become known in which a setting pulse generator is provided by one on the clock Push button can be switched on. In addition, this push button is mechanical too connected to the slide of a potentiometer provided in the setting pulse generator, whereby the resistance value of this potentiometer by pressing in different depths of the push button is changeable. By changing the resistance value in this way of the potentiometer, the repetition frequency of the control pulse train is also variable. Ever The deeper the push button is pressed in, the higher the repetition rate the control pulse sequence.

Such an adjusting device is disadvantageous because the value of the repetition frequency of the control pulse train from the manual skill of the user depends on the clock. On the other hand, a relatively complex mechanism is required, because by pressing the button for the adjustment process the normal running of the The clock is switched off and the repetition frequency of the actuating pulses is changed must become.

It is also from the DT-AS 25 40 486 an adjusting device for an electronic clock became known, in which at a clock to generate a Control pulse sequence a cam wheel is provided, in the cam a spring element engages, which in turn acts mechanically on a piezo element. When turning of the cam wheel are transmitted by the periodic snapping of the spring element into the grooves between the cams of the cam wheel as mechanical pressure pulses on the piezo element, whereby corresponding electrical impulses are generated. The repetition frequency of these pulses, which are used as control pulses, is determined by the speed of rotation of the cam wheel. This is also mechanical Ways to change the repetition frequency of the control pulse train possible.

Such a device is also due to the detour via the Mechanics for generating the control pulse train with variable pulse train frequency are disadvantageous.

From the DT-OS 25 52 366 is a time correction circuit for electronic Timepiece become known, which can be actuated by a mechanical switch Contains cascade of shift registers. In this time correction circuit, at Briefly pressing the switch generates an actuating pulse, while pressing it for a longer period of time of the switch, an actuating pulse sequence with a fixed repetition frequency is generated. this has the disadvantage that the actuation process either only with a pulse or a pulse train with a fixed repetition frequency is possible.

The present invention is based on the object of a circuit arrangement for setting electronic clocks at which the repetition frequency is the Control pulse sequence changes automatically after switching on once.

In the case of a circuit arrangement, this task becomes the one mentioned at the outset Kind by a setting pulse generator with a normal run the time constant circuit that is switched off after switching on the setting process automatically a time-variable actuating pulse repetition frequency caused, solved.

Such a circuit arrangement has the advantage that the adjusting process after switching on, initially with a low repetition frequency of the actuating pulse train can start and that the repetition rate increases automatically as a function of time. It is thus possible for the actuating pulse train to be at a low repetition frequency at first a precise setting of the smaller time units, such as minutes and possibly seconds is possible and that only when it may be necessary to adjust it by long periods of time over hours due to the increasing repetition frequency of the actuating pulses a faster one Adjustment is possible.

Refinements of the inventive concept are characterized in the subclaims.

The invention is illustrated below with reference to FIGS. 2 to 6 Embodiments explained in more detail. It shows: FIG. 2 a circuit diagram of a first Embodiment of a circuit arrangement according to the invention; Figure 3 is a diagram the functional relationship of the output frequency of the circuit arrangement 1 and a control voltage which determines the variable repetition frequency of the actuating pulse sequence; FIG. 4 shows a diagram of the output frequency of the circuit arrangement according to FIG. 2 as Function of time; FIG. 5 shows a second embodiment of the circuit arrangement according to the invention; and FIG. 6 shows a diagram of the output frequency of the circuit arrangement according to FIG. 5 as a function of time.

In the embodiment of FIG. 2 is used as a control pulse generator Generation of the control pulse sequence a voltage-controlled oscillator 20 with a control input 21 and an output which supplies the control pulse sequence 22 provided. The control input 21 of this voltage-controlled oscillator 20 receives a control signal from the connection point of one formed by a resistor R1, C. Series RC element which is connected to a terminal 23 at a fixed voltage. The capacity C of this series RC element is through a two-pole switch S with two switching contacts s1 and s2 and a switching arm 53 can be short-circuited. The switch contact s1 of this two-pole Switch S is located directly at the connection point of the resistor R1 and the capacitance G of the series RC element. The switching contact of the two-pole switch is also located S via a resistor R2 to a terminal 24, which also has a fixed voltage lies.

The output 22 of the voltage controlled oscillator is at one Input of an AND gate 26, the other input of which via an inverter 25 to the Switching contact s2 of the two-pole switch S is coupled. At an exit 27 the control pulse sequence can be removed, for example according to the block diagram 1 of the actuating device 5, which the circuit arrangement according to FIG. 2, into which stage 3 can be fed.

How this works. The circuit arrangement is now as follows: When the clock is running normally, the two-pole setting switch S is in the position shown in FIG Switched to the position in which the contact arm s3 lies on the switching contact s1. So is the capacitance C of the series RC element R1, C short-circuited, so that the control input 21 of the voltage-controlled oscillator 20 from this time constant element no signal receives. Since the switch contact s2 continues in the illustrated position of the switch S runs idle, the fixed voltage on terminal 24 is across the resistor R2 at the input of the inverter 25. By inversing this voltage through the inverter 25 the AND gate 26 is blocked so that no signal occurs at its output 27 can.

If the two-pole switch S is now switched over for an actuation process, so that its contact arm 53 is on the switching contact s2, then on the one hand the short circuit the capacitance C of the series RC element R1, C canceled and on the other hand that on the Fixed voltage on terminal 24 short-circuited to ground via switching contact s2. Since there is thus a zero signal at the input of the inverter 25, the inversion occurs this signal, the AND gate 26 is activated, so that the output pulses switched through to output 27 at output 22 of voltage-controlled oscillator 20 will. Furthermore, the capacitance C charges through the resistor R1, so that on Control input 21 of the voltage controlled oscillator 20 as a function of time increasing control voltage U5 is available. Because of this control voltage which increases over time U5 is the repetition frequency of the output 22 of the voltage controlled oscillator 20 is greater as a function of time, i.e. h., the repetition frequency of the removable at the output 27 Control pulse sequence also increases as a function of time.

The circuit arrangement of FIG. 1 can be designed so that the control voltage at the control input 21 of the voltage-controlled oscillator 20 Us is the repetition frequency of the actuating pulse sequence according to one of those shown in FIG Characteristics influenced. The repetition frequency fa of the control pulse train can as a function of the control voltage U5 disproportionately (curve a) proportional (curve b) or disproportionately (curve c).

The course of the repetition frequency of the control pulse sequence as a function of Actuation time t of the setting switch S is shown in Fig. 4, which is the repetition frequency Fa as a function of time t. The repetition rate approaches asymptotically the value that is valid when the capacity C is fully charged.

In the described embodiment of the circuit arrangement according to the invention for setting electronic clocks the repetition rate the control pulse sequence as a function of time t according to FIG. 4 continuously.

In a further development of the invention, however, it is also possible that the temporal Change in the control pulse repetition frequency is stepped.

An embodiment of the circuit arrangement according to the invention for Realization of such a stepped course of the actuating pulse repetition frequency is shown in FIG. In this embodiment there is an actuating pulse generator 30 0 provided, which several pulse trains discrete different sequence frequencies supplies. In the illustrated embodiment, the control pulse generator delivers 30 two pulse trains of discrete repetition frequencies f1 and f2 at outputs 31 and 32, where, for example, f1 = 1 Hz and f2 = 100 Kz. The time constant circle contains in this embodiment, a binary counter 33 with a key element Reset input 34, a counting pulse input 35 and a carry signal output 36.

The reset input 34 of the binary counter 33 is via an inverter 50 and a resistor R3 coupled to a terminal 37, at which a fixed voltage lies. Furthermore, the connection point lies between the inverter 50 and the resistor R3 on switching contact s1 of setting switch S. The setting pulse sequence with the repetition frequency The output of the actuating pulse generator 30 which supplies f1 is at an input of an AND gate 39 with two further inputs, which have an inverter 40 and a resistor R4 to a terminal 38 with a fixed voltage or via an inverter 41 to the carry signal output 36 of the binary counter 33 are coupled. The output of this AND gate 39 is located at the counting pulse input 35 of the binary counter 33.

the carry signal output 36 of the binary counter 33 is also present Via an inverter 42 at an input of an AND gate 43 or

directly at an input of a further AND gate 44. To each Another input of these AND gates 43 and 44 is an actuating pulse output 31 or 32 of the control pulse generator 30 coupled. The outputs of the AND gates 43 and 44 are coupled via an OR gate 45 to an input of an AND gate 46, its other input via an inverter 47 to the resistor R4 and the switching contact s2 of the setting switch S is coupled. An output 48 of the AND gate 46 is represents the control pulse output, which according to FIG. 1 is the output of the control device 5 is.

The mode of operation of the circuit arrangement shown in FIG. 5 is the following: In normal operation of the clock, the switching arm 53 of the setting switch is S in the position shown in FIG. 5 on switching contact S1. At the connection point of the resistor R3 and the inverter 50 is therefore zero potential, so that at the reset input 34 of the binary counter 33 a holding the binary counter in its zero counting position Signal lies. The one at the junction between resistor R4 and the inverters 40 and 47 standing signal is converted into a signal by these inverters, that keeps the AND gates 39 and 48 locked.

Therefore, no control pulse signal can arise at output 48.

T; the setting switch S is now in one position for a setting process switched, in which his switching arm 53 is located on the switching contact, so that drops at the connection point of the resistor R4 and the inverters 40 and 47 standing signal at ground potential away.

The inverters 40 and 47 convert this zero signal into one of the AND gates 39 and 48 effective switching signal. At the same time it jumps at the connection point of the resistor R3 and the inverter 50 to a non-zero signal Value which is converted into an xilert other than zero via the inverter 50 is so that the binary counter 33 at its reset input 34 no reset signal receives more.

Since first the signal at the carry signal output 36 of the binary counter 33 is still zero, this zero signal is passed through the inverter 41 into an AND gate 39 effective switching signal transferred. Therefore, the control pulse generator 30 pulse train delivered at its output 31 with the repetition frequency f1 via the AND gate 39 are fed into the counting pulse input 35 of the binary counter 33, so that it begins to count. At the same time, the zero signal is applied to the carry signal output 36 of the binary counter 33 through the inverter 42 into an AND gate 43 effectively switching Signal transferred, so that the control pulse sequence with the Solge frequency f1 via the AND gate 43, the OR gate 45 and the AND gate 46 are transmitted to the output 48 will.

As soon as the binary counter 33 has counted its full counting capacity, a carry signal arises at its carry signal output 36, which is transmitted via the inverter 41 is transferred into a signal blocking the AND gate 39. At the same time will the AND gate 44 switched through by the carry signal at the carry signal output 36, so that the control pulse sequence delivered by output 32 of the control pulse generator with the repetition frequency f2 via the AND gate 44, the OR gate 45 and the AND gate 46 is switched through to output 48.

The step-like increase in the repetition frequency fa of the actuating pulse train as a function of time t is shown in the diagram of FIG. - Owns the binary counter 33 the counting capacity n, after actuation of the setting switch S in the aforementioned Meaning two n-1 clocks with the first small repetition frequency f1 switched through, because the carry signal at the carry signal output 36 as long as it has the value zero. Then the higher repetition frequency f2 is switched through, and at the same time the further counting of the binary counter 33 is prevented.

Preferred inert ones for the counting capacity of the binary counter 33 are Values 2 to 4.

By appropriate cascade connection of parts of those shown in FIG Circuit arrangement is also an increase in the control pulse repetition frequency in several Levels feasible.

Furthermore, the circuit arrangements according to FIGS. 2 and 5 can also be combined with another switch, with which a correction of the time display the clock can move forward or backward.

6 figures 12 claims L e r s e i t e

Claims (12)

patent claims Sp Y. Circuit arrangement for setting electronic Clocks with time unit counters controlled by a frequency divider from a frequency standard and with one controlled by the time unit counters, in particular digital, Time display arrangement in which actuating pulses with variable pulse repetition frequency in the time unit counters can be fed in, g e k e n n n z e i c h n e t d u r c h a setting pulse generator that automatically switches on the setting process requires a time-variable control pulse repetition frequency. 2.) Circuit arrangement according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the temporal change in the actuating pulse sequence frequency is constant runs. 3.) Circuit arrangement according to claim 1, d a d u r c h g e -k e n It is not clear that the change in the actuating pulse frequency over time is gradual runs. 4.) Circuit arrangement according to claim 1 and 2, d a d u r c h g e k E n n z- e i c h n e t that the actuating pulse generator is a voltage-controlled oscillator (20) is formed, the control input (21) to a time constant circuit in Shape of a ROG member (R1, C) is that the capacity (C) of the RC member (R1, C) can be short-circuited via a setting switch (S) for normal running of the clock and that the output (22) of the voltage-controlled oscillator (20) via the setting switch (S) can be decoupled from the time unit counters for normal running of the clock and for the setting process can be coupled to the time unit counter. 5.) Circuit arrangement according to claim 4, d a d u r c h g e -k e n n z e i c h n e t that the output (22) of the voltage-controlled Oscillator (20) is at an input of an AND gate 26, which is connected to a further input can be coupled to a fixed potential by the setting switch (S) via an inverter (25) is. 6.) Circuit arrangement according to one of claims 1 and 2 and 4 and 5, that the voltage controlled oscillator (20) is designed so that the control pulse sequence frequency as a function of the time constant circle (R1, C) delivered control signal increases disproportionately. 7.) Circuit arrangement according to one of claims 1 and 2 and 4 and 5, that the voltage controlled oscillator (20) is designed so that the control pulse repetition frequency as a function of the time constant circle (R1, G) supplied control signal increases proportionally. 8.) Circuit arrangement according to one of claims 1 and 2, and 4 and 5, that the voltage controlled oscillator is not shown (20) is designed so that the control pulse repetition frequency as a function of the time constant circle (R1, c) the control signal supplied increases disproportionately. 9.) Circuit arrangement according to one of claims 1 to 3, d a d u It is clear that the control pulse generator (30) has several pulse trains discrete different repetition frequencies (f1 f2) delivers that a time constant circle a binary counter (33) with a preset value that can be effectively switched via the setting switch (S) Contains counting capacity (n) and that to a carry signal output (36) of the binary counter (33) a switchable gate circuit (42, 43, 44, 45, 46, 47) is coupled, via which a switchover occurs after the specified counting capacity has been reached from a sequence of actuating pulses with a lower repetition frequency (f1) to a sequence of actuating pulses takes place with a higher repetition frequency (f2). 10.) Circuit arrangement according to claim 9, d a d u r c h g e -k e n n z e i c h n e t that a reset input (34) of the binary counter (33) with normal A constant signal is applied to the clock via the setting switch (S) is that keeps it in its zero count position. 11.) Circuit arrangement according to claim 9 and 10, d a d u r c h g e k e n n n z e i c h n e t that the counting signal input (35) of the binary counter (33) over an AND gate 39 at the output (31) for the actuating pulse train of lower repetition frequency (f1) of the control pulse generator (30) is coupled that the AND gate 39 is additionally to an input coupled to the actuating pulse generator (30) two further inputs a first inverter to a constant signal or via a second inverter (41) has inputs located at the carry signal output (36) of the binary counter (33), and that the constant signal present at an input of the AND gate 39 is in the actuating mode can be short-circuited by the setting switch (S). 12.) Circuit arrangement according to claims 9 to 11, d a -d u r c h e k e n n n z e i n e t that the switchable gate circuit (42, 43, 44, 45, 46, 47) comprises the following components: AND gates (43, 44) that start with a Input at each control pulse output (31 or 32) of the control pulse generator (30) and with another input at the reset signal output (36) of the binary counter (33) lie, an inverter (42) in the connection between the reset signal output (36) of the binary counter (33) and the other input of the AND gate (43), the at the output (31) for the actuating pulse train of lower repetition frequency (f1) is a at the outputs of the AND gates (43, 44) lying OR gate 45, as well as one with an input at the output of the OR gate (45) and another input via an inverter (47) is connected to the signal branch, which is connected to the counting signal input (35) lying AND gate (39) switches effectively in actuating mode.