DE2828776A1 - Frequency-stabilised control generator with synchronisation counter - produces regulating value for output frequency from time difference between count at end of period and following counter result - Google Patents

Abstract

The frequency-stabilised control generator is designed so that its output frequency can be set to a given value within a frequency range not much greater than 1 digit of the lowest decade of the frequency counter. The clock frequency is roughly that needed for the digital frequency counter. There is a synchronous or quasisychronous counter. It is employed such that the control signal for the frequency is obtained from the time difference between the count at the end of the count time and the next count.

Description

TITLE OF THE INVENTION

FREQUENCY STABILIZED CONTROL GENERATOR Application of the Invention The The invention relates to a frequency-stabilized control generator, the output frequency of which adjustable within a certain frequency range and on a digital one Frequency counter can be read, with a variable that can be controlled with respect to its frequency Oscillator and a reference frequency oscillator for generating the gate time of the frequency ihlers and a device for generating a charging voltage (current) for a charge storage device controlling the frequency of the variable oscillator of a deviation of the oscillator frequency from a Solbert that is within a Frequency range that is not or not significantly greater than 1 digit of the least significant Decade indicated by the frequency counter, specified or variable.

Such control generators are used in particular in Na @@ - richtmeßtechnik Used for sail transmitters and selective level meters that work @it frequency conversion. They can also be used sensibly anywhere within a relatively schinalen frequency range selectable frequencies with great accuracy and high long-term stability should be available.

Characteristics of the known technical solutions One is known Circuit arrangement in which, for the purpose of obtaining an actual value of the frequency, that within a frequency range of one digit is the least significant Counting decade, an additional number not displayed decade (1/10 divisor) or a 711 divider is also used, whereby the gate time of the counter is increased tenfold must and at which this actual value with a predetermined target value in a difference calculator is compared and in dependence on this. Difference value via an integrator the frequency of the oscillator is readjusted until the difference is zero is.

A control generator in which the solbvert within a digit of the lowest significant frequency decade can vary, was already considered "on adjustable Frequency values lockable control generator "(DT-OU 2362115) also proposed. In this case, either the actual type is used as the setpoint when a latching button is pressed transferred to a digital memory serving as a setpoint memory or the setpoint is entered by hand directly into a settable decadic up / down counter that serves as a memory entered.

The known circuits have the disadvantage that the counting time of the electronic meter must be 10 times longer than the last one indicated Decade is required, which is very disadvantageous for the exact frequency setting, if this results in counter cycle times of the order of 1 s.

a further disadvantage is that due to what is known as digital error The last digit of a digital counter results in an indefinite drift the frequency by the value of one digit of the least significant counting decade that is not displayed occurs (i.e. 711 or 711 of the least significant digit displayed). Farther# can be disadvantageous for certain applications (e.g. when measuring steep pilter flanks) be that the setting of the setpoint is within the range of the least significant Decade not continuously, but only in 10 or 16 steps is possible. Finally, it is also disadvantageous that the control characteristic only has exactly one Decade, so that an overflow during interpolation is not possible and Even elaborate art circuits must be used to avoid instabilities To avoid regulation at the points of discontinuity in the decade margins.

Objective of the invention The objective of the invention is a frequency-stable control generator, which avoids the disadvantages inherent in the known,., circuits.

Statement of the essence of the invention A control generator of known type, the one with a 1/10 - or not used for display but only for control 1/16 frequency divider works before the first decade of counting, requires one to break -frequency resolution of 10 Ifz as digit width of the lowest displayed counting decade a counting time of 1 s. The counting time of the counter is then> 1 s, since it is the counting time there are still times for saving the results and deleting them. Without that Frequency control could, however, be used with a counting time of 1 s.

The object of the invention is a control generator whose output frequency to one within a frequency range that is not or not significantly larger is, as 1 digit of the least significant decade displayed by a frequency counter, lying setpoint is set and stabilized whose cycle time is not or is only slightly larger than that for a digital frequency counter without additional, Counter elements not used for display, required cycle time.

According to the invention the object is achieved in that a per se known counter sequence control is used, which is a synchronous or quasisynohrone Counting causes the time difference between the end of gate signal and the next Counting event detected by means of a bistable multivibrator and by means of an integrator is converted into a proportional voltage, which during a charging time that is shorter than the counting cycle for charging (or discharging) voltage a charge store is used and that the charging current is also counteracted by a reference current whose value corresponds approximately to the current coming from the integrator for the case where the time difference between the end of the gate signal and the next counting event is equal to half the period of the mean measuring frequency.

The circuit arrangement according to the invention acts so that the voltage of the charge store is changed until the output current of the integrator is equal in magnitude to the current from the reference voltage source, i.e. that the Time difference between the end of the gate signal and the next: counter event roughly the same half a period of the mean measuring frequency.

The frequency of the control generator is thus at the middle frequency stabilized to a value around 0.5 digit of the least significant decade is greater than the frequency that can be read on the frequency counter.

For frequencies higher than the middle frequency, a value stabilized, the more than 0.5 digit of the least significant decade of the displayed Value deviates, for frequencies lower than the middle frequency it behaves vice versa. This dependency can be avoided if provided that either the reference current supplied by the reference voltage source proportional or the charging current supplied by the integrator is inversely proportional can be changed with the measuring frequency.

According to the invention, the required control signal is generated by means of a digital-to-analog converter obtained from some BCD outputs of the most significant counter decades.

In most cases the frequency deviation is 0.5 digit from readable value be insignificant. She can be but also on simple quietly eliminate by taking the one derived from the reference frequency oscillator very precise gate time either through targeted use of the delay times of the Sequence divider of the counting sequence control or by other known ittel m @@ en @ert a hsll @@ eriodem @ outside of the @mttleren requenz is barred.

So with a vorzane'u @ ending new appointment the @requdnz dicse When the desired change is made, the procedure is to ensure that the control loop is operated with the aid of the Stabilization switch can be disconnected, thereby reducing the voltage of the charge store is brought to a mean modulation value.

Another improvement of the invention is that the Integrator a threshold switch is connected, which responds when at the integrator an input pulse is present which is about 90% of the period of the highest frequency of the variable oscillator and that the threshold switch is a monostable Controls the tilting stage, which during its idle time of a few seconds an electronic Switch operated, which interrupts the control circuit and the charge storage to a medium tension.

There is a high probability that a performed frequency tuning occurs a frequency value that the threshold switch can address.

In the event that the stable setting of any frequency is desired, the invention further provides that the gate time extension of the Counter by means of a monostable multivibrator whose service life can be changed by hand in a range of the size of the period of the measurement oscillation and that an indicator is connected to the output of the charging switch, which indicates when the amount of the charging current supplied by the integrator equals the The amount of the reference current, or which of the two current components is in terms of amount the bigger one is. For high demands on the accuracy of the frequency of the control generator the invention also provides that the control element for setting the service life the monostable Tilting stage with a display device (scale) is coupled, which is the deviation of the frequency from the value displayed by the counter indicates. In this case it is possible and useful for operation to adjust the range of variation the service life of the monostable multivibrator is greater than a period of the TC-eating frequency to choose. In order to be able to implement negative gate time changes, expediently shortened by one or a few periods of the reference frequency Gate time assumed what by preprogramming the gate time generating divider chain the sequence control is possible.

The invention also provides that the service life of the monostable Flip-flop can be changed by means of a control voltage and that this control voltage is varied either manually or automatically, in both cases, but specifically with the putomatic variation (wobble principle) it can be useful to set the gate time of the counter n X 10 (n integer) to change to the desired range of variation the. |; frequency (lSobbelhub) and especially with the [obbel short To get counter cycle times.

The invention therefore sees a possibility of changing the Division ratio of the counting chain that is part of the process improvement, which derives the gate time signal from the reference frequency. Of course it has to If the frequency display appears shifted.

For short gate time intervals in which the natural, charging of the The invention continues to see the integrator not finished until the renewed signal suggest that the integrator is reset to its initial state by the counter reset signal is discharged.

So that the counting time variation is independent of the measuring frequency for the same Control voltages always have the same percentage of the period of the measuring frequency makes up, according to the invention continues to be a controllable attenuator in front of the Control input of the monostable multivibrator, which influences the local time signal, switched, its attenuation either directly through some of the most significant BaD outputs of the Tough- lers or by the output voltage of a according to claim 3 provided digital / analog converter is controlled.

Manual operation of the stabilization switch is superfluous to make and still a desired setting that is unhindered by the regulation To ensure frequency, the invention also provides that of the least significant BCD output of the counter a monostable multivibrator is controlled so that it with every change of the logical state of this output a control signal for outputs the stabilization switch designed as an electronic switch, whereby this interrupts the control loop while the monostable multivibrator is inactive and applies a medium voltage to the charge storage device.

Compared to the known with an additional decade counter and D / A converter working generators, the control generator according to the invention has the following advantages: a) No significant extension of the counting time.

b) Any frequency within the last counter digit can be set and stabilizable {interpolation).

c) Setting and stabilizing frequencies outside the digit range possible (extrapolation), as there is no point of discontinuity in the control characteristic of the setpoint is available.

d) No statistical instability in frequency due to digital error.

Stability only depends on the switching times of the components.

e) wobble possibility f) no additional circuits for Stabilization at the boundaries of the digit area required.

EXEMPLARY EMBODIMENTS The invention is illustrated with reference to FIG. 3 in the drawing illustrated embodiments explained in more detail.

1 shows a block diagram of a first exemplary embodiment, that is, the regulation of the oscillator frequency takes place in such a way that between the end of the counting time and the next counter event there is always a constant time difference.

Fip. 2 is a block diagram of a second embodiment, at The gate time of the counter is variable for the purpose of stabilizing any Prequenzen is.

Fig. 3 is a block diagram of a third embodiment, in a defined fine tuning of the frequency or a wobble is possible.

The control generator of the first embodiment consists of one within a relatively narrow sand variable oscillator 1, its frequency also varied in an even narrower range by means of a capacitance diode can be.

The frequency of this variable oscillator is measured by means of a frequency counter, from the counting decades 11 (each counting decade consists of a decimal counter, memory and numeric display), the counter flow control 13 and the counting gate 14 is measured.

The counter sequence control is controlled by a quartz oscillator via its input a 12 and above their entrance b. variable oscillator 1 is controlled and delivers on Output c is a memory signal, which is accepted via input b of the counting decades 11 of the count result in the memory causes a reset signal at output d, the A reset of the decimal counter in theirs via the input a of the counting decades 11 The initial state after the memory transfer and a very precise one at output e (Static) counting time signal for the counting gate 14.

The counting time signal is generated in such a way that it can either be triggered by begins at the same time as the first counting event of the measuring signal (synchronous counting) or that the counting time signal during each cycle by one between the beginning of the counting time and the first counting event occurring initial fall time extended becomes (quasis @ synchronous counting).

The measuring signal coming from the variable oscillator 1 is transmitted via the counting gate 14 applied to the counting input e of the counter decades 11 for the duration of the counting time signal. The L-C-Plcnke of the measuring signal counts as counting event. Through the L-0-Fla.nke of the counting time signal the edge-controlled bistable Lultivibrator 2 is set at the end of the counting time, however already reset by the following L-O edge of the measuring signal, see above that at its output for the short time between the end of the counting time and the next counting event a logical L occurs. An integrator 4 is effective for this short period of time, which generates an output voltage proportional to this time. The output voltage of the integrator goes back to the next Tählzeitendeai @@@ l Aurch Welbst kull.

@a by means of the memory pulse received from the @output @ of the counter sequence control an electrical switch gate 7 is closed, flows for the duration of the storage pulse one a charging resistor 5 one dcr the output voltage of the integrator more proportional Charging current in a charge storage device 8. At the same time, however, this charging current is by the amount of one caused by a Roferenzspannungsquelle 3 over a Charging resistor 6 reduces the current flowing.

At the output of the charge store 8 there is a switch 9 which is in the closed position State a fixed DC voltage coming from the source 10 to the charge storage device and applies to the frequency control input of the variable oscillator 1. The greatness of this DC voltage is chosen so that the capacitance diode of the variable oscillator 1 is in the middle of your dynamic range.

Becomes the stabilization switch after setting any frequency 9 is opened, it is the voltage of the switch 7 during each storage pulse Charge storage device 8 changed until the integrator 4 and the reference voltage source 3 coming charging current components are equal and cancel each other out.

The frequency of the variable oscillator 1 is therefore changed as long as until the time between the end of the counting time and the next counting event is so great that im Integrator creates a voltage that flows in the charging resistor 5 a current sets, which is equal to the reference current flowing in the charging resistor 6, but with reverse sign.

Appropriately, in order to achieve an optimal control range, Reference voltage source 3 and charging resistor 6 dimensioned so that both charging current components are the same if the time difference between the end of the counting time and the next counting event half a period of the mean frequency of the variable oscillator 1 consists. The short-term instability of the frequency of the variable oscillator 1 is then t 0.5 digits.

The permissible long-term instability is determined by the modulation range of the charge storage and the voltage sensitivity of the variable oscillator 1 and can be orders of magnitude larger.

The actual frequency of the variable oscillator 1 is around in this case E digit is greater than the number of displayed digits counted by the counter.

However, if the meter sequence control, e.g. through targeted utilization the delay times of the counting chain are dimensioned in such a way that the counting time signal changes the value of half a period of the P eßfrequency is extended, then the Actual frequency exactly the same as that readable on the meter.

The control generator can then count all frequencies with a counting time of 0.1 s Deliver n X 10 Hz with great long-term stability. The oscillator frequency deviates from the mean frequency, the result is a slightly different actual value of the oscillator frequency, If the frequency is increased by a factor of 1.25 (e.g. from 5 Iv; IHz aug 6.25 I: ffiz), the period is reduced by a factor of 0.8 (in the example of 200 ns to 160 ns). Since the regulation is based on half a period of the mean frequency (100 ns in the example), this means an error of 0.1 = 10 Y0 (in the example 20 ns) of a digit of the least significant counter position.

A counter that works with 0.1 s counting time has a digit width of 10 Hz. The control of the oscillator was then not set to n 7 10 Hz, but rather to n N (10 Hz + 1 Hz), which in most cases will be irrelevant.

For automatic actuation of the stabilization switch 9 can des Embodiment can be supplemented so that the -, stabilization switch as an electronic Switch is executed by the output signal of an -onostable multivibrator 23 is closed. The monostable multivibrator is controlled by means of a threshold switch 24, the Aussprechwelle is placed so that it is at a Responds to the pulse width at the input of the integrator 4, which is here as 90 , J is the period of the highest frequency to be output by the variable oscillator. This ensures that the oscillator frequency is changed by hand with a probability of more than 10 g (i.e. with a cycle time of 0.1 5 for example every second), a time difference between the end of the counting time and the next counting event occurs, which is so large that the threshold switch 24 responds and via the monostable multivibrator 23 the Te gelung for a few seconds - according to the Service life of the monostable i? Iultivibrator 23 - interrupted. During this time the frequency can be set in a bin that is not influenced by the control will. In addition, the voltage of the charge storage device is automatically set to a medium level Bringing value and thus ensuring a symmetrical control range, which is synonymous is with optimal conditions for long-term instability.

In embodiment 2 the circuit is changed so that the extension the counting time by means of a monostable lultivibrator 16 of variable standing time in the range 0 - 1 period of the lowest frequency of the variable oscilloscope author 1 and one CR-Gatters 15 is pre-rusted.

The variable (dynamic) counting time interval thus generated becomes except the counting gate 14 and the bistable multivibrator 2 also the input f of the counting down control fed, because from its end the further control impulses for the Count whose are derived.

The exemplary embodiment also provides an indicator 17 which can be seen whether the sum of the two charging currents through the resistors 5 and 6 is flow, zero, positive or negative.

The stabilization of any set frequency of the variable Oscillator 1 is done so that by manually changing the service life of the monostable Lultivibrators 16 the display "buzzing current = O = on the indicator 17 is brought about. By actuating the two-pole stabilization switch 9, the control loop is then activated closed by contact a and the frequency held at the set value. Contact b of the stabilization switch causes the indicator to be disconnected 17 from the charge store 7 in the event that the input of the indicator 17 is insufficient is high resistance.

To maintain an optimal operating point for the regulation, the is given when the setpoint value, which is provided by the reference voltage source 3 and the Charging resistor 6 is determined, an input pulse of half the period corresponds to the frequency of the variable oscillator 1 is in the embodiment a correction of the sensitivity of the integrator as a function of the Digital counter determined frequency by means of the output voltage of a D / A converter 22 is provided, depending on the width of the frequency range of the variable oscillator 1 the signals of only some of the most significant]? CD outputs-of the digital counter processed.

The embodiment 2 represents a control generator with a Frequency accuracy of + 1 digit of the least significant counting decade (plus the caused by the - the quartz oscillator 12 adhering - relative errors Error), which can be stabilized at any set frequency.

The additions result in a further increase in accuracy of the third embodiment. The monostab @ le ultivibrator 16 is designed here in such a way that the service life is changed by means of a control voltage will. Thick control voltage supplies a local DC voltage source that can vary from country to country 18, which has a frequency scale calibrated in frequencies that shows the digital error of the meter shows exactly.

The advantage here is that the scale is not on values within a Digits must remain limited, but that an overflow after tjinuswerte and after Values over 10 is possible. It makes sense to give the scale, for example, a range of numbers from -2, -1, 0, 1 ... 10, 11, 12.

The number 0 corresponds to an extension of the static counting time signal by half a period of the measuring frequency and the number 10 a shortening by one half the period. The shortening of the static counting time signal is thereby achieves that the counter sequence control has a counting chain preprogrammed by 1 digit contains and thus a shortened by one period of the frequency of the crystal oscillator 12 Payment time signal is formed by the service life of the monostable multivibrator 16 is supplemented to the required value of the dynamic counting time signal.

About the increased measurement accuracy within the entire frequency range To be able to guarantee the variable oscillator 1 is a frequency-dependent control both the output voltage of the DC voltage source 18 and the integrator 4 (it would be equivalent to control the reference voltage source 3 or one of the charging resistors 5 or 6) required. As in the second exemplary embodiment, the output voltage is used for control of the D / A converter 22 is used, depending on the desired accuracy, possibly more BCD outputs of the meter are to be evaluated. Influencing the output voltage of the DC voltage source 18 takes place by means of a controllable attenuator 21.

Furthermore, the embodiment provides that the voltage of the DC voltage source 18 with the aid of a switch 20 through the output voltage a triangle generator 19 can be replaced. This becomes a periodic one in time the counter changes the frequency in steps of variable oscillator 1 reached with the control loop closed (switch 9 open).

On the one hand to keep the increments small and on the other hand To obtain a larger wobble stroke, it makes sense to use the wobble mode with work at a much shorter beat. The counting time is switched on controlled by the switch 20 via the input g of the counter sequence control.

In order to safely discharge the integrator with the short counting time To ensure until the next pulse, it is also provided that the integrator by the counter RL1.ckstellipuls coming from output d of the counter sequence control is discharged.

In the same way as in the first exemplary embodiment, there is also an automatic one here Actuation of the stabilization switch 9 when changing the frequency manually of the oscillator 1 is provided. The control of the, the time-limited separation The monostable flip-flop 23 effecting the control loop takes place here through the outputs c and d of the counter decades, which å each emit a signal when the level of the lowest fourth BCD output of the lowest decade counting from 0 to L or changes from L to 0, i.e. each time the counter result changes, the cause of which is usually only a quick one due to the effective regulation Hand made, frequency change can be.

Claims (12)

P a t e n t a n s p r ü c h e 1. Frequency stabilized control generator, its output frequency can be set as required within a certain frequency range and is readable from a digital frequency counter, with one with regard to its frequency controllable variable oscillator and a reference frequency oscillator for generation the gate time of the frequency counter and a device for generating a charging voltage (current) for a charge storage device that controls the frequency of the variable oscillator as a function of a deviation of the oscillator frequency from a setpoint value, the within a frequency range the size of one digit of the least significant is indicated by the frequency counter decade, characterized in that for the digital I "frequency counter a per se known number is used which causes a synchronous or quasi-synchronous count that the time difference between the end of the gate time and the next counting event by means of a bistable Flip-flop detected and converted into a proportional voltage by means of an integrator that is used during a charging time that is shorter than the payment cycle as a charging (or Discharge: voltage of a charging storage device is used and that the charging current is also a Reference current is connected in the opposite direction, the value of which is approximately that coming from the integrator Current corresponds to the case in which the time difference between the gate time end signal and the next counting event is equal to half the period of the mean Hess frequency is. 2. Control generator according to claim 1, characterized in that the The reference current flowing into the charge storage is proportional or that of the integrator incoming charging current changed inversely proportional to the period of the measuring frequency will. 3. Control generator according to claim 2, characterized in that the from the period duration of the measuring frequency reducing control signal by means of a digital-to-analog converter is obtained from only a few of the most significant 0D outputs of the frequency counter is controlled. 4. Control generator according to one of claims 1 to 3, characterized in that that the very accurate gate time derived from the reference frequency oscillator either by utilizing the delay times of the frequency divider of the counter sequence control or by other means known per se by the value of half a period the reading frequency is lengthened. 5. Control generator according to one of claims 1 to 4, characterized in that that a threshold switch is connected to the integrator, which is a monostable Controls the flip-flop that actuates an electronic switch during its idle time, which interrupts the control loop and the charge equalizer to a medium voltage lays. k control generator according to one of claims 1 to 3, characterized in that that the gate time of the counter can be changed by hand in its service life monostable multivibrator can be changed and that to the output of the load switch for the charge storage an indicator circuit is switched on, which responds, if the amount of the charging current supplied by the integrator is equal to the amount of the Reference current and, in the event of inequality, indicates which of the two currents is the larger is. 7. Frequency stabilized control generator, its output frequency adjustable within a certain frequency range and on a digital one Frequency counter can be read, with a variable that can be controlled with respect to its frequency Oscillator and a reference frequency oscillator for generating the gate time of the frequency counter and a device for generating a charging voltage (current) for a the variable oscillator in its frequency controlling charge storage depending on a deviation of the oscillator frequency from a nominal value, which lies within a frequency range approximately the size of a digit corresponds to the least significant decade indicated by the frequency counter, in particular according to one of claims 1 to 3, characterized in that the dividing chain for Generation of the gate time signal is preprogrammed so that a Uì5.L one or a few Periods of the reference frequency shortened iDor time and that this gate time is extended by means of a monostable tilting stage with selectable service life and that the control element for changing the service life is coupled to a scale, which is calibrated in such a way that it shows the deviation of the frequency from that of the frequency counter displayed value can be read. 8. Control generator according to claim 7, characterized in that the Service life of the monostable multivibrator changed by means of a control voltage (current) can be and that a changeover switch is provided through which the control voltage input either to a voltage that can be set by Iland or to an automatically changing voltage is placed. 9. Steuergenerator. Gate according to claim 7 or 8, characterized in that, that the gate time in the ratio n 7 10 can be switched and at the same time a Shifting of the comma of the frequency counter is made. 10. Control generator according to one of claims 1 to 9, characterized in that that the integrator was in the status of its output due to the counter reset signal is discharged. 11. Control generator according to claim 8 or 9, characterized in that that in front of the control input, the monostable multivibrator that changes the gate time signal, a controllable attenuator is switched, its attenuation either directly by some of the meter's most significant BCD outputs or by the output voltage one according to qn- Spruch 3 vogesehenen digital / analog converter controlled will. 12. Control generator according to one of claims 7 to 11, characterized in that that through the lowest value BCD output of the counter a monostable multivibrator is controlled in such a way that every time the logical state of this output changes a control signal for the stabilization switch designed as an electronic switch releases, whereby this during the standing time of the monostable flip-flop the Re The circuit is interrupted and the charge storage device is applied to a medium voltage.