DE1616885C - Circuit arrangement which, in response to a frequency-modulated input signal fed to it, emits an output voltage, the amplitude of which depends on the frequency of the input signal - Google Patents

Description

supplies falling or rising output voltage, the amplitude of which depends on the interval between the pulses emitted by the trigger signal generator, and that the function generator a positive and negative by the output from the pulse generator Pulse-controlled sampling amplifier is connected downstream of the output from the function generator Output voltage as a function of the pulses emitted by the trigger signal generator scans in such a way that it is sent to a memory device upon occurrence of the from the trigger signal generator The output pulses correspond to the amplitude of the function generator output voltage Voltage supplies, wherein the step-shaped output voltage of the storage device in a through the voltage-time function of the function generator given relationship to the frequency of the frequency-modulated input signal.

Such an arrangement has the advantage that a certain, arbitrarily selected functional dependency between the frequency-modulated input signals and the signal generated by the circuit ^{device r} . generated output voltage can be produced. In particular, the dependency given by the function generator can be selected so that the output voltage is proportional to the respective frequency of the frequency-modulated input signal.

Further details and advantages of the invention are illustrated in the drawings with reference to the exemplary embodiments explained. It shows

F i g. 1 is a block diagram of the demodulator circuit according to the invention,

F i g. 2 based on an input signal from the individual assemblies of the invention Demodulator circuit output signals, F i g. 3 shows the possible structure of the in FIG. 1 shown demodulator circuit provided trigger signal generator,

F i g. 4 a possible implementation of a pulse generator in the demodulator circuit shown in FIG can be applied

F i g. 5 a new function generator, which is shown in FIG. 1 is used will,

F i g. 6 shows the possible structure of the in FIG. 1 provided keyed demodulator circuit shown Amplifier,

7 shows an embodiment of one in the in Fig. 1 shown demodulator circuit applicable memory device,

F i g. 8, a low-pass filter which is used in the in F; G. 1 shown Demodulator circuit can be applied.

In order to achieve the above-mentioned object on which the invention is based, the invention has Set up a function generator, which is based on the frequency of an input signal emits changing output signal of corresponding amplitude. In the described embodiment of the Circuit assembly according to the invention is a voltage with a function generator generated hyperbolic or exponential curve, i.e. the temporal curve of this voltage is sufficient a hyperbolic or exponential function. It's of course within the scope of the invention, others To use types of function generator to demodulate other input signals which change in frequency. Which deal with the frequency The voltage that changes the input signal and is output by the function generator is detected by a sampling device scanned, which is one of the instantaneous voltages present during scanning transfers proportional current of a storage device. At about the same moment that the voltage of the function generator is sampled

ίο will, or a brief moment afterwards, will the function generator is reset, whereupon it begins to generate another output signal in the form of a to generate a new output voltage. The function generator is scanned and reset in one of the frequency of the input signal or in one of the modulated carrier signal proportional ratio. Since the sampling is proportional to the modulated carrier signal Relationship takes place and because the voltage generated by the function generator is constantly changing changes according to the prescribed function, it follows that that of the sense amplifier device supplied voltage is proportional to the frequency of the modulated carrier signal. Accordingly stand the

»5 from the scanning device to the storage device transmitted current pulse and the frequency of the modulated carrier signal in a proportional relationship. The cooperation of the function generator, the scanning device and the storage device in response to an input signal constitutes an important part of the present invention represent.

Let it now be the case in FIG. 1 illustrated block diagram. Some of those provided in this arrangement special circuits are known and it should be noted that it is within the scope of the Invention is in place of the circuits shown in Figs. 3 to 8 and described below to use other known circuits.

The in F i g. 1 is used as an input signal, when used in a video recording device, a device recording measured values or other tape recording devices, an amplitude-limited * re

frequency-modulated signal supplied. The amplitude of such a signal is either through a limiting circuit kept at a certain value or stabilized by an amplifier, which to emit an output signal with

a certain amplitude is used. Such limiting circuits are known and are, for. B. in the Publication "Video Tape Recording" by Julian Bernstein, published by John F. Rider. Editor, New York. July 1960, pp. 51 and 212-217.

The amplitude-limited, frequency-modulated signal (curve A in FIG. 2) is fed to the input terminal 10 (FIGS. 1 and 2), which leads to a trigger signal generator 11 which has one of the frequency of the

amplitude-limited frequency-modulated input signal corresponding number of needle pulses gives away. The trigger signal generator 11 can be implemented in various ways and designed in this way be that he is on some part of the frequencies / -modulated Wave responds to generate trigger pulses, the spacing of which is the frequency of the modulated Input signal is proportional. This Triggersif.ialgencrator Il may be designed in such a way that

7 8

If he ate positive or negative trigger pulse or source (not shown) connected and may in advance

Both, positive and negative impulses at the same time, a DC voltage of +12 volts

ibt. According to one shown in FIG. 3 lead embodiment shown, the emitter 34 of the transistor 25 is with

arm dcv crfindungsgemcn circuit arrangement connected to the emitter 16 of the transistor 14, and

/ ird as a trigger signal generator an ordinary S both emitters are via a common emitter-

Ichmitt trigger circuit used which simultaneously resisted 36 to power supply line 30

»Provides positive and negative trigger pulses. connected. The collector 38 of the transistor 25

The one between the output pulses of the trigger is via a collector resistor, namely the

Signal generator 11 and the output signals of the resistor 40 to the power supply line 19

connected to their devices of the demodulator circuit \ o. At terminals 42 and 44, ie at

The current temporal relationships are in the collectors of the two transistors 14 and 25

Figs. 1 and 2 shown. of the Schmitt trigger, are pulse shaping circuits

The connected in the demodulator circuit according to the invention. About these pulse shaping circuits

The Schmitt trigger circuit used is in include the capacitors 46 and 48, the resistors

F i g. 3 shown in detail. These Schmitt stands 50 and 54 and the diodes 52 and 56. The

Trigger circuit is known and, for example, in KC elements of the pulse shaping circuits are so

dcm book "Handbook of Selected Semi-Conductor" measure that from the terminals 42 and 44

Circuits ”, elaborated by“ Transistor Applications ”, the relatively rectangular output signals that occur

Inc. for Bureau of Ships, Department of the Navy ", needle-shaped output pulses can be derived.

published 1960, pp. 6-63 to 6-65, as well as in the ao The delivery of a needle-shaped output pulse

Publication »Basic Theory and Applications of or a trigger pulse is achieved by

Transistors "of the" Depaitment of the Army ", March that the time constants of the FLC elements are very small

1059, pp. 208 to 210. The Schmitt j _m compared to the pulse width of the terminals

Trigger circuit is usually used as a sensible 42 and 44 square-shaped output

liche 'and stable zero point detector is used. »5 signals can be selected. For diodes 52 and 56

The characteristic feature of this circuit are used ordinary control diodes, their

is that two transistors are used. The task in the present circuit is to

those whose one with his collector is at the base, only to pass through positive needle-shaped impulses.

of the other transistor is connected. Let them.

The emitters of both transistors are connected to one another.

bound and have a common emitter- the elements are built up:
Resistance. This circuit also has a

positive feedback, due to which a brief element ^ Y ^erte

Schaltzcit is achieved. In the case of the i shown in Fig. 3: derFtementc

Schmitt trigger is at base 13 of transistor 14 35 capacitor 12 100 nF

one with its other assignment to the input transistor 14 2 N 711

terminal 10 connected coupling capacitor 12 resistor 15 1 kOhm

connected. In addition, the base 13 of the contradiction 21 is 2.2 kOhm

Transistor 14 through a resistor 15 on a transistor 25 2 N 711

certain potential, which in the present case by 40 capacitor 27 30 pF

Earth potential is formed. The collector 17 of the Tran resistance 28 4.7 kOhm

Sistor 14 is through the collector resistor 21 to resistor 32 lOkOhm

a power supply line, namely to the Lei resistor 33 330 Ohm

device 19, connected to the negative pole resistor 36 3.3 kOhm

a voltage source (not shown) is connected; 45 resistor 40 1.5 kOhm

Usually the line 19 carries a DC voltage capacitor 46 30 pF

from -12 volts. The collector 17 of transistor 14 capacitor 48 is 30 pF

is also to the base 23 of the second transistor resistor 50 2.2 kOhm

25 connected. In the connection path between resistor 51 2.2 kOhm

the collector 17 of the transistor 14 and the base 50 diode 52 1 N 96

23 of the transistor 25 is one from the diode 56 1 N 96

Capacitor 27 and the resistor 28 existing

Parallel AC member. Thus, there is between the base in the idle state, the transistor 14 is in its 23 of the transistor 25 and the power supply «- held in the non-conductive state because its emitter line 19 via the resistors 21 and 28 a wiring 55 due to the via the emitter resistor 36 and binding. The base 23 of the transistor 25 is also on the emitter-collector path of the conductive Via a base resistor 32 with the positive transistor 25 current flowing at a low potential leading Stromversoraungsleitung 30 geren potential than its base is located. That included and also via a resistor 33 with earth at the emitter 16 of the transistor 14 negative potential connected. The resistor 33 is relatively 60 may now through a base 13 of the potential low resistance and has a resistance value of transistor 14 supplied negative signal from, for example 300 ohms; the resistance value of the reaching amplitude is exceeded. The resistor 33 is to be chosen so that a saturation negative signal may be part of a frequency moduder Transistors 14 and 15 is prevented. This will be the lated input signal. If this negative If the trigger signal generator occurs with a relative 65 signal, the collector potential of the Tranhoen Frequency, e.g. B. work at 700 kHz. The sistors 14 more positive. The change in potential at KoI-das The power supply lector 17 of the transistor 14 carrying positive potential becomes the base 23 of the Line 30 is transmitted to the positive pole of a voltage transistor 25 and causes a there

9 10

Reduction of the positive needle impulses derived from the emitter-collector path impulses are fed to this transistor and also a current flowing to a pulse generator 60, the right-lowering of the potential gradient across the return impulses with a spacing of the needle impulses was 36. This increases the potential emits a corresponding distance at the emitter 16. The output pulses emitted by the trigger of the transistor 14, whereby a stronger signal generator is emitted, are the collector current through this transistor 14. shown as curve B in FIG. As mentioned above and as can be seen from FIG the pulse generator 60 is supplied. The purpose of the off pulse generator 60 occurring at terminal 42 is to change the frequency of the output signal by a positive voltage-modulated input signal proportional pulses occurs. To generate the conductivity states of the selected amplitude that have been reached. The pulse width of the two transistors 14 and 25 remain as long as 15 of the pulses generated by the pulse generator may be retained until the input signal becomes more positive again in the order of 150 nanoseconds. Due to the change then occurring. These pulses are fed both to the function of the collector potential of the transistor 14 to the negative generator 100 and to the gated amplifier 160 tive values located at the base 23 of the transistor, in order to control their operation in each case. 25 a bias voltage that controls the same again during the gated amplifier 160, and a positive and negative control pulse occurs at the same time as a change in the emitter current and thus a change is supplied to the function generator 100 of the common emitter resistor 36 - only a negative pulse supplied. The ablating tension on. The change in the voltage level of these square-wave pulses corresponds, as already mentioned, the drop across the resistor 36 and the reduction 25, to the distance between the needle pulses emitted from the trigger signal generation of the gate 11 located at the base 23 of the transistor 25. The square wave voltage supports the conduction of these pulses of the pulse generator 60 are therefore in the transistor and ultimately causes this to be relatively highly conductive to the frequency of the frequency-modulated transistor, while the input signal generates a proportional ratio. Transistor 14 nearly off, ie non-conductive, 30 A typical embodiment of the pulse generator. The at the collectors of the transistors 14 and gate 60 is shown in detail in FIG. This pulse generator 60, which occurs at terminals 42 and 44, is a modified monodic output signals which are generally rectangular. stable multivibrator, although of course these signals are differentiated from the circuit details 46, 48 and the resistors 50, 54, which are still present from the capacitors and which are just fed to the fulfillment of the function of the pulse shaping circuits by which they are required by the pulse generator 60 so that at their outputs to the in F i g. 4 pulse generator shown 60 needle pulses occur. It is important that the transistor 62 belongs, the base 64 of which is connected directly to these needle pulses at one of the frequency of the two input terminals 63. modulated input signal proportional distance 40 At these input terminals 63 are the control diodes, or ratio occur, that is, the trigger 52 and 56 of the trigger signal generator 11 connected signal generator responds when the input, moreover, these terminals are negative via the counter signal and at the same time a needle pulse was 65 with the power supply line 19 is verbunel Delivered. It follows that the distance with which. The emitter 67 of the transistor 62 is connected proportionally to this power supply line 19 via one of which the needle pulses follow one another, the frequency 45 emitter or bias resistor 68, likewise frequency of the modulated input signal. It goes without saying that a needle pulse can be generated during a plurality of waves connected to the collector 70 of the transistor 62, or during a cycle of a capacitor 72 and a resistor 73. sen; The resistor 73 is connected to its other. The diodes 52 and 56 are normal control ends to ground, and the other assignment of the condiode, which only passes the positive needle pulses through the capacitor 72, is connected to one of the power supply lines. It should be noted that the collector 38 of the line 30-carrying resistor 77 is connected. Transistor 25 becomes positive when transistor 14. These connections affect the non-conductive state, whereby normal exposure to transistor 62 is carried out in the same way via diode 52 as a positive pulse as with a conventional one . The one from the collector 17 of the tranmonostable multivibrator.

sistor 14 occurring negative output signal at the connection point of the capacitor 72 Derived negative pulse is not transmitted via the diode 56, which is polarized for this purpose in and of the resistor 77 in a protection or span blocking direction. voltage limiting diode 76 connected, whose If, on the other hand, the transistor 14 becomes conductive, the anode 60 connected to the base 74 of a transistor 75 is the one at the collector 17 thereof. The diode 76 acts in such a way that a Potential more positive, and the voltage to be supplied to the transistor 75 at the collector 38 of the voltage is limited The potential lying on transistor 25 becomes more negative. and thus a destruction of the transistor 75 Which is prevented from at the collector 17 of the transistor 14. The base 74 of the transistor 75 is Any positive voltage jump which occurs is also derived 65 via a resistor 78 with the current-positive needle pulse is connected via the diode 56 to the over-supply line 19. The emitter 79 of the carry. The from the to the Knilektoren 17 and 38 transistor 75 is direct. connected to this power supply of the two transistors 14 and 25 occurring line 19, while the collector 81

11 12

this transistor through a resistor 80 with the NEN positive needle-shaped pulses. This needle power supply line 30 is connected. As a result, shaped pulses are applied to the terminals 63 at the collector 81 of the transistor 75 a relatively summed up to one of the number of runs high positive potential, while at the base 74 of the frequency-modulated input signal through the same a negative and at the emitter 79 this 5 zero line corresponding Number of pulses to transistor received an even more negative result. The positive needle impulses reach the potential. The transistor 75 is thus the base 64 of the transistor 62 and causes it to be in the conductive state. Transistor goes into the conductive state. The collector 81 of the transistor 75 is connected to an output or switching transistor 84 occurring at the collector of the transistor 62; Transistor 75 is. The transistor 84 lies with its emitter col- is converted into the non-conductive state. The lektor path over the resistors 86 and 88 at switching of the transistor 75 leads to a potential power supply line 19 or 30, whereby tialverschaltung at its collector 81, whereby at the collector of this transistor 84 over the resistor 15 of the base of the transistor 84 a a potential 86 was connected to the power supply line 30 such that this transistor 84 is in the conductive state. /*.uf the reason that got through the resistors 80, 86. When the transistor 84 and 88 become conductive, the potential distribution given is the tran- leads to the fact that a negative transistor 84 at the terminal 98 is normally non-conductive. The emitter 901 voltage jump and at terminal 97 a positive transistor 84 is ao tive voltage jump occurs via a capacitor 92. When the transistor and via an acceleration or pulse shape 62 reach saturation, the capacitor network, which from the capacitor 72 connected to the capacitor 92 is discharged and closed via the resistor 77, reaches itself from the resistor 94 and the capacitor while a state in which the capacitor 96 existing parallel circuit formed sistor 75 is again conductive. When transistor 75 is in feedback Wuse with base 64 of 25 becomes conductive, causing transistor 62 to be connected to its collector 81. The resistor 94 and the potential shift occurring, that the transistor, the capacitor 96 act in such a way that the 84 is returned to its non-conductive state. Base 64 of the transistor 62 becomes needle-shaped feedback. At the transition of the transistor 84 to the non-processing pulses are supplied that this to defl- conductive state occurs at the terminal 98, a posited time in the non-conductive state 30 tive voltage jump and at the terminal 97 to switch. Let there be a negative voltage jump in this context. From terminal 97 notices that the modified monostable used is fed a feedback pulse multivibrator to transistor 62, which differs from conventional monostable multivibrators due to the fact that the multivibrator in the feedback circuit differs in that the resistor 94 and the Kon input transistor, namely the Transistor 62, through 33 capacitors96 existing ÄC-GHedes a needle-shaped transistor 84 is switched off even before ger pulse is. This needle-shaped pulse turns the capacitor 72 has discharged. The resistors 86 and 88 connected to the transistor 62 off, ie, this transistor 62 transistor 84, come to its non-conductive state. This means that they have the same resistance value, which means that a positive square wave pulse occurs at terminal 97 and a negative square pulse at terminals 97 and 98 from almost the same 40 terminal 98.
Size occur. During the pulses of the appearing at terminal 97 positive pulse occurring at these terminals substantially will have the same amplitude-function generator having 100 and the getastetude, the polarity of a pulse, th amplifier having a double-acting charge positive and the other negative. In this circuit 160 represents supplied. The on 'er pulses are square-wave pulses from 45 terminal 98, the negative pulse is only very small, but has a defined pulse width. the keyed amplifier 160 is supplied. The circuit described above can be made up of the following positive impulses from terminal 97 as individual parts: the function generator 100 as well as the

fed to the gated amplifier. This in one

_FI values 50 to the frequency of the frequency-modulated input signal of _{the E} | _emente signals proportional ratio with exact right transistor 62 2 N 706 corner shape generated pulses are used to

Resistance 65 2.2 kOhm to control the function generator 100 and the sampled resistance 68 1.5 kOhm stronger 160 . The keyed amplifier 160

Capacitor 72 20 pF 55 is triggered by the pulses supplied to it,

Resistor 73 1 kOhm so that it emits a current surge or a pulse,

Transistor 'j 2 N 706 that of the function generator 100 the keyed

Resistance 77 47 kOhm amplifier 160 at the time applied span resistance 78 2.2 kOhm voltage is proportional to which the pulses from

Resistor 80 6.8 kOhm 60 pulse generator 60 are transmitted. Through the

Resistance 86 510 0hm pulse trailing edge of the occurring at terminal 97-

Resistor 88 510 ohms the positive pulse becomes the function generator

Capacitor 92 100 μΡ 100 returned to its original position, from

Resistor 94 22 kOhm where it then starts again with a voltage

Capacitor 96 10 pF 65 hyperbolic, exponential or other course to create.

During operation, the pulse generator receives the function generator 100 in such a way that the trigger signal generator 11 emits a frequency-modulated input signal into a

⁰ I.

1 14

Output signal converts the corresponding voltage. Transistor 104 can switch the most suitable course of this voltage to Dc- via switch 114. The capacitor modulation of a frequency-modulated signal connected to the resistor 106 is one of the capacitors 108 to 113 via the limiting hyperbolic curve, because the frequency-time-tongue resistor 134, the potentiometer 136 and the ratio in which the message is transmitted 5 charge resistor 106, where that with the counter of a hyperbolic function is sufficient. Generating a voltage span 106 associated occupancy of the relevant voltage with such a profile is the customer sator which carries negative charge carriers. The difficult one. In the embodiment described here for the charging circuit for the capacitor in question, a device according to the invention is used via the base 119 and the emitter 116 of the conductive voltage with an exponential curve, io transistor 102 to which the positive potential lead, whereby a very close approximation to the ge - the line 30 closed. In the voltage desired in FIG. 5 with a hyperbolic position of the sounder 114 shown , the course f aims is determined. It goes without saying that the amount of charge falling within the scope of the invention, other functional capacitor 112 , is largely in resistor 106,
Generators are to be used to demodulate the function generator 100 to reverse other types of signals or to perform different mathematical operations on the positive side of the terminal 120. Pulse is used to turn on transistor Ϊ04

The function generator 100 (FIG. 5), when switched, that is to say transferred to the conductive state, consists essentially of two transistors 102 and 104 and This is done in such a way that a negative pulse derived from the pulse of an RC network, which is the resistor 106 20 trailing edge includes the base 142 and the capacitors 108-113. Which of the transistor 104 is transmitted. This capacitors 108-113 are 104 leading into the on state 114 connectable via a switching transistor to the resistor 106th With the help of the pulse determines the amount of charge on these capacitors, various selected customer sator can be achieved and RC time constants that, with regard to 25, switches on a tape recording device of the special tape discharge circuit for the capacitor in question, the speed via the emitter 140 the tape recorder and collector 146 of transistor 104 and system used are customizable; With regard to a demodulator via the switch 114, the capacitor 112 (or modulation of carrier frequency signals, this means any other selected capacitor) and that the demodulator runs through the diode 132 for different carriers. A frequency can be used for the diode 132. such diode used, through which already at one

Normally, the transistor 102 is low voltage, for which it is in the forward direction in the conductive and the transistor 104 in the non-conductive ', a high current state within a short time. The emitter 116 of the transistor 102 flows. It should be noted that through which is connected to the power supply line 30 , 35 bias voltage involved in the discharge circuit and the collector 118 of this transistor 102 leads to the transistor 104 that of the base 119 of the transistor via the collector resistor 122 and a coupling 102 and that of the Anode of the diode 132 supplied capacitor, namely the capacitor 124, to the potential more positive or greater than that on the input terminal 120. The potential of -4-12 volts at the connection point line 30 of the Koüektorverbindungen 122 and the Koppe! - * o must be . Due to this positive potential, capacitor 124 , resistor 126 is switched off with its transistor 102 , ie connected to the non-one end; the other end of this conductive state is transferred, and also resistor 126 is at a reference potential. the diode 132 in such a manner in the pass band ge-The base 119 of transistor 102 is one hand controls that a rapid discharge of a biasing resistor 128 is also carried out with the charged capacitor 45 (112). As soon as the capacitor is discharged to this reference potential and, on the other hand, via a (112) to a certain level, beDiode 132 with the power supply line 30 loses a new charge after an exponential bond. Because of these connections is located or hyperbolic function. The generated view of the transistor 102 in the conductive state when the output voltage is at the output terminal 150 and no pulse is fed to the input terminal 120. 50 acceptable.

The emitter 140 of the transistor 104, which is a For the construction of the above-described radio

If it forms part of a discharge circuit, the following individual parts can also be viewed as typical directly on the power supply line 30 if the generator is also 100:
closed. Via a bias resistor 144

is also the base 143 of this transistor 104 with 55 elements _Λ ^W i ^Crle

this power supply line 30 is connected. That of the elements

Base 142 is also transistor 102 2N711 via a capacitor 125

and the coupling capacitor 124 with the input transistor 104 2N711

terminal 120 connected. At collector 146 of resistor 106

Transistor 104 is connected to the contradiction 106 , 60 capacitor 108

which in turn via the resistor 136, the filter capacitor 109

capacitor 137 and resistor 134 to capacitor 110

Power supply line 19 leads. The transistor 104 capacitor 111

is normally biased to be in capacitor 112

is non-conductive state, in which the 65 capacitor 113

Capacitor 124 switched on by switch 114 30pF

of the Kf'-member can charge. Resistor 122 2.2 kOhm

With transistor 102 on and off controller 125 3 nF

15 16

Elements ^values ^^ ^ ^er F ^u nk ^t i ° ^{ns generator} by the trailing edge

of the elements of _{the positive output from the} pulse generator 60

Resistor 128 18 kOhm pulse is reset and starts again with the

Diode 132 IN 3605 Generates an output voltage.

Resistance 134 750 Ohm 5 The in Fi g. 6 keyed resistance shown in detail 136 250 Ohm stronger 160 consists essentially of an emitter

Capacitor 137 100 [iF follower 162, to which the two transistors 163

Resistor 144 6.8 kOhm and 165 belong. The base 167 of transistor 163

Resistor 126 2.2kOhm is connected to output 150 of the function generator

ίο 100 connected. The emitter 169 of this transistor 163 is connected to the connection via a resistor 170

In summary, it can be stated that the connection point of two resistors, namely the resistance function generator 100, one of the pulse generator stands 171 and 172, connected, the positive pulse supplied to the resistor 60 is fed. With was 171 with the power supply line 30 and with the help of one of the trailing edge of this positive Im- ₁₅ the resistor 172 is connected to ground. The pulse derived pulse is the transistor emitter 169 of the transistor 163 is also transferred to the 104 in its conductive state, whereby collector 175 of the transistor 165 is connected. The for the capacitor of the AEC member a discharge base 176 of the transistor 165 is is switched directly to the circuit, in which at the collector 173 of the transistor 163 and a other of the resistor 106 and one of the condensate ₃₀ resistor 178 to the power supply line 19 capacitors 108 to 113 lie. Because of that connected in this. For the construction of the in Fi g. The following elements can be viewed as a sometimes conductive transistor 192 in its non-typical:
transferred to the conductive state. The selected by the switch 114 and charged capacitor (108 25

to 113) is quickly discharged. The basic potential ^values

After this end, the tial of the transistor 102 reaches the elements

charge such a value that this transistor 102 transistor 163 2 N 863

becomes conductive again, which as a result of the transistor 165 2 N 706

the resistor 122 and the capacitor 125 at the 30 resistor 170 3 kOhm

Base 142 of transistor 104 affecting positive resistance 171 8.2 kOhm

Voltage jump of transistor 104 in its resistor 172 3.6 kOhm

non-conductive state returns and also the resistor 178 910 ohms

ÄC element is brought back to the state of charge.

It should be noted that the function 35

generator as a modified monosiabiler effected In operation, may be considered by the function generator multivibrator, although 100 of the base 167 of the transistor 163 supplied of course an entirely different function performs as a voltage that the transistor becomes conductive 163 and an ordinary monostable multivibrator. The function generator that sends a signal to the base 176 of the transistor 165 works in such a way that the output 40 feeds the transistor 165 into the output terminal 150 with an output voltage with an expo-conductive state and thereby an output nominal or hyperbolic increase and very signal outputs, as indicated at terminal 182, with a steep trailing edge, that is, the reset time is. A portion of this output signal is the emitter Au ^r output voltage is very small. The form of the applied to 169 of the transistor 163 and acts like an output voltage occurring at the terminal 150 is 45 negative feedback to improve the Temin of the Fi g. 2D shown. It should be noted that the temperature stabilization and linearity,
plitude of at the output terminal 150 occurs, it should be noted that only a part of the voltage the distance between the de from the pulse generator 60 base 167 * transistor 163 supplied voltage output pulses, which as stated above, the via the emitter 169 of the transistor to the terminal Frequency of the frequency-modulated input signal 50 182 arrives. While the one at the base 176 of the tranproportional. These relationships are shown in FIG. 2 sistors 165 occurring voltage an amplitude to shown. up to 14 volts, the amplitude fluctuates. The input voltage output by the function generator 100 from the voltage established at terminal 182 is fed to a device that only increases by approximately plus or minus 2 volts,
as a keyed amplifier or as a sampling circuit 160 55. Accordingly, the one occurring at terminal 182 can be overcome. The sampled amplifier voltage, in comparison to the voltage at the terminal 150 160, is, as already mentioned, connected to the two outputs of the function generator 100 , the voltage of the pulse generator 60. The flattened out. This flattening results from the input pulses of the pulse generator 60 keying or that the emitter 169 of the transistor 163 on the triggering the keyed amplifier 160 in such a way that 60 the connection point of the two resistors 171 and 172 supplies these current pulses. A current pulse is connected; Because of this connection bc from the gated amplifier 160 at the point in time, the transistor 163 is found output at any time at which the function generator 100 supplies an output voltage at which the potential at its base 167 is too positive, i.e. at the point in time than that at its emitter 169, which the function generator 100 receives the pulses from 65, incidentally, to the one at the junction of the two pulse generators 60. When the resistors 171 and 172 lying potential ent-output voltage of the function generator 100 speaks, in the non-conductive state. This arrangement is sampled by the gated amplifier 160 , so the amplitude of the signal at the terminal 182 is correct

inn £ ιηΙΛ cc

17 18

occurring maximum positive voltage. The device 208 reduces the stored charge, the maximum amplitude that can occur at the terminal 182 .

The negative voltage at the tap of the potentiometer 136 comprising the transistors 210 and 220 and fed by the circuit branch feeds the storage device or function generator 100 causes its stored charge to increase.

determination. that is, the transistors 210 and 220 are effective,

The emitter follower 162 is used for resistance when that occurs at the input terminal 182

adaptation and sets the voltage for the function generator 100 to be greater than the stored voltage or

represents a very high load resistance, so the stored charge of the storage device 208

that a current draw is from the AC element of the func- tion. The transistors 210 and 220 are through a

tion generator 100 is reduced. With the positive from the output from the pulse generator 60 import

Function generator 100 withdrawn low current pulse triggered, which via the resistor 231 (Fig. 5)

the emitter follower 162 operates as a keyed amplifier 160 is fed to the keyed amplifier. A

Amplifier part 185 upstream amplifier. Such a positive impulse is given over to the two

the emitter follower or the _{cascaded, i 5} resistors 213 and 215 with the power supply

directly coupled complementary amplifier transmission line 30 connected emitter 212 of the transistor

sistoren betre.ünde Publication can be found in 210 . The collector 214 of this transistor

the "Handbook of SelectedSemi-ConductorCircuits", 210 is connected to the power supply via a resistor 216

Navships 93 484 U.S. Government Printing Office, Care Line 19 , and Base 218 of the

1960, from pp. 3-13. ao transistor 210 is connected to input terminal 182 directly

The keyed amplifier section 185 of the described connected. At the connection point of the zwi embodiment of the circuit according to the invention see the emitter 212 of the transistor 210 and the arrangement has four transistors, namely the Tran power supply line 30 lying resistors 190, 200, 210 and 220 , which are used to open 213 and 215 , the base 221 of the transistor 220 or discharge of the storage device 208 is connected together. The emitter 222 of the transistor 220 menarbeit as shown in Fi g. 7 and how it is connected to the output terminal via the resistor 223 will be described later. Accordingly, the 230 are connected; the collector of this transistor 220. Transistors 190 and 200 together over a Wi is higher than the resistor 224 at the Stromversorderstand 1P9 (F i g. 5) to de. "pulse generator 60 supply line 30.

connected so that negative pulses to the emitter 30. Due to the above-described connections 191 of the transistor 190 and the base 201 of the transistor, the transistors 210 and 220 are fed to the transistor 200 in this way. The emitter 191 of the spans, that it is 192 passed positive pulses in the conducting state and are converted connectedness with the power supply line 19193 through the two resistors through from the pulse generator 60 abge transistor 190th The ones who speak at terminal 182. The collector 195 of this transistor 190 is 35 tending voltage is fed to the Ba.Is 221 of the transistor via a resistor 196 to the power supply 220 . If this voltage is more positive than line 3ü connected. The base 201 of the transistor 200, which is at the emitter 222 of the transistor 220 , is connected to the connection point of the two resistors of the storage device 208, is connected to the statuses 192 and 193 and thus the capacitor 234 of the storage device 208 is connected to the resistor 193 on the power supply - 40 the value of the chip line 19 connected to terminal 182. Charge the voltage via a resistor. It should be noted that a similar state 203, the collector 202 of the transistor voltage, as it is supplied to the base 221 of the transistor 220 200 also with this power supply line 19 , is also connected to the base 201 of the transistor. To the emitter 206 of the transistor 200 200 is supplied. As a result, however, the is a resistor, namely the resistor 211, an- 45 transistor 200 remains largely in the non-conductive state. 3 closed, which leads to the output terminal 230 . It is further noted that the voltage drop übsr to this output terminal 230 is shown in FIG. 7 of the base-emitter path of overall of the transistor 190 and pointed storage device 208 connected to the resistor 192 to the voltage rise above th e present case, the choke coil 232 and the con-base-emitter path of the transistor 200 and the capacitor 234 contains. 50 resistor 211 corresponds. Similarly,

Due to the above-described compounds of the voltage rise speaks over the base Emitterist the transistor 190 is biased such that it of the transistor 210 and the resistor 213 track the base-emitter negative pulses is made Ubertragungsfähig distance by the output from the pulse generator 60 to the voltage drop across the of the transistor 220 and the resistor 223. with and occurring at the Eingangsklsmme 182 55 aid of this circuit which supplies voltage to the terminal 182 the base of transistor 200th Occurring voltage without any appreciable ampli-If the tensile influence on the base 201 of the transistor 200 led to the output terminal 230 with respect to the voltage transmitted at the emitter 206 of the.

Transistor 200 lying voltage of the memory input In summary, with regard to the keyed

direction 208 is negative, the memory 60 th amplifier 160 discovers that these three inputs

Set up to a value that the DSR on the aisle has: Two of these inputs are with your

Terminal 182 corresponds to the voltage present. If pulse generator 60 and an input is with the

the function generator 100 fed to the base 201 of the transistor 200 is connected. The one from that

Voltage in relation to the signals emitted at the emitter 206 of the same pulse generator 60 trigger the

If the voltage is positive, the transistor 65 is gated amplifier 160, so that this is the front

200 remaining in the non-conductive state - function generator 100 output energy saving

Hen. It should be noted that this division can scan through. The from function generator 109

de :, sampled amplifier 160, the output voltage sampled in the memory arrives at a

Resistance matching, formed by the emitter follower 162 circuit, which largely protects the gated amplifier 160 from an influence otherwise acting by the function generator 100. Due to the simultaneous supply of the output voltage output by the function generator 100 and the signal supplied by the pulse generator 60 to the keyed amplifier 160 , the keyed amplifier section 185 operates in such a way that it transfers the memory device 208 to the scanned voltage or to one of the output voltage of the function generator charges or discharges the corresponding voltage. '

How au «F i g. 7, the storage device 208 consists of a storage capacitor 234 and a choke coil 232. The task of the storage device 208 is to store each of the _. sampled amplifier 160 receive the transmitted signal and emit an output voltage which is fed to a low-pass filter and optionally to the output of the demodulator device.

The sampled amplifier 160 can also be referred to as a sampling device for sampling the output voltage output by the function generator, or it can be referred to together with the memory device 208 as a sampling and storage device for sampling the output voltage output by the function generator 100 and for storing the sampled voltage. A publication relating to these facilities can be found under the title "Sample and Hold Circuit with Bilateral Charging" in "Electronic Equipment Engineering", November 1961, pp. 43 to 4 ^r .

Typical circuit elements for the construction of the gated amplifier part 185 and the memory device 208 are:

Elements . Values ,

of the elements

Transistor 190 2N706

Resistance 192 150 ohm

Resistor 193 5.1 kOhm

Resistance 196 470 ohms

Transistor 200 2 N 863

Resistor 203 220 ohms

Transistor 210 2 N 863

Resistor 211 22 ohms

Choke coil 232 2.2 μΗ

Capacitor 234 33OpF

Resistance 213 150 ohms

Resistor 215 5.1 kOhm

Resistance 216 470 ohms

Transistor 220 2N706

Resistor 223 22 ohms

Resistor 224 220 ohms

The last circuit component of the demodulator device is shown in FIG. 8 and consists of a low-pass filter which converts the output voltage output by the memory device 208 into a voltage which approximates an exact replica of the input signal which actually modulated the carrier signal. This low-pass filter is a typical active filter, as stated, for example, in the article "Transistor Activ Filter Design" by Daniel Meyer in "Electrical Design News", April 1960, from page 54. This article describes the structure of a low-pass filter in such a way that that the average person skilled in the art easily 8 could build the circuit shown.
The in Fig. 8 shown low-pass filter has a

Emitter follower or two cascade-connected, directly coupled complementary transistors, how this to the in Fig. 6 has already been explained. This emitter follower works therefore in a similar manner and represents a facility

In addition, this emitter follower is used to reduce a current draw from the capacitor 234 of the storage device 208 , and the output voltage supplied by the storage device 208 is also amplified. the

As can be seen, the emitter follower consists of the two transistors 240 and 242 and the resistors 246 and 248. The output terminal 250 of the emitter follower 244 is connected to the actual η filter part 252 of the circuit. The filtered 252 contains the

thus the cutoff frequency of the filter-determining resistors 254 and 256. The resistor 256 is connected to the base 259 of the transistor 260 . In addition, the filter capacitor 258 is connected to the basic 259 of this transistor. At the collector 262

As the transistor 260 , a further transistor 266 is connected to its base 264 . The collector 268 of this transistor 266 is connected to the emitter 272 of the transistor 260 . A controllable resistor 270 is connected to this connection point, the tapping of which leads via a coupling capacitor, namely the capacitor 274, to the connection point of the two resistors 254 and 256 . The other end of the resistor 270 is connected to the power supply line 19 through a resistor 271 . Together with the resistor 270 and the coupling capacitor 274, there is thus a feedback branch between the output and the input of the circuit part comprising the transistors 260 and 266. The cascade-connected transistors 260 and 266 provide an improved alpha characteristic for the filter arrangement and improve the linearity of the filter, while at the same time a low-impedance output is created. When the demodulator circuit according to the invention is used in a magnetic tape device for recording signals, the filter circuit 238 is effective for all selected tape speeds; When used in carrier frequency systems, this filtering is effective for all selected carrier frequencies. The output voltage provided by this circuit is shown in FIG. 2, curve F. It should be noted that this circuit is described in more detail in the referenced article by D. Meyer.

The low-pass filter 238 described above can be constructed from the following circuit elements:

_. values

Elements of elements

Transistor 240 2 N 1307

Transistor 242 2 N 1306

Resistor 246 4.3 kOhm

Resistor 248 3 kOhm

Resistor 254 200-20 kOhm

Resistance 256 200-20 kOhm

Capacitor 258 3.9 nF

Transistor 260 2 N 706

1 (516 885

21 "22

Elements values, the gated amplifier 160 samples the output

of the elements voltage of the function generator 100 , and a

Transistor 266 2 N 1305 a short period of time thereafter, the function genes resistor 270 250 Ohm rator by one of the trailing edge of the im-

Resistance 271 1 kOhm 5 pulse generator 60 transmitted positive pulse from resistance 273 2.2 kOhm conducted pulse reset.

Capacitor 274 39 nF The output voltage of the gated amplifier

160 is supplied to the storage device 208 , which in turn stores the supplied voltage and

In summary, it can be stated that the IO supplies a low-pass filter 238 with a voltage proportional to the frequency of the circuit arrangement according to the invention, a trigger signal. The signal generator 11 has the trigger pulses in the storage capacitor of the storage device 208 a proportional ratio to the frequency of the input signal is only generated during each sampling, which the pulse generator when the 60 supplied by the sampled amplifier are fed (Fig. 2, Curve B, and Fig. 3). 15 Output voltage from the voltage delivered during the previous, the pulse generator 60 generates pulses of more defined outgoing scanning. The output voltage output by the storage device 208 or, as is the case in the embodiment described, the output voltage has a stepped verder case, of positive and negative polarity. run, where the step height of the difference between these pulses generated by the pulse generator 60 ao successive samples are also proportional to the frequency of the input signal, which are supplied to the gated amplifier 160 (FIG. 2C) and are the function (curve £ in Fig. 2), is proportional. A low-pass filter 238 (FIG. 6) is fed to generator 100 and to gated amplifier 160 storage device 208. The connected downstream of the gated amplifier, which receives the step-shaped voltage of 160 supplied pulses, serves to trigger the storage device 208 and converts them into a smoothed output voltage (FIG. 2, function generator 100 scanned and an ent curve F, and Fig. 8). This output voltage, which corresponds to the information given by the low-pass filter to the storage device, is transmitted from the output 208 (curve £ in FIG. 2). The output desired from the demodulator device in the embodiment described used 30 voltage. The amplitude of this output voltage sense amplifier 160 (Fig. 6) represents one in two is dependent on the frequency of the input signal. Direction acting device and fulfills the From the above summary and special task, which should emerge in the memory device from the detailed description, that 208 contained storage capacitor (Fig. 7) is charged with the present invention for demodulating or discharging. Since the keyed comparison of frequency-modulated input signals more powerfully 160 can perform both processes, namely suitable circuitry has been created for charging and discharging the storage capacitor, in which a minimum of filter devices is required for the storage device 208 on the from. The required filter effort is the voltage output by the function generator 100 , which is used in a pulse of positive and negative polarity in relation to the many carrier frequencies for which the circuit arrangement output by the pulse generator 60 can be used. appropriate ratio, so that when it is used, the voltage fed to the gated amplifier 160 from the functional circuit arrangement in a frequency mode generator 100 has a hyperbolic or exponential curve that records and reproduces signals (FIG. 2, system is no longer necessary, in a low-pass filter) Curve D, and Fig. 5). The function generator 100 45 filter additionally use capacitors to generate a corresponding output voltage 7 \ i which has an exponential profile Circuit arrangement contains exactly the transistors. The amplitude that is operated, is reliable, the amplifier 160, which is keyed to a large extent during operation, is linear from the function generator 100 50 and the voltage supplied in many respects is more simply proportional to the frequency or to the known setup information of the input signal serving the same purpose. Is built up through lines.

the pulse supplied by the pulse generator 60 is not only limited to the function generator shown in the figures, ie the individual switching capacitor shown and described above of the AC element 55 contained therein, but can be discharged in many ways; then the capacitor sees this without being recharged by the actual concept of the invention. As has been shown to vary, yet to be modified.

For this purpose 2 sheets of drawings

Claims (13)

Cascade-connected transistors (163, 165) give off partial voltage. One of these demodou existing emitter followers (162) has, the generator circuit has a reactance element, the two of which, each consisting of two transistors (190, 200; impedance changes as a function of the frequency of the polarity-dependent switch demodulator circuit supplied to the 210, 220), are downstream Outputs (206, 222) 5 One of the frezu of the storage device (208) then occurs at the reactance element. frequency change of the input signal corresponding 14th circuit arrangement according to claim 13, voltage change. This demodulator circuit is characterized by the fact that the two devices have two disadvantageous properties: a phase distortion occurs for each two transistors (190, 200; 210, 220), and for the existing switch by the pulse generator, there is between the frequency change of the (60 ) emitted pulses can be actuated. Input signal and the resulting 15. circuit arrangement according to claim 13 voltage change a relatively poor linearity, and 14, characterized in that the With this circuit, it is very difficult, the required two transistors (190, 200; 210, 220) such degree of linearity to obtain existing switches over wide frequency bands during their actuation 15. only then a change of the Ladezi. A second type of demodulator for frequency storage device (208) cause "when modulated signals work 1 ..- ^ h a digital merit fed to them by the emitter follower (1.-2), with which even with large frequency changes Voltage differs from the voltage stored in the memory device gen of the input signal an excellent linear voltage (208). ao tat is achievable. In this demodulator circuit 16. Circuit arrangement according to one of the preceding claims, the frequency-modulated input signal is converted into a preceding claim, characterized in that the memory device (208) converts a series of pulses of specific voltage-time into a surface. A display circuit is then applied to a choke coil (232) and a capacitor (234) to sum the pulses within a certain amount of time from the sense amplifier (160). This display tray stores the voltage indicated. device supplies one of the frequency of the input signal 17. Circuit arrangement according to claim 9, corresponding output voltage. The main feature is that the memory problem with this demodulator circuit is that means (208) downstream low-pass filter pulses with a constant voltage-time area to (238) receive one to the memory means (208), because a deviation, like a closed temp, from two cascaded temperature changes, etc., leads to a change in the transistors (240, 242) existing emitter-voltage-time areas of these pulses and consequently (244) that the actual filter is a faulty one Output signal. It is also subordinate to part (252). have been difficult to obtain pulses with a sufficiently short 18. Circuit arrangement according to claim 7, da- 35 fall time. There are already various characterized in that attempts have been made to the emitter to overcome this difficulty follower (244) downstream filter part (252), as it is also adjustable, the cutoff frequency of the filter from the USA. Patent specification 3,099,800 shows, matching resistors (254,256) and a filter- Although some of the above capacitor (258) are part of these attempts, the difficulties mentioned with the control 40 have been overcome, electrode (259) one of two ge in cascade - However, it is connected to such a switched transistor (260, 266), the integrated circuit arrangement of which is used in other connected output electrodes for the selection of selectable carrier frequencies which lead to the switching arrangement (typical areas are between 3.375 and 108 kHz. 45 and deviate by ± 40% from the carrier frequency), 19. Circuit arrangement according to claim 17 necessary, relatively extensive filter devices or 18, characterized in that to be provided between, un? the important part of the pulse information output and the input of the actual mat: w to be transmitted. Another reason for filtering the filter part (252) of the low-pass filter (238) is that the pulse devices are provided with capacitive feedback branches (274) to achieve the required accuracy. with an amplitude of 12VoIt. The present invention is based on the object of providing a circuit arrangement that is particularly suitable for demodulation and has good linearity for frequency-modulated signals with a relatively large range of carrier frequencies (for example 3.37. The invention relates to a circuit up to 108 kHz ), in which the output voltage arrangement, which emits an output voltage of the frequency-modulated input signal in response to an input signal that is fed to it in a certain functional dependency, the amplitude of which is based on the frequency of the 6o and that with as few filter devices as possible Input signal depends. In particular, relates comes. The invention relates to a demodulator circuit, soft This object is achieved according to the invention in that an output voltage proportional to the frequency of a frequency-modulated input is provided, which is controlled by the input signal. 65 with one of the frequency of the input signal. There are two basic types of demodulation-speaking spacing that the trigger signal is known to generate a function of the frequency-modulated signal generated by the frequency of a generator via a pulse generator monotonous al: i 616 claims: 1. A circuit arrangement which emits an output voltage on a frequency-modulated input signal Wn supplied to it, the amplitude of which depends on the frequency of the input signal, characterized in that a trigger signal generator (11) controlled by the input signal is provided, the pulses having a frequency of the input signal corresponding Distance (Fig. 2B) gives that the trigger signal generator (11) via a pulse generator (60) is followed by a function generator (100) which supplies a monotonically decreasing or increasing output voltage (Fig. 2D), the amplitude of which is different from the distance from the trigger signal generator (11) pulses delivered depends, and in that the function generator (100) is followed by the output from the pulse generator (60) positive and negative pulses overall ao-controlled sense amplifier (160), the output from the function generator (100) output voltage as a function of the I emitted by the trigger signal generator (11) pulses in such a way that, when the pulses emitted by the trigger signal generator (11) occur, it supplies a memory device (2u8) with an indication corresponding to the amplitude of the function generator output voltage, the stepped output voltage (Fig. 2E) of the memory device is in a relationship to the frequency of the frequency-modulated input signal given by the voltage-time function of the function generator. 2. Circuit arrangement according to claim 1, characterized in that the function generator (100) emits an output voltage which has an exponential curve, and that the sampling amplifier (160) sequentially scans and amplifies this output voltage. 3. Circuit arrangement according to claim 1 or 2, characterized in that the amplitude of the output voltage output by the function generator (100) is in a proportional relationship to the frequency of the frequency-modulated input signal. 4. Schaitungsanoidnung according to one of claims 1 to 3, characterized in that the trigger signal generator (11) is followed by a pulse generator (60) which converts the pulses supplied to it into pulses of a defined width and thus the function generator (100) and the sampling amplifier (160 ) controls. 5. Circuit arrangement according to claim 4, characterized in that the positive pulses emitted by the pulse generator (60) control the function generator (100) in such a way that the output of an output voltage from the function generator (100) ceases with the occurrence of the trailing edge of such a pulse. C). Circuit arrangement according to one of the preceding claims, characterized in that the function generator (100) emits an output voltage which occurs at the frequency of the input signal and which has an approximately hyperbolic or an exponential increase and a steep decrease. 7. Circuit arrangement according to one of the preceding claims, characterized in that the function generator (100) for outputting an output voltage having an approximately hyperbolic rise comprises a resistor (106) and a capacitor (108 ... 113) connected in series with it ÄC element contains that a charging device serving to charge the capacitor (108 ... 113) of the ÄC element contains a transistor (102) which, when the capacitor (108 ... 113) is charged, reaches the area of high conductivity, and that a discharge device serving for the rapid discharge of the capacitor (108 ... 113) of the RC element contains a transistor (104) which, when the capacitor (108 ... 113) is discharged, enters the area of high conductivity, but when the Capacitor (108 ... 113) reaches the area of low conductivity. 8. Circuit arrangement according to claim 7, characterized in that the output voltage of the function generator (100) occurs on the capacitor (108 ... 113) of the ÄC element and that the charge or discharge of the capacitor (108 ... 113 ) Serving devices (102; 104, 132) are constantly connected to the ÄC member. 9. Circuit arrangement according to one of claims 1 to 8, characterized in that the memory device (208) is followed by a low-pass filter (238) which serves to smooth the voltage supplied by the memory device (208) so that the output voltage output largely with has the course of the modulation voltage of the input signal matching course. 10. Circuit arrangement according to one of the preceding claims, characterized in that the trigger signal generator (11) is formed by a Schmitt trigger, at its outputs (42, 44) for the delivery of needle-shaped pulses of certain polarity differential elements (46, SO; 48, 54 ) and diodes (52; 56) are connected. 11. Circuit arrangement according to one of claims 4 to 10, characterized in that the pulse generator (60) contains three transistors (62, 75, 84) , of which the first transistor (62) with the second transistor (75) and the third transistor (84) is galvanically coupled, and that between the third transistor (84) and the first transistor (62) there is a feedback branch containing a capacitor (92) and an AC element (94, 96) in series therewith. 12. Circuit arrangement according to claim 11, characterized in that the emitter and the collector of the third transistor (84) of the pulse generator (60) pulses of positive or negative polarity occur and that the pulses of one polarity for controlling the function generator (100) and of the sampling amplifier (160) are used, while the pulses of the other polarity are only used to control the sampling amplifier (160) . 13. Circuit arrangement according to one of the preceding claims, characterized in that the sampling amplifier (160) has one of two in