DE2038694C3 - Circuit for automatic transmitter search in telecommunications equipment with capacitance diode tuning - Google Patents

Description

The invention relates to a circuit for electronic viewing Tuning and automatic station search in telecommunications equipment, especially radio receivers, with varactor diode tuning, in which the tuning voltage for the varactor diodes the intermediate and oscillator circuits of a tuner analog depending on the load of one to one Operating voltage source connected, controlled chargeable capacitor is changed, the Charging of the capacitor depends on the frequency of the output of an intermediate amplifier! Demodulator tapped differential voltage, which depends on the detuning size and direction is dependent, can be changed by indirect superposition.

In such tuning devices, the t, o frequency tuning of the high-frequency circuits is carried out by capacitance diodes which change their capacitance as a function of the applied voltage, the capacitance decreasing with increasing voltage, so that the frequency increases. The frequency is therefore a function of the applied voltage, and the junction capacitance of the tuning diodes can be controlled with a corresponding voltage. When the voltage is taken from a voltage divider, it is increased or decreased by changing the voltage divider ratio. The fixed transmitter and continuous tuning are based on this principle. However, it has also already been proposed to change the voltage by means of automatically operating devices. One possibility is to control the tuning potentiometer accordingly by means of a motor. Search circuits have also become known in which the tuning voltage is changed purely electronically high frequency and then jumps back to the lower frequency after reaching the end frequency. Do you want z. If, for example, you set a lower frequency than the one already set, you must run through the entire frequency band by pressing the function key until you have found the desired frequency, starting from the lowest frequency. This disadvantage is to be avoided by the invention.

From DT-OS 18 17 378 a circuit for station search in superimposition receivers is known, in which the search process when receiving a station that is worthy of reception is ended in that a direct voltage dependent on the transmitter a ballast transistor shunted to the capacitor switches on, and for which automatic armed tuning starts after the search run has ended, which acts on the ballast transistor. This circuit is characterized in that as a direct voltage instead of the control voltage for the automatic sharpening, which is achieved by rectifying the intermediate frequency voltage obtained, by special means kept constant DC voltage is used over the Bridge diagonal of the control voltage generator for automatic setting as switching voltage the ballast transistor is supplied.

The circuit has the advantage over the first-mentioned circuit that it enables sharp tuning is possible, but it only allows a search in one direction, i. that is, the capacitor only charged in one direction, but not necessarily by pressing a search switch in the other direction is unloadable. To set a defined frequency below the set must therefore the entire frequency band can be traversed by charging the capacitor in order to start again with Charge the capacitor to set the desired frequency. The circuit can't either, sender to be caught automatically, since no means are provided that the opening or blocking state of the charging transistor maintained until the next sender arrives.

A similar circuit is the subject of US Pat. No. 3,467,870, in which the automatic search also only takes place in one direction by using a capacitor that changes the voltage across the capacitance diode is only chargeable in one direction, which is to be avoided by the invention, so a fast, easy finding of individual stations is made possible.

In the DT-OS 18 17 377 a circuit for station search in superimposition receivers is described, in which the search run not only always in the same direction, depending on the charging of the capacitor

occupies, but also in reverse can be done to a transmitter to switch over, which is close to the set one, but only with a lower capacitor voltage is adjustable. In the disclosed circuit, a second switch position is used for optional reverse running the key or with a second key to the sole key or an additional key to both keys Associated contact pair with which a circuit can be switched on, whose current after releasing the button is held and generates a voltage in a resistor, which the ballast transistor in the sense of a stronger discharge current controls until the occurrence of a worthy transmitter by the result occurring DC voltage the mentioned circuit is interrupted again. This circuit arrangement allows charging and discharging of the capacitor that changes the voltage across the capacitance diode, however, the circuit has a different structure than that formed according to the invention Circuit arrangement on and does not allow a search for stereo stations or a setting by means of Preset memory. This should be the case with the circuit arrangement designed according to the invention also be possible.

A method for automatic station search with the help of voltage-dependent capacitances in the tunable Resonance circles of a receiver is described in DT-PS 1171964, in which the The discriminator of the receiver is designed so that the polarity of the output voltage as a function of Frequency assumes a so-called »S-curve«, which voltage is exceeded when a defined one is exceeded Response threshold actuates a switch that adjusts the voltage at the charging capacitor to a corresponding one Adjusts the value so that the receiver is tuned so that the intermediate frequency is sufficiently accurate Center frequency corresponds to the discriminator curve, whereby a sharp tuning is guaranteed. This circuit allows individual transmitters to be found properly and also allows for sharp tuning this transmitter. Finding special stereo transmitters is not possible due to the circuit arrangement enables. Voting using the preset memory is also not possible.

A circuit for finding stereo stations is described in DT-OS 20 23 352. This arrangement has a switchable pilot signal detection circuit, such that the automatic station search function If the pilot signal detection circuit is switched off, each transmitter worth receiving is set and when the Pilot signal detection circuit only adjusts the transmitters that are triggered by a transmitted pilot signal Marked are. To find the individual transmitters, the entire frequency band must always be run through will. A setting in the other direction from a station that has already been found is not possible. since the circuit does not discharge the capacitor that determines the tuning voltage is possible

The invention is based on the stated disadvantages of known circuits avoid by designing the circuit so that they Sharp tuning enables mono and stereo broadcasts found together or separately finds and records and enables a vote by means of preset memory

This object is achieved in a circuit of the type mentioned in that the capacitor is connected to the non-inverting input of an operational amplifier, the output of which on the one hand via a negative feedback circuit with the second, s inverting input and on the other hand with one Switching amplifier is connected to which the demodulator output is also connected, of which Differential voltage of the switching amplifier is regulated, and which switching amplifier is controlled via a control input

ίο when actuating a switch by changing the to The voltages applied to the inputs can be optionally controlled in such a way that the search run is triggered Capacitor via semiconductor current generators, which are used to charge or discharge the capacitor with it

, c and at the operating voltage source as well as the Switching amplifier are connected, charged or discharged, the switching amplifier when changing the The voltage at the control input switches off in one potential direction (negative), which causes the charging process of the capacitor is triggered via the operational amplifier, and that the charging process is interrupted becomes, if the search runs on a transmitter and at the demodulator output a differential voltage of a such a potential and such a size that the switching amplifier via a control loop in reverse Sense is activated, and that when the search run is activated in the other potential direction (positive) the switching amplifier becomes conductive and the discharge process of the capacitor is triggered via the operational amplifier, which is discharged until the search laul meets a transmitter, and a differential voltage with the first opposite potential at the demodulator output is applied, which causes a temporary blocking of the switching amplifier.

Further developments of the invention are described in the subclaims.

The invention is explained in more detail below with reference to two exemplary embodiments that are shown in FIGS Illustrations are shown. From these illustrations shows

F i g. 1 the scheme of the entire circuit structure for a search circuit according to the invention,

F i g. 2 an embodiment of the invention Search circuit with operational amplifier and preset button device, omitting the Intermediate frequency part and the demodulator part,

F i g. 3 a field effect transistor with its circuit as a replacement for the semiconductor current generator D1 ir Fig. 2,

F i g. 4 the voltage curve at the output de; Demodulator for three different incoming transmitters with the entered threshold voltage UX,

F i g. 5 a schematic representation of the upward and downward movement of the search voltage over five different transmitters, after the transmitter 2 eir return of the vote on the transmitters 3 and 4 unc then in turn there is a run-up to the tuning of the transmitter 5, and

F i g. 6 shows a circuit implementation with a discriminator in the demodulator without using a Preset button setup.

From Fig. 1 is the basic structure of the fiction according to the search circuit. From dei

For the receiving antenna 1, the oscillations reach the tuner 2 with the symbolically represented capacitance diodes Ki, K 2 for the purely electronic tuning of the receiver. From tuner part 2 di <

Oscillations via the intermediate frequency part 3 into the demodulator 4, at the output of which the low-frequency voltage (differential voltage) is taken, and via the line 6 to the series resistor R 10 of the transistor T2 in the search part 5. A varying DC voltage is fed back from the search run part 5 to the capacitance diodes of the tuner part 2, depending on the transmitter tuning. In stereo reception, the low-frequency voltage of the demodulator 4 is also fed through the decoder 7 to the transistor stage T4 of the search part 5, whereby z. B. the search tuning is only possible on stereo stations when the preselection switch 53 is in the "search stereo" position. The function of the search part 5 is explained in detail below with reference to FIG. The following circuit functions are to be described one after the other:

A. Search for any station (mono and stereo stations).

A. 1. Preliminary
A. 2nd return

B. Search only for stereo channels.

G Station selection through preset buttons or continuous Hand vote.

D. Automatic frequency adjustment when coordinated according to C.

A. 1. Forward

If the device is switched on and the switches 51 and 52 are in the "search run" position, as indicated by the arrows, the device first sets itself to the transmitter with the lowest frequency, i.e. That is, the charging capacitor C 1 receives a charge of the lowest direct voltage, namely via D 1 corresponding to a station with the lowest frequency.

The adjustment and retention of the transmitter set by charging the capacitor C1 takes place by the differential voltage that is present at the demodulator output on line 6 (see. Fig. 1). in the the following happens:

Briefly tapping the rocker switch SW in the "Forward" position temporarily blocks the transistor Tl, which works as a switching amplifier. The capacitor CX, the voltage of which is decisive for the respective tuning, is charged via the field effect diode Dl. The positive charging current is tapped at the resistor R1 and then further amplified in the subsequent operational amplifier V. The resistor R1 is connected to the non- inverting input of the operational amplifier V, the output of which is connected to the inverting input of the operational amplifier V via a negative feedback branch with a resistor R β Operational amplifier V is tapped from a voltage divider R 21 R 3 also connected to the same output voltage and applied to the emitter of transistor Ti.This positive bias voltage at the emitter of Tl maintains the blocking state of transistor Tl previously initiated by rocker switch SW When searching for a transmitter, it generates a direct voltage at the direct voltage output 6 of the demodulator 4 (see FIG. 1), which has the specified S-curve form in accordance with FIG. 4. FIG. 4 shows the voltage curve for three different transmitter settings ellt, and you can see that these different transmitters come in different strengths. Two of these transmitters go with their voltage curve above the threshold voltage UX , whereby they are detected by the search circuit. All other transmitters that reach a demodulator voltage that is below UX are not detected by S of the search circuit

The direct voltage tapped by the demodulator 4 (FIG. 1), which corresponds to an incident transmitter, is applied to the transistor T2 (see FIG. 2) via R 10 and conducts it with reversed polarity via its collector and the

ίο Resistance R 11 to the base of the transistor Tl. If this positive DC voltage at the base of Tl is so large that it cancels the blocking effect of the DC voltage UX at the emitter of Tl, the charging process of the capacitor Cl is interrupted because the transistor Tl begins to become conductive. An interruption of the charging process with the result that the voltage across the resistor / 71 at the input of the operational amplifier V, and thus the voltage at the output of the operational amplifier V to 0 V decreases The voltage tapped off at the voltage divider R2IR 3, so that the emitter voltage of the transistor Tl, thus also goes back to 0 V. The operational amplifier V is no longer involved in the subsequent exact adjustment and adjustment of the search run to the target frequency (intermediate frequency)

This adjustment to the exact respective tuning voltage is taken over by the transistors T1 and T2. If the frequency-voltage characteristic has the specified polarity (cf. the S-curve voltage on line 6 in accordance with the diagram shown under resistor R 10), the voltage at the demodulator output will become more negative when the frequency increases. This makes the voltage at the collector of T2 more positive, which also makes the base voltage of T1 more positive and thus opens the transistor T1, ie switches it on. When the transistor T1 becomes conductive, the voltage across the capacitor C1 drops. Such a decrease in the voltage on the capacitor C1 and thus also on the capacitance diodes in the tuner 2 causes the frequency to decrease. The frequency will therefore approach the setpoint frequency again, since the frequency change is contrary to the frequency increase assumed above. If, on the other hand, the frequency falls, the control process runs in the opposite direction. It is important for this control process that the frequency-voltage characteristic at the demodulator output has the specified course (cf. the two S-curve diagrams on the right at the edge in FIG. 1 and FIG. 2).

A. 2. Rewind

When switching the device to return by briefly pressing the rocker switch SW to the right as indicated by an arrow, an opening

ss ie making the transistor T1 conductive. The capacitor C1, which is decisive for the coordination of the capacitance diodes, will thus be discharged. A second field effect diode D2 is located in the collector circuit of the transistor Ti so that this discharge process does not happen suddenly.

Field effect diodes keep within a certain voltage range (working area of the diode)

6s depending on the applied voltage the current is constant when charging a capacitor over such a capacitor Field effect diode, which thus represents a current generator, so the voltage across the capacitor becomes linear.

increase over time. If you discharge a capacitor through a field effect diode, the voltage will decrease linearly with time. The present circuit of the invention makes use of this principle. The field effect diode D 2 in the collector circuit of transistor Tl s limits and accordingly keeps the discharge current constant.

If the discharging process is to take place with the same time constant as the charging process, a diode with twice the operating current as the diode Di must be selected for D 2 . The diode D 2 will then take over the current that flows through D 1 and draw an equally large current from the capacitor CX . The negative discharge current causes a voltage change at RX and the operational amplifier V. This amplifies the signal and emits a negative voltage at the output, that is to say at the resistor R 3, which maintains the conducting state of the transistor T1. Only a negative voltage at the base of Tl, which is so great that it blocks the transistor Tl, interrupts the discharge process of Tl. This means that the voltage at RX and A3 will again drop to 0 V, and it is the same state as before Adjustment of the frequency is achieved, so that the further control process proceeds as previously described for the advance. At the base of the transistor Tl, for. B. a silicon transistor, about 0.7 V should be present in the regulated state (opening voltage for silicon transistors). This voltage is set by means of the resistor R 7 . The setting is made through a special calibration process by applying a high-frequency voltage to the high-frequency input of the receiver.

In order to influence the responsiveness of the device, the resistor R 3 (see FIGS. 2 and 6) is designed to be adjustable. By varying this resistance A3, the stop sensitivity of the search run can be changed as required. An increase in the resistance R 3 causes the voltage at the emitter of the transistor Tl to also increase when the capacitor CX is charged or discharged. Since the differential voltage at the demodulator output 6, which occurs via transistor T2 at the base of transistor T1, is field strength-dependent in the event of detuning, the search run is also maintained depending on the field strength. Only directional voltages at the base of Tl, which are so great that they cancel the effect on the voltage at the emitter of Tl, bring the search to a standstill.

B. Search only for stereo channels

Switching to "Search Stereo" is done by opening the Scha'iers 53. This causes the short circuit is removed from resistance RA and the threshold set so high that the magnitude of the differential voltage is no longer sufficient to hold the search SS run Assuming that the transistors T3 and T4 are blocked and are only activated by a control signal from the pilot output of the stereo decoder 7, the search run on a stereo transmitter is initiated when the pilot signal opens the transistor T4.The collector of T4 becomes positive and controls the field effect transistor T3 , T3 thus short-circuits the resistor RA , the response threshold of Tl is reduced, and the search comes to a halt. The rest of the process is as described under A.

C Station selection using the preset buttons or continuous manual tuning

By operating the switches 51 and 52 (see Fig. 2) the tuning diodes KX, K2 are connected to the push-button transmitter selection switch DS . Any previously set station can be selected by pressing one of the key switches 10 to 15. The capacitor CX charges itself to the voltage U2 via the diodes D 5 or D6 and prepares the search run for an automatic frequency control.

D. Automatic frequency control
when voting according to C.

The automatic frequency control is switched on by means of switch 54. The operating voltage for the push button switch DS is then supplied by the capacitor CX. However, since this capacitor voltage is controlled as a function of the frequency by the differential voltage of the demodulator, an automatic adjustment to the setpoint frequency also takes place. The diodes D 5 and D 6 limit the catch and hold range of the retuning device.

In Fig. 3 shows the circuit arrangement of a field effect transistor T5 with the resistor Ä20. This circuit element can be set as a unit in place of the semiconductor current generator having the field effect diode DX.

In Fig. 4 shows the voltage profile at the output of the demodulator 4 (see FIG. 1) for three different incoming transmitters. The threshold voltage for the advance of the search device is indicated by + UX and for the return with - UX. All incoming transmitters whose voltage is below this voltage level UX are not detected by the search device.

In Fig. 5 shows the course of a search movement for five different stations. The time r is shown on the abscissa and the voltage UCX on the charging or discharging capacitor CX is shown on the ordinate. It can be seen that the voltage on the charging capacitor CX initially rises until the sufficient voltage of the received transmitter 1 is sufficient to hold the charge on the capacitor CX . The transmitter 1 is received. By tapping the button 5 W (see Fig. 2) on the advance, the voltage on the capacitor CX continues to rise until the next transmitter 2 is received and the voltage on the capacitor C1 is kept constant again by influencing the transistors T2, T1 accordingly. The reception of transmitter 2 is thus assured. If you want to let the search run back again, you press the 5VV button in the return position, and the return movement is switched on accordingly, i.e. the voltage on the capacitor CX now decreases until the corresponding receive voltage of the transmitter 3 is at the demodulator output makes noticeable, so that now when the transmitter 3 is received via the transistors T2 and Tl, the charge on the capacitor Ci is retained . In the same way, the transmitter 4 can be reached by further tapping the button 5VK on return, to which the transmitter 5 can then connect when the button 5VV is again tapped in the forward position.

A circuit arrangement for the search device 5 (see FIG. 1) is shown in FIG in the event that a ratio or discriminator circuit is used for the demodulator 5. In contrast to FIG. 2, the FIG Transistor T2 has been omitted, since discriminator 20 has a DC differential voltage of 0 at the soli frequency

V supplies at point O , to which a voltage of approx. 0.7 V of diode D 7 is added. This voltage of 0.7 V is necessary for the precise frequency adjustment at the base of transistor TX. In the previously described circuit according to FIG. 2, the voltage supplied by the demodulator is greater than 0.7 V and must therefore be brought to the required voltage value of approx. 0.7 V at the base of transistor TX by interposing a transistor T2 . It can be seen from the circuit arrangement according to FIG. 6 that the transistor T2 is accordingly omitted here. The demodulator, ie the discriminator, works directly on the base of the transistor TX. The remaining circuit arrangement in FIG. 6 is constructed in the same way as in FIG. 2, with the only difference that the push-button transmitter selection switch DS is omitted for the sake of simplicity. With regard to the search run, the circuit arrangement works in the same way as in connection with FIG. 2 described.

A control signal for a muting circuit during the search can be taken from the output of the amplifier V via the resistor R 13 (cf. FIGS. 2 and 6).

In summary, the advantages of the circuit according to the invention are briefly highlighted:
1. Any station selection by tapping a switch that z. B. can also be operated by remote control;
2. Continuous forwards and backwards at will,

without having to jump to the starting point;
ίο 3. Accurate capture and retention of the desired transmitter, which also compensates for frequency drifts in the receiver;

4. Possibility of only being able to search for stereo stations using the preselection, with mono stations using the Control signal for mute tuning cannot be heard while searching;

5. By using modern switching means, such as. B. monolithic operational amplifiers and field effect diodes as power generators, the circuit is extremely simple and ready for production and comes with little adjustment work.

For this purpose 4 sheets of drawings

Claims (13)

Patent claims: 1.Circuit for electronic tuning and automatic transmitter search in telecommunications equipment, in particular radio receivers, with capacitance diode tuning, in which the tuning voltage for the capacitance diodes of the intermediate and oscillator circuits of a tuner changes analogously depending on the charge of a controlled, chargeable capacitor connected to an operating voltage source The charge of the capacitor is frequency-dependent on the differential voltage tapped from the output of a demodulator connected downstream of an intermediate frequency amplifier, which is dependent on the size and direction of the muting, can be changed by indirect superimposition, characterized in that the capacitor (Ci) is connected to the non-inverting input of a Operational amplifier (V) is connected, the output of which is connected on the one hand via a negative feedback circuit to the second, inverting input and on the other hand to a switching amplifier which is connected to the Demodulator output is connected and is regulated by its differential voltage, and which can be optionally controlled via a control input when a switch (SW) is operated by changing the voltages applied to the inputs in such a way that the capacitor (Ci) via semiconductor current generators ( Di, D2), which are connected to the capacitor (C 1) and to the operating voltage source and the switching amplifier for charging or discharging, is charged or discharged, the switching amplifier in one potential direction when the voltage at the control input changes (negative) switches blocking, whereby the charging process of the capacitor (Ci) is triggered via the operational amplifier (V) , and that the charging process is interrupted when the search runs on a transmitter and a differential voltage of such a potential and such at the demodulator output (6) Height is applied that the switching amplifier is controlled in the opposite direction via a control circuit t becomes, and that when the search run is actuated in the other potential direction (positive) the switching amplifier becomes conductive and the discharge process of the capacitor (Ci ) triggers via the operational amplifier (V) , which is discharged until the search run hits a transmitter and a differential voltage with the first opposite potential is present at the demodulator output, which causes a temporary blocking of the switching amplifier. 2. A circuit according to claim 1, characterized in that either field effect diodes (DX, D 2) or field effect transistors (T5) are used as a semiconductor current generator as a source for the charging or discharging current, in the latter case the control electrode of the field effect transistor (TS ) is connected to the gate connection via a resistor (R 20) connected in series with the source connection and that the semiconductor generator thus formed enters the charging or discharging circuit with its source-Draue connections in series with the capacitor ( C i) is switched. 3. A circuit according to claim 2, characterized in that the current generator (D 2) for keeping the discharge current constant has an internal resistance that differs from the current generator (DX) supplying the charging current such that the discharge current is twice as large as the charging current, so that On the one hand, the charging current flows through it and, on the other hand, the discharging current of the capacitor (CX) flows simultaneously ■ ο 4. Circuit according to one of the preceding Claims, characterized in that the switching amplifier is designed in two stages and consists of a transistor (TX) of the npn type and a further upstream transistor (T2) of the npn type for reversing the polarity of the voltage tapped at the demodulator output (6) 5. Circuit according to one of claims 1 to 3, characterized in that when using one Discriminator (20) is designed as a demodulator (4) of the switching amplifier and is made in one stage a transistor (Tl) whose base is connected to the demodulator output (6). 6. A circuit according to claim 5, characterized in that the transistor (T I) with its base to a changeover switch (SW), the z. B. is designed as a rocker switch, is connected such that when the switch is operated in one direction, the base-emitter potential or base-collector potential of the transistor (Ti) is changed by making a direct connection so that it is briefly blocks or opens, and that the transistor (Ti) is kept in the selected switching state via the operational amplifier (V) until a sufficiently large differential voltage of opposite potential is applied to the control input at the demodulator output, which is the base potential of the transistor switched on or off (Tl) changed in such a way that the effect of the control voltage of the operational amplifier (V) on the transistor is canceled, and that the tuning voltage on the capacitor (Ci) corresponds to the tuning voltage corresponding to the set transmitter. 7. Circuit of claims 1-3, 5 or 6, characterized in that the response sensitivity can be adjusted by changing the voltage (UX) at the emitter of the transistor (Ti) by means of a controllable resistor (R 3). 8. Circuit according to one of claims 1-7, characterized in that for tuning to stereo transmitters the voltage present at the switching amplifier input connected to the operational amplifier (V) can be changed by means of an electronic switch connected in parallel to the voltage divider ans.s connected to ground at the input, if a control signal is present at the pilot output of a stereo decoder (7), which stereo decoder (7) is connected to the electronic switch. 9. A circuit according to claim 8, characterized in that the control signal from the pilot output of the stereo decoder (7) is fed to the emitter of a bipolar transistor (T4) whose collector is connected to the gate of a field effect transistor (T3) which is parallel to a resistor fts (R 4) of a voltage divider (R 2, R 3, R 4) is connected, which is connected to the operational amplifier (V) and to which one input of the switching amplifier is connected, and that the Resistance ratio of the voltage divider when receiving a stereo transmitter is changed by conducting the field effect transistor (T3) in such a way that the response threshold is reduced to the value also required for mono reception. 10. Circuit according to one of claims 1-9, characterized in that the voltages for the search are set by a bilateral threshold value limiter made up of two anti-parallel connected diodes (D 3, D 4) which are connected to an operating voltage source on the one hand and to the capacitor (on the other hand). CX) are connected. 11. Circuit according to one of the preceding claims, characterized in that a switch with several switching contacts is provided for the fixed transmitter tuning, via the one switching contact of which for charging the capacitor (CX) the operating voltage source (Uz) via a two-sided threshold value limiter with the diodes (D5, D6 ) to the capacitor (Cl) is completed and via its second shaft contact the tuning unit with the capacitance diodes (K 1, K 2) can be switched to a potentiometer memory with optionally connectable voltage dividers, which potentiometer memory is connected to the capacitor (C \) and the tuning voltage divides according to the setting of the individual potentiometers. 12. A circuit according to claim 11, characterized in that an AFC switch is provided by means of which the voltages applied to the potentiometers of the potentiometer memory for different charging of the capacitor (CX) are switched through to this. 13. Circuit according to one of claims 1 - 12, - ^ characterized in that a frequency display calibrated measuring instrument for the respective tuning voltage is connected to a tap between the two current generators (DX, D 2).