DE2127682C3 - Noise reduction system containing a compressor and an expander - Google Patents

Description

The invention relates to a noise reduction system comprising a compressor compression circuitry that increases the amplitude of an input signal with a compression ratio compressed, depending on one of the compression circuitry supplied first control voltage is variable, as well as with a first control circuit arrangement according to the Level of the output signal of the compression circuit arrangement generates the first control voltage, further comprising a signal transmission system which transmits the output signal of the compression circuit arrangement and one receives the transmitted output signal of the compression circuitry lowing expander with negative feedback amplifier circuitry that allows the The output signal of the compression circuit arrangement received by the expander is amplified with an in expansion circuitry provided in the negative feedback loop of the amplifier circuitry, their expansion ratio depending on one of the expansion circuitry supplied second control voltage is variable, as well as with a second control circuit arrangement which according to the level of the compression circuitry output signal received by the expander generates the second control voltage, the compression circuitry now; and the expansion circuitry practically the same construction and the first and second control circuitry also have practically the same structure.

One such noise reduction system is its basic structure from an essay by R. M. Dolby with the title »An Audio Noise Reduction System, ”published in the journal of the Audio Engineering Society, Volume 15, No. 4, October 1967. Pages! 8 "to 388. known. This known noise suppression system has proven itself in practice enforced under the name Dolby-S / N-Stretcher. Good results are achieved with this Dolby noise reduction system, but it does this known circuit arrangement has a relatively complicated structure. This is, among other things, on it due to the fact that the entire transmission band is divided into several (preferably four) individual frequency bands is subdivided, which are controlled independently of one another with regard to compression and expansion. Although this is associated with certain advantages, it has the disadvantage that the circuit arrangement contains numerous formwork components and thus entails high manufacturing costs. Apart from that, at the well-known Gerä'Jschverminderungsanlage after Dolby requires a precise setting, the one Requires great skill This is due to the fact that even a small change of an input signal level, for example a deviation of ± 2 dB from the normal level results in an extremely strong change in the frequency curve. Another disadvantage is that even with precisely set devices in the vicinity of -2OdB to -30dB in the input-output characteristic a curved section of the curve occurs. Furthermore, there is a difference in level in the frequency curve.

But it has also been shown that with the known noise reduction system on the Compression and expansion carried out over the entire audio frequency range is far too expensive. In the Audio frequency transmission occurs with transmission media such as magnetic tapes and records namely the Noise-disturbed frequency bands especially in the middle to high range of the tone frequency band. There is thus a need for frequency weighted compression and expansion.

In DE-OS 19 54 328 a noise reduction ... i! Age described, which in practice is referred to as the Dolby B system and in which the Compressor and expander an additive or subtractive superposition of the signal of a main channel with the Make the signal of an additional channel in which a filter with a controllable cut-off frequency is arranged. As a result the filter provided in the additional channels with a controllable cut-off frequency, it is necessary that both in the compressor and in the expander to the control connections of control elements Signal levels occur in order to achieve good noise and interference signal suppression. The cutoff frequency namely, the filter changes depending on the magnitude of the signal level of the additional discount. That The presence of a small level difference already makes it impossible to faithfully reproduce the original signal to reproduce.

For further general prior art, reference is made to US Pat. No. 2,193,966, ius of the Noise reduction a compander system is known. but only one over the entire audio frequency range provides uniform compression and expansion.

The invention is based on the object of creating a noise reduction system that is characterized by a simple structure and is capable of. the compression and expansion in such Frequency ranges of the audio frequency band to be undertaken <ne :. where the noise level is highest.

To solve this problem, the at the beginning stands out noise reduction system described after Invention characterized in that the compression circuit arrangement or the expansion circuit arrangement each contain at least one bridge circuit, the resistors in three bridge branches and in a fourth branch of the bridge has a control element whose resistance value increases with an increase in the Tax saving decreases, and in one of the diagonal branches there is a reactance element with a frequency-dependent one Reactance value lies that the resistance values of the resistors in the three bridge branches such are selected that the bridge is balanced when its a control voltage with a predetermined Value is supplied that the input signal of the compression circuit or the input signal of the

Expansion circuit placed on the other bridge diagonal branch and the output signal of the compression circuit or the output signal of the Expaiv sionsschaliung at one end of the former Diagonal branch is removed and that the first control circuit or the second control circuit each characterized by a filter circuit with a frequency characteristic that is approximately equal to the frequency characteristic the unmatched bridge circuits, a limiter amplifier circuit is back Amplify and limit the output signal of the filter sound, a rectifier circuit for Rectifying the output signal of the limiter amplifier circuit and a time constant circuit for smoothing the output of the rectifier circuit for the purpose of generating the control voltage, which with a progressive increase to the predetermined

amplifier circuit is set, the Brückenschaltüng gradually brings into the balanced state.

According to the invention, the compression-expansion ratio can be changed as a function of the frequency in a frequency band in which the noise distribution is particularly large, for example in the high and medium frequency bands. In a frequency band with little noise distribution, for example at low frequencies, there is practically no frequency-weighted compression and expansion. Despite the simple structure, the signal input and signal output characteristics are linear. Next to a high dynamic, the playback is characterized by a remarkably good stability. This is upon it due to the fact that you can choose suitable capacitor and resistor values or by setting suitable resonance frequencies at the resonance elements of the bridge circuits in the noisy Frequency bands can set appropriate time constants. In this way it is possible to be dynamic Compensate for processes and stabilize the signal. Furthermore, the interference signal and Noise reduction without increasing the modulation noise and an associated reduction the sound quality made.

In a preferred further development, the distortion factor remains low in the case of noise reduction the invention uses NPN and PNP transistors as controls. Furthermore, are preferred stabilizes the bias voltages for the control element circuits.

So that the output signal is as distortion-free as possible In a preferred development of the invention, the input signal becomes more opposite in two signals Phase split, and the two output signals obtained are mixed after the Phase of one output signal has been reversed

In addition to the entire noise suppression system, the invention should also include those that can be produced separately Compressor and expander devices as well as recording media that are used with the compressor device of the Noise reduction system according to the invention have been produced.

Preferred exemplary embodiments of the invention are described with reference to figures.

F i g. 1 shows a block diagram of a general compression and expansion system to which the system is applicable according to the invention;

FIG. 2 uses a block diagram to show the basic structure of an interference reduction system of a compression and expansion system according to the invention;

F i g. 3 shows a block diagram of a first embodiment the system according to the invention;

4 shows an example using a diagram for the characteristic of a control element;

F i g. Fig. 5 is a diagram showing a characteristic of a control system in the presser and the stretcher;

6 and 7 show in a graphical representation the Input / output characteristic of the presser or the stretcher:

Fig. 8 is a graph showing the Input-output characteristic of the overall system in the system according to the invention;

9A and 9B show, in part as a block diagram, a second embodiment of the system according to FIG Invention;

Pi σ 10 7ρΐσ (pinp crrafKrhp Darstplliincr ρϊηπς

Frequency distortion factor of the output signal;

F i g. 11 shows a third in part as a block diagram Embodiment of a system according to the invention;

FIGS. 12A through 12D use circuit diagrams to illustrate the operation of an embodiment a bridge circuit;

13 shows the frequency curve in a diagram the bridge circuit according to FIGS. 12A to 12D;

F i g. 1- * is a circuit diagram of another embodiment of a bridge circuit;

Fig. 15 shows a frequency curve of the bridge circuit according to FIG. H;

Fig. 16 is a block diagram of an example having two Bridge circuits;

17 shows a frequency curve of the circuit according to FIG of Fig. 16;

18A and 18B show the frequency curves of the presser and stretcher in the circuit according to FIG Fig. 11:

Fig. 19 is a circuit diagram of a control element circuit in the block diagram according to FIG Waveforms;

F i g. 20 is a circuit diagram of an embodiment of one Pre-stabilization circuit for the strain control circuit of the stretcher;

Fig. 21 shows a graphic representation the gate-source voltage resistance characteristic of a field effect transistor of FIG. 20;

F i g. Figure 22 is a circuit diagram illustrating a general biasing method;

Figs. 23A to 23E show by means of diagrams the relationships between the flow, the spam and the resistance.

The in the F i g. 1 shows a general compression and expansion system that the system according to the invention can be used. On a recording side or transmitting side 10, a from a signal source II delivered signal pressed in a presser 12 and via a recording and Playback system or via a transmission channel, hereinafter referred to as transmission system 13 to a Reproduction side or a receiving side 14 transmitted. In the stretcher 15, the received signal stretched and fed to a signal processor 16

The invention relates to the improvement of the general compression and expansion system in the aforementioned contained pressers and stretchers. The F i g. 2 shows a block diagram of an embodiment the invention. A press 20 which is similar to the one shown in FIG. 1 corresponds to the presser 12 shown, contains a pressing

Y = kX.

(U

* γ

AY l + ate '

(2)

ok

circuit part 22 ztiiii controlling the Sigrtalampliiudcn ^ pressure characteristics and a pressure control scarf 23, which generates a Pfessungssieuefspahnung and gives away. The pressure control circuit 23 receives as an input signal part of the output signal of the PfessiU'it'sschaltteils 22 and generates a pressure S ' control voltage to the compression switching part 22 Is fed. The presser 2Ö has the in Fig. 6 Input-output characteristics shown.

A stretcher 21st the one in the Flg. 1 shown Dehner 15 corresponds, includes an amplifier 24, a negative feedback circuit 25 and a strain control circuit 26. which generates and outputs a strain control tension. The negative feedback circuit 25 feeds part of the output signal of amplifier 24 back to the input of amplifier 24. The expansion circuit 26 generates a strain control voltage upon receipt of a portion of the input to amplifier 24 and supplies this voltage to the negative feedback circuit 25. The stretcher 21 has the in the F i g. 7 input-output characteristics shown.

The transmission system 13 includes a recording and reproducing system and a transmission channel. In the recording and reproducing system, a recording medium is used, for example a magnetic tape, a magnetic disk, a phonograph record, etc. The recording and reproducing system further includes means for recording an output of the presser on the recording medium and means for reproducing the signals recorded on the recording medium. Of the Transmission channel transmits an output signal from the presser via the air or via a cable. A The pressing device with the presser and an expansion device with the stretcher can be constructed separately form. The recording medium on which the signal of the presser is recorded can be in be designed in different ways.

On to the presser 20 from the signal source 11

7iippfiihrtp "; SÜtrnal Χ is in Hpm Prpssiincrcqphalhinori: -

30th

35

part 22, which is controlled by the control voltage supplied by the pressure control circuit 23, changed in amplitude. If the entire amplitude control characteristic of the pressing control circuit 23 and the pressing circuit part 22 with respect to the input signal X is represented by a coefficient k , the following equation holds for an output signal Y of the presser 20:

50

The output signal K of the presser 20 is transmitted via the transmission system 13 and fed as an input signal F to the stretcher 21. In the expansion circuit part 27 of the stretcher 21, the amplitude curve of the input signal Y undergoes a change. The stretcher 21 supplies an output signal Z to the signal processor 16.

If the gain of the amplifier 24 of the stretcher 21 is denoted by A and the feedback ratio of the negative feedback circuit 25 is denoted by β , the following equation applies to the output signal Z of the stretcher 21:

65

If Aß> I ₍ one can write the above equation (2) as follows:

To establish a relationship between the signal; X and the signal Z , the equation (I) is substituted into the equation (3). This results in:

Z =

kX

If between the coefficient k representing the amplitude control characteristic of the presser 20. and the return ratio β of the negative feedback circuit 25 of the stretcher 21 has the relationship k = ß , the following relationship results for the input signal X of the presser 20 and the output signal Z of the stretcher 21:

Z = X.

25 shows an example of the amplitude control characteristic of the control system by the presser 20 and is Dehner21 6dargestellt in Fig..

Therefore, if the coefficient k representing the amplitude control characteristic of the presser 20 and the feedback ratio β of the nagative feedback circuit 25 of the stretcher 21 are selected to be the same, the input-output characteristic of the signal is linear throughout the system as shown in Fig.8. Thus, if the coefficient k and the feedback ratio are selected in the above manner, the signal will not be distorted in the system and the system's S / N ratio will be improved.

An HnnH Hpr F i σ "\ u / irH *» in r »i-aUttcr> K (ac Ancfiih.

approximately example of the invention described in detail. The presser circuit part 22 of the presser 20 contains an emitter follower stage 30 with a transistor 31 which, with a low output resistance, supplies the input signal X to a presser circuit 32, which is followed by an amplifier stage 33 which amplifies the output signal of the presser circuit 32.

When the amplifier stage 33 is provided in the presser circuit part 22 in the manner described above, the relation Y = kX of the FIG. 2 related equation (1) as follows:

7 = kX ■ Ac.

(Ia)

Acaes is the gain of the amplifier stage 33. From the relationship Z = X in equation (5) it then follows:

= X-Ac.

(5a)

60 The above changes have no effect on the characteristics of the system according to the invention.

The compression circuit 32 provides a network with variable attenuation from resistors 34 and 35 and a control element circuit 36. The resistor 34 is at one end via a Capacitor 37 connected to the emitter of a transistor 31. One end of the resistor 35 and

the other end of the resistor 34 are shared with the amplifier stage 33 via a capacitor 38 Tied together. The other end of the opposing land 35 is grounded. The control element circuit 36 is the Resistor 35 connected in parallel. The control element circuit 36 contains a semiconductor control element 39, for example a transistor, as a changeable Contradictory element works, the resistance of which changes depending on the input voltage as it does in FIG. 4 is illustrated. A limiting spacing 40 is in series with the control element 39 switched. The limiting resistor 40 has a resistance value that is within the range of Change in resistance of the constant element circuit 36 is. The resistance of the control noise 36 is the sum of the resistance value of resistor 40 and the internal resistance value between the collector and the emitter of the transistor 39, the resistance of which is dependent on changes from the control voltage at the base.

In the following description, the resistance of the control element circuit 36 is referred to as VR . Instead of a transistor, a field effect transistor or a circuit composed of a lamp and a photocell can also be used as the control element 39.

The input signal X supplied by the emitter follower stage 30 of the presser circuit 32 with the variable attenuation or division network is attenuated or divided by an amount given by the following relationship:

Rl

R1K2
VR

(6)

R 1 is the resistance value of resistor 34 and R 2 is the resistance value of resistor 35. The attenuated signal is fed to amplifier stage 33.

The value given by the relation (6) changes

cir * h in AhhänoioVpit win Apr ΛηΗρπιησ Ηρς WiHpr-

- ■ »■ ■ ■ - · ο ο '' -'ο '

Status value VR of the control element circuit 36. The resistance of this circuit changes in turn as a function of the control voltage which is supplied by the presser control circuit 23. The amount of attenuation of the input signal X depends on the value given by the relation (6). The variation characteristics of the given by the relationship (6) value thus provides a composite characteristic of the control voltage characteristic of the compressor control circuit 23 and the resistance change characteristic of the control circuit 36. Thus, this change pattern represents the coefficients k of the amplitude control characteristic of the presser 20th

The pressure control circuit 23 of the presser 20 contains an emitter follower stage 41 with a transistor, an adjusting element 42 for setting the control signal level, an amplifier stage 43, if necessary a limiter 44, a rectifier 45 and a smoothing filter network 46 with a suitably selected time constant. The output signal of the presser circuit part 22 is fed to the transistor of the emitter follower stage 41 via a capacitor 47. The press control circuit 23 generates a DC control voltage as a function of the output signal Y of the presser 20 and feeds this control voltage to the control element 39 of the pressing mechanism 22. If a limiter 44 is used, as is the case in the present embodiment, the DC control voltage of the presser control circuit 23 assumes a constant voltage value which is above a voltage at which the limiter 44 begins to operate. This control voltage changes the internal resistance of the control element 39, so that the input signal X becomes a signal ZfA ", which arises from the fact that the damping ratio '·

ίο ratio with respect to the input signal ^ is changed. In this way, the input-output characteristic of the presser 20 shown in FIG. 6 is obtained. The relationship between the input signal X and the output signal Y is linear when the level of the input signal X exceeds a particular level.

Next, the stretcher 21 shown in FIG. 3 will be seen. to which the signal Y emitted by the presser 20 is supplied as an input signal / via the transmission system Ί5.

The amplifier 24 of the expansion circuit part 27 has a suitable number of amplifier stages. The output stage of amplifier 24 is an emitter follower. A capacitor 50 and resistors 51 and 52 form a negative alternating current return which is between the emitter of a transistor 49 of the Output stage and the emitter of a transistor 48 is connected in the input stage. A capacitor 53 and a control element circuit 54 are connected in series. This series connection is the Emitter resistor 52 of transistor 48 connected in parallel. The control element circuit 54 includes one Resistor 55 and a control element 56 connected in series.

The feedback ratio β of the negative feedback circuit 25, which comprises the resistors 51 and 52 and the control element circuit 54, is given by the following equation:

R ₂

t «2t

(7)

VR

Where R \ is the resistance of resistor 51, /? 2 is the resistance of resistor 52 and VT? the resistance of the control element circuit 54.

The equation (7) is identical to the equation (6). Therefore, if the resistance values of the resistors 51 and 52 and the control element circuit 54 in the negative feedback circuit 25 are made equal to the resistance values of the resistors 34 and 35 and the control element circuit 36 in the presser circuit 32 described above, the negative feedback ratio β is equal to the coefficient / r of the amplitude control characteristic of the Pressers 20. If the gain of the amplifier is expressed by A and the feedback ratio ß = k and also the relationship Aß> 1 holds, the output signal Z of the extender 21 can be expressed by the following equation:

(8th)

Since the input signal Y of the stretcher 21 can be represented by the equation (1), i.e. Y-kX,

results for the initial signa! Zdes stretcher 21 the following expression:

nisjS des stretcher 21 has the same fixed value that is determined by the following equation is given:

Z = ^ = X.

The feedback ratio β described above, like the coefficient k, includes a characteristic of the circuit which generates the control signal which is supplied to the control element circuit 54. Therefore, if the condition ß = k is to be met, not only the feedback circuit 25 of the stretcher 21 and the presser mechanism Mimg 32 of the presser 20 must have the same structure, but also the stretching control circuit 26 of the stretcher 21 and the presser control circuit 23 of the presser 20.

The expansion control circuit 26 contains an emitter less stage 57 with a transistor, an input element 58 for the control signal level, an amplifier stage 59, if necessary a limiter 60, a rectifier 61 and a smoothing filter network 62 with a suitable time constant. The transistor of the emitter follower stage 57 receives the same input signal Y via a capacitor 63, which is transmitted by the transmission system 13 and is also applied to the expansion circuit part 27. The expansion control circuit 26 generates a DC control voltage which corresponds to the output signal Y of the presser 20. This output signal is equal to an input signal Y of the stretcher 21. The DC control voltage is fed to a control element 56 of the stretching circuit part 27. If a limiter 60 is present, as is the case in the embodiment described, the DC control voltage of the strain control circuit 26 assumes a constant value when this voltage exceeds a value at which the limiter 17 begins to operate.

The characteristic of the strain control circuit 26 can be very easily matched with that of the Make presser control circuit 23 identical by adding

HiA FmiMArfrtlorArCttlfA ζ7 rtoc D ^ iToloinctellfrliÄ ^ l ^ B Ait *

Amplifier stage 59, the limiter 60, the rectifier 61 and the smoothing filter network 62 of the expansion control circuit 26 are constructed in the same way as the emitter follower stage 41, the level adjuster 42, the amplifier stage 43, the limiter 44, the rectifier 45 and the like Smoothing parent network 46 of the presser control circuit 23

Since the compression control circuit 23 and the strain control circuit 26 have the same structure and characteristics and the input signal supplied to these circuits is the same, namely the signal Y, the control voltages supplied by the two control circuits 23 and 26 are of the same magnitude. Furthermore, the pressing circuit 32 of the presser 20 and the feedback circuit 25 of the stretcher 21, which are controlled by control voltages supplied by the control circuits 23 and 26, have the same structure. Consequently, the coefficient k of the amplitude control characteristic of the presser 20 and the return ratio β of the stretcher 21 also have the same value.

If the control element 29 is a transistor, its conductivity is reduced when the supplied control voltage decreases. In the non-conductive state of the transistor, the coefficient k of the presser 20 and the feedback ratio k = fi =

+ R ₂

(10)

The above state is clear for small signal levels in the characteristic curves shown in FIGS. 5, 6 and 7

ίο shown. Furthermore, one can see from the characteristics that the limiter works when the signal level is high. The F i g. 8 shows a relative level for the input signal X supplied to the presser 21 and the output signal Z output by the stretcher 21 in an actual embodiment of the invention. In the figure, there is a difference of the order of ± 0.2 dB between the two signal levels. These level fluctuations are partly due to the different signal levels between the input signal and the output signal, which resulted from the introduction of equation (3), i.e. through the assumption Z = Yl3 or the application of the condition to equation (2)

Z = AYI (X + Aß),

and in part to slight differences in the individual components of the presser 20 and of the stretcher 21. The mentioned fluctuation range of ± 0.2 dB between the input signal and the output signal level however, has no adverse effects in practical applications.

In the F i g. 9A and 9B show a second embodiment of the invention. The first The embodiment according to FIG. 3 changes the value of the internal resistance of the control element 39, that is to say the resistance between the collector and the emitter of the transistor, as a function of voltage changes between the collector and the emitter, even if one, constant DC control voltage at the base. There can therefore be an amplitude distortion in a signal fed to the network.

contain higher harmonics that are undesirable can result in a high distortion factor.

In the second embodiment of the invention, the distortion caused by the mentioned property of the control element in the presser 20 and in the stretcher 21 is avoided by higher harmonics. In the Figure 3, 9A and 9B for the same circuit components same reference numerals are used as the 9A shows the Eingangssigna) X is the signal source 11 is supplied through a capacitor 70, a variable resistor 71 and a capacitor 72 to the base of a transistor 73 Furthermore, bias resistors 74 and 75 are connected to the base of the transistor 73. In the following description, however, the bias circuits, load circuits and the other general circuits are not specifically referred to. A variable resistor 76 and an emitter resistor 77 are connected to the collector and the emitter of the resistor 73, respectively. The transistor 73 operates as a phase reversal stage, at which signals of opposite phase can be picked up at the emitter and the collector.

The output signal appearing at the emitter of the transistor 73 is transmitted to a presser circuit 32a a network of changeable damping standards

stand 79, 80 and 81 and from a control element 82, for example a transistor, supplied via a capacitor 78. The one at the collector of transistor 73 occurring output signal becomes the basis of a Transistor 83 is supplied, which forms an emitter follower with a resistor 84 - the output signal am The emitter of transistor 83 becomes a presser circuit 326 with a network of variable attenuation Resistors 86, 87 and 88 and a control element 89. for example a transistor, via a capacitor 85 supplied.

The variable resistor 76 is used to adjust the two signals in antiphase, so that these signals are supplied with the same amplitude via the capacitors 78 and 85 to the associated compression circuits 32a and 32b. The pressing circuits 32 a and 320 change the degree of attenuation of the signals depending on a control voltage supplied from the pressing control circuit 23. The output signals from compression circuits 52a and 320 are supplied to the bases of transistors 90 and 91. As the signals pass through compression circuits 32a and 326, their progression is changed due to changes in resistance of control elements 82 and 89. The signals applied to transistors 90 and 91 are therefore distorted by numerous higher harmonics.

The transistor 91 represents an amplifier circuit constructed as an emitter follower. The output signal of transistor 91 is in phase with the input signal applied to the base of that transistor. Of the Transistor 90 forms an amplifier constructed as a basic emitter circuit. The output signal of the Transistor 90 is in antiphase with the input signal at the base of that transistor. The emitter of the Transistor 91 and the collector of transistor 90 are connected in series via a resistor 92. In the composite output of the transistors

90 and 91, which is tapped off at the collector of transistor 90, therefore no or only slight distortion as a result of higher harmonics. The distortion factor is therefore low. This is due to the fact that the output signals of the two transistors are of opposite phase when they are combined to form the common output signal. This output signal is then transmitted as signal Y of the presser 20 via transistors 93 and 94 and a capacitor 100 to the transmission system 13.

A resistor 95 and a variable resistor 96 are parallel to each other between the emitters of the Transistor 90 and ground connected. These resistors are used to set the mode of operation of the circuit, so that the output signals of transistors 90 and

91 assemble in the right way. The resistor 95 can also be omitted.

As in the first embodiment, the pressure control circuit 23 contains an emitter follower stage 41 with a transistor, an adjusting element 42 for adjusting the control signal level, an amplifying stage 43, a limiter 44, a rectifier 45 and a smoothing filler element 46 PressUhgssteuerschaltung 23 further resistors 97 and 98 and a diode 99, the circuit consisting of the resistors 97 and 98 and the diode 99 supplies a bias voltage stabilized by the diode 99 to 0.4 V, for example, to the control elements 82 and 89. This bias voltage prevents this Occurrence of distortion in the signal waveform due to a curvature near the stop zone in the control characteristics of the control elements 82 and 89.
Next, the stretcher 21 will be described. As shown in FIG. 9B, the input signal Y is fed to the stretcher 21 via the transmission system 13 and an input terminal 144. From there, the input signal Y passes via a capacitor 101, variable resistors 102 and 103 and via

ίο a capacitor 104 to the base of a transistor 105. The transistor 105 divides the input signal into two signals. The values for a variable resistor 106 and a resistor 107, which are connected to the collector and emitter of the transistor 105, are chosen such that the transistor 105 via capacitors 108 and 109 two signals of the same Output amplitude and opposite phase. The variable resistor 106 is used for setting the state of equilibrium between the two signals of opposite phase.

The signals transmitted via the capacitors 108 and 109 are transmitted to an amplifier circuit 114 Transistors 110 and 111 or an amplifier circuit 115 with transistors 112 and 113 supplied. Amplifier circuit 114 has negative feedback aut. Between the collector of the transistor 111 and the emitter ^ s transistor 110 is a negative Feedback circuit 116 switched. The negative feedback circuit 116 includes resistors 117, 118 and 119.

a transistor 120 and a capacitor 121. The amplifier circuit 115 also has a negative one Return to. A negative feedback circuit 122 is between the collector of transistor 113 and the Emitter of transistor 112 switched. The negative feedback circuit 122 includes resistors 123, 124 and 125. a transistor 126 and a capacitor 127. The negative feedback circuits 116 and 122 are connected to the collectors of transistors 111 and 113 through capacitors 128 and 129. the Resistors 117 and 118 and capacitor 121 are connected to the emitter of transistor 110. Resistors 123 and 124 and capacitor 127 are connected to the emitter of transistor 112. The resistor 119 is between the capacitor 121 and the collector of the transistor 120 is connected. The resistor 125 is connected between the capacitor 127 and the collector of transistor 126 is switched.

The circuit parameters of the circuit components used in the feedback circuits 116 and 122 are the same as the circuit components in the aforementioned pressing circuits 32a and 326 of the presser 20. The feedback circuits 116 and 122 therefore have the same AC characteristics as the pressing circuits 32a and 32c V / ie in the first embodiment, the condition k-β is therefore also met in this embodiment. The capacitance values of the capacitors 121 and 127 in the feedback circuits 116 and 122 are chosen so that the capacities compared to the lowest

Frequency within the observed frequency band represent a sufficiently low resistance.

The output signal of the amplifier circuit 114 is via a capacitor 130 and a resistor 131 fed to a connection point 132 Das

The output signal of the amplifier circuit 115 is via a capacitor 133, a variable widef * stood 134 and a capacitor 135 fed to the base of a transistor 136, which is used as an emitter

development is established. The output signal picked up at the collector of the transistor 136, the phase of which is reversed, is fed to the connection point 132 via a capacitor 137 and a resistor 138. The signals fed to the connection point 132 are mixed by a resistor 139 and fed as a distortion-free output signal Z to a signal processor 16. Since the output signal Z is generated by mixing two signals with opposite phase, the distortion factor of the output signal Z is extremely low in the entire frequency band, as shown in FIG. 10 is shown

The structure of the strain control circuit 26 which supplies the control voltages to the bases of the transistors 120 and 126 of the feedback circuits 116 and 122 is constructed in the same way as in the first embodiment. The circuit 26 includes an emitter follower stage 57. an adjustment member 58 for adjusting the control signal level, an amplifier stage 59 comprises a limiter 60, a rectifier 61 and a Glättungsfiltemetzwerk 62. The emitter follower stage 57, the input signal Y supplied from the variable resistor 102 via a capacitor 140th The strain control circuit 26 also has a circuit with resistors 141 and 142 and diodes: 143. The characteristic or values of the strain control circuit 26 are identical to those of the pressing control circuit 23 of the presser 20 in terms of the relationship between the output control voltage and the input signal Y.

The signal generated by the amplifier circuit 115 running is amplified to a greater extent than that Signal passing through amplifier circuit 114. this is due to the additional amplifier circuit with transistor 136. The changeable one Resistor 134 is therefore set so that the amplitudes of the two signals at the connection point 132 are the same.

A third embodiment of the system according to the invention will be described with reference to FIG. In a recording and reproducing system, the noise distribution is generally different in each frequency band. In general, there is a risk that the interference distribution in the high and medium frequency bands of the audio frequency range is greater. As a result of this risk, a bridge circuit is provided in this exemplary embodiment, the frequency characteristic of which can be set as a function of a frequency band. In Fig. 9A. 9B and 11, the same reference numerals are used for the same parts. The input signal X originating from the signal source 11 is fed to the base of a transistor 73. An output signal picked up at the emitter d <-s transistor 73 is fed to a bridge circuit 150 via the capacitor 78 and the resistor 79. The bridge circuit 150 contains an LC circuit 151 with a capacitor 152 and a coil 153. However, the capacitor 152 alone can also be used to construct the circuit 151. The ZC "circuit 151 operates as a high-pass or band-pass filter. The bridge circuit 150 also contains a control element sound system 134 with transistor ovens 155 and 156. This circuit is used to increase (press) the level of a band in which interference is to be reduced, as will be described below the bridge circuit 150 has resistors 157 to 16i .

The signal that has passed through the bridge closure 150 frill after reinforcement in a lineäfvefsiäfkef ' circuit 162 at connection point 163. The output at connection point 163 is via a variable resistor 164, which is used to adjust the control signal level, a control signal amplifier amplifier circuit 165 fed The signal amplified in the amplifier 165 passes a filter circuit 166, the gives the signal a frequency characteristic that is roughly the same as the frequency characteristic of the bridge circuit 150 matches. The output of the filter circuit 166 is fed to a rectifier circuit 168 via a limiting amplifier circuit 167. From there the signal goes to a time constant circuit 169. One of the time constant circuit 169 supplied control voltage is the control element circuit 154 supplied.

The rectifier circuit 168 contains diodes 170 and 171 and a resistor 176. The diodes 170 and 17t are connected in parallel with one another with opposite polarity, that is to say in an anti-parallel connection. The rectifier circuit 168 therefore supplies positive and negative voltages. The time constant circuit 169 consists of two time constant circuits 172 and 173. The positive and negative output control voltages of the time constant circuits 172 and 173 are supplied to the bases of the transistors 155 and 156 of the control element circuit 154 through resistors 174 and 175. Transistor 155 is an NPN transistor and transistor 156 is a PNP transistor. Transistors 155 and 156 are controlled by de ^r-called positive and negative control voltage as a constant current circuit and change their internal resistances accordingly. The changes in the internal resistances of transistors 155 and 156 change the balance of a bridge condition in

J5 of the bridge circuit 150. This changes the frequency response of the signal passing through the bridge circuit 150 is changed by the LC circuit 151. That signal passed through bridge circuit 150 is passed through amplifier, junction 163 and

transmit the capacitor 100 to the transmission system 13. In the output signal V of the presser 20, therefore, the signal level is raised particularly in the high and middle frequency bands, as shown in FIG. 18A. The degree of increase in the signal level in the high and medium frequency bands depends, as shown in FIG. 18 is indicated by several curves. on the amount of the total output level corresponding to the level of the input signal X.

The control circuit 154 is in combina tion au ^r the NPN transistor 155 and PNP transistor 156. The waveform of the output signal is therefore as shown in Fig. 19. a normal oscillation, even if the course of the output signals to the

Transistors 155 and 156 has complementary distortion. Since the output signal of the circuit contains the Cancel distortions, the distortion factor is extremely low due to high harmonic oscillations.

Next is that shown in Fig. II

6Q stretcher 21 described. The signal Y, which is pressed in the high and medium frequency bands by the presser 20 * is fed to the transmission system 13 and applied to the stretcher 21 as an input signal. The input signal Y arrives via the capacitor 101

And the variable resistor 102 as well as via the variable resistor 103 and the capacitor 104 to the base of a transistor 203. In a directly coupled three-stage amplifier circuit 185 with

Zl Δί OÖZ

Transistors 203, 204 and 205, the incoming signal is amplified and fed to the signal processor 16 as output signal Z.

On the other hand, the input signal after the variable resistor 102 becomes a variable Resistor 179 is supplied, which is used to adjust the control signal level. The variable resistor 179, a control signal amplifier circuit 180, a filter circuit 181, a limiting amplifier circuit 182, a rectifier circuit 183, and a time constant circuit 184 constitute the stretch control circuit. This stretch control circuit performs the same operation as the compression control circuit of the Pressers 20, which consists of similar units starting with the variable resistor 164 and ending with time constant circuit 169.

A bridge circuit 190 is located in a negative feedback loop of the amplifier circuit 185 with an LC circuit 188 and a control element circuit 189. The LC circuit 188 includes one Capacitor ίβό and a Spuie iS7. The control switch 189 contains an NPN transistor 191 and a PNP transistor 192. Furthermore, the Bridge circuit 190, resistors 193, 194 and 195 and a capacitor 196. The rectifier circuit 183 contains two diodes 197 and 198 which are connected in anti-parallel. The time constant circuit 184 includes two time constant circuits 199 and 200. The output control signals of the time constant circuits 199 and 200 become the bases of transistors If ** and 192 via resistors 201 and 202 fed.

The bridge circuit 190 operates in a similar manner to the bridge circuit 150 of the presser 20. Die Bridge circuit 150, however, is in the open circuit of the presser 20 inserted, whereas the bridge circuit 190 of the stretcher 21 in the negative Feedback loop of the amplifier circuit 185 is switched on. The amplifier circuit 185 therefore operates in with respect to the amplifier circuit of the presser in an exactly opposite manner. The amplifier circuit, with the bridge circuit 190 in the negative feedback loop, therefore diminishes in the high and frequency bands mutate the signal level. This is how the stretching is done.

In the following, the operation of the bridge circuit will be described with reference to FIGS. 12A to 12D and 13, and / was under the assumption that the LC circuit 151 consists only of a capacitor C ". In the bridge circuit shown in FIG. 12A with for the resistors r \ to r4 , the input signal is denoted by e _m and the output signal by e _o ". If the values for the resistors rl to λ 4 are selected in such a way that the voltages ei and e * at the resistors r 3 and r4 are equal, i.e. ei = e <. the following equation applies:

flat even if the capacitor C is inserted between points a and b. In this third embodiment, since the control element circuit 189 is used as the resistor r3 , the value of the resistor r3 changes depending on the control voltage, which in turn changes depending on the level of the signal passing through the circuit

When the input signal level is infinite kWn, the value of the resistor r3 is infinitely large. The branch with the resistance r3 can therefore be regarded as open. The corresponding equivalent circuit diagram is shown in Fig. 12.5. With respect to a high-band frequency of the input signal, the capacitor C can be neglected. The in the F i g. 12B is therefore equivalently simulated by the circuit shown in FIG. 12C. The following equation then applies:

r4

Ll ΐλ + _r4
rl + r2

For a low band frequency, the equivalent circuit diagram of the circuit is in FIG. 12D shown for this case results in the equation:

rl rl + r4

(14)

It follows from this

rj

1-4

rl *; 4

r \

= r2 * r3.

(12)

The voltage at point a is therefore equal to the voltage at point b.

In this unbalanced state, the frequency response or the frequency characteristic of the peeling remains. Equations (13) and (14) result in the frequency response shown in FIG. 13 _{for the output signal e ouf.} You can see from this. that the output levels change as a function of the frequency, and that the level for the high and middle frequency bands changes as a function of the value of the variable resistor r3 of the control element according to the full-drawn line or the dashed line.

14 shows a bridge circuit in which the LC circuit 151 is composed of a capacitor C and a coil L. In this circuit, the frequency response of the output signal e _{OI /} , has a maximum at a resonance point f \ of the capacitor C and the coil L. as shown in FIG. At this resonance frequency / i and in the frequency band bordering on this resonance frequency, the value of the output signal level changes as a function of the value of the resistor r3 of the control element described above

When a frequency band is divided and the level is to be controlled in each frequency band, two bridge circuits 210a and 2106 are provided as shown in FIG. The structure of these bridge circuits is similar to the structure of the bridge circuit shown in FIG. The bridge circuits 210a and 2106 are connected in parallel. They are controlled by control circuits? .Lla and 211 / j. In this case, the frequency characteristic or the frequency course has two different resonance points / j and fa as shown in Fig. 17, the signal level is therefore controlled at the resort point h and h as well as in the frequency bands that border these resonance points.

In accordance with this embodiment of the invention, the presser and the stretcher are thus with bridge circuits equipped, riiit riiit in one or more predetermined frequency bands

Mood with the input signal level can variably control the frequency curve. The frequency compression and frequency expansion ratio therefore changes in a predetermined frequency band, in particular at high and medium frequency bands in which the noise distribution is large. In frequency bands with little noise distribution practically no compression and expansion processes are carried out, see above that the input-output characteristic is linear Since one uses the time constant circuit as a function of can freely select the state of an interference band, dynamic processes can be fully compensated and the signal can be stabilized so that interference can be effectively reduced without that a modulation interference is amplified and the sound quality is reduced.

On the basis of FIG. 20 and the following figures, an embodiment of a bias stabilization circuit for the control element circuit is described. FIG. 20 shows an embodiment of the pre-tensioning device for the control element circuit in the presser. A field effect transistor 221, which represents an active element with a variable gain, is used as the control element in the control element circuit 220. In this case, a DC bias is applied to the source of the field effect transistor 221 and a control signal is applied to the gate. Therefore, the voltage Vcs between the gate and the source is changed so that the resistance value | Z | between the source and drain changed With a constant alternating current signal, a constant voltage Vas and thus a constant resistance value \ Z \ must be obtained regardless of fluctuations in the supply voltage Vb ₊ .

The F i g. 21 shows the characteristic curve for the resistance value \ Z \ as a function of the gate-source voltage Vgs. In order to reduce the resistance value \ Z \ during a control in which a control signal increases in the positive direction, a positive bias voltage Vk, is applied and a control signal voltage Vc is supplied to the gate. The result is a resistance value that corresponds to the voltage

Vas = Vsn- V _f ,

is equivalent to. Therefore, if the control signal voltage V ₍ , increases, the voltage V _(i s decreases and the resistance value \ 2 \ also decreases, as is shown in FIG. 21.

The in Fi g. Circuit 220 shown in FIG. 20 is constructed such that a positive bias voltage corresponding to Vso is applied to field effect transistor 221 so that the resistance value decreases as the control signal increases. In particular, a forward current is caused to flow through silicon diodes 223 and 224 of a circuit block 222 to obtain a stabilizing voltage using the initial characteristic of the diodes. This stabilization voltage is fed to the field effect transistor 221 as a bias voltage. In this case, the field effect transistor 221 can assume a resistance value which, despite fluctuations in the supply voltage V ^, corresponds to the control signal voltage Vg

In a rectifier circuit block 225, an alternating current signal fed to the base of a transistor 226 is generated The output signal appearing at the collector of transistor 226 is amplified by a first stage becomes double the voltage by a voltage doubler circuit of diodes 227 and 228 and rectified from capacitors 229 and 230 Die

ίο dynamic properties of the stretcher, i.e. the The response time and the recovery time are determined by capacitors 229 and 230 and resistors 231, 232 and 233.

In a circuit according to Fig. 22 in which the bias voltage is applied in a conventional manner when a signal amplifying part and a voltage doubler circuit are combined into a control signal rectifier circuit, the detector voltage of the transistor 234 is kept constant despite fluctuations in the supply voltage Vb _+. A circuit current / ti therefore increases with the supply voltage Vb ₊ , as shown in FIG. 23A. 22 is fed to a circuit according to the invention, the output control voltage Vo of the voltage doubler circuit at the collector increases with the current Ia , as shown in FIG. 23B even if the AC input to transistor 220 is constant. In this case, the control voltage Vc is influenced by the fluctuations in the supply voltage Vg , as shown in FIG. 23C is shown. Since the resistance value \ Z \ changes in accordance with the change in the voltage Vc, as shown in Fig. 23D, the resistance value \ Z \ changes in accordance with the fluctuation of the supply voltage Vb *, as shown in Fig. 23E shows. This prevents precise control of the circuit.

Therefore, in the circuit according to the invention, the forward stabilization voltage of the silicon diodes 223 and 224 is applied as a bias voltage to the base of the transistor 226, as shown in FIG. This keeps the circuit current In constant. Therefore, when the AC input signal to transistor 226 is constant. the output voltage Va of the voltage doubler circuit is also constant and the influence of fluctuations in the supply voltage Vb _{+ is} avoided. The field effect transistor 221 is therefore supplied with a control voltage which is proportional to the level of the AC input signal. at

So the present embodiment of the invention is the forward stabilization voltage of the silicon diodes 223 and 224 as a bias voltage for the source of the field effect transistor 221 and as a bias voltage for the Base of transistor 226 used. This results in a simpler structure.

Finally, it should be mentioned that the term "expandor" or "expander" used here a meaning is assigned that differs from the meaning of the otherwise common expression »expander« ·

6p det.

For this purpose IÖ sheet drawings

Claims (6)

Patent claims: 1. Noise reduction system, comprising a compressor with a compression circuit arrangement which compresses the amplitude of an input signal with a compression ratio which can be changed as a function of a first control voltage supplied to the compression circuit arrangement, as well as having a first control circuit arrangement which, according to the level of the output signal of the compression circuit arrangement, the first Control voltage generated, further comprising a signal transmission system transmitting the output signal of the compression circuit arrangement and an expander receiving the transmitted output signal of the compression circuit arrangement with an amplifier circuit arrangement having a negative feedback, which amplifies the output signal of the compression circuit arrangement received from the expander, with an expansion circuit arrangement provided in the negative feedback loop of the amplifier circuit arrangement , whose expansion ratio tnis can be changed as a function of a second control voltage supplied to the expansion circuit arrangement, as well as with a second control circuit arrangement which generates the second control voltage according to the level of the output signal of the compression circuit arrangement received from the expander, the compression circuit arrangement and the expansion circuit arrangement being practical have the same structure and the first and second control circuitry also have practically the same structure,
characterized,
The compression circuit arrangement and the expansion circuit arrangement each contain at least one bridge circuit (150 or 190) which has resistors (157, 158, 159 or 193, 206, 207) in three bridge branches and a control element (154 or 189 ), the resistance of which decreases with an increase in the control voltage, and in whose one diagonal branch there is a reactance element (151 or 188) with a frequency-dependent reactance value that the resistance values of the resistors in the three bridges are selected so that the bridge is balanced is. if it is supplied with a control voltage with a predetermined value that the input signal of the compression circuit or the input signal of the expansion circuit is applied to the other bridge diagonal and the output signal of the compression circuit or output signal of the expansion circuit is applied to one end of the first-mentioned diagonal branch is removed and that the first control circuit and the second control circuit are each characterized by a filter circuit (166 or 181) 6ö with a frequency characteristic which is approximately equal to the frequency characteristic of the unmatched bridge circuits, a Begfenzefvefstarkkaliung (167 or 182) to Amplifying and limiting the output signal of the filter circuit, 6} a rectifier circuit (168 or 183) for rectifying the output signal of the limiter amplifier circuit and a time constant circuit (169 or 184) for smoothing the output signal of the rectifier circuit for the purpose of generation the control voltage which gradually brings the bridge circuit into the deviated state with a progressive increase to the predetermined value which is set by the limit level of the limiter amplifier circuit (167 or 182) 2. Plant according to claim 1,
characterized, that the reactance element (151 or 188) contains a capacitor (C) . 3. Plant according to claim 1,
characterized, that the reactance element (151 or 188) is a series circuit of a coil (153 or 187) and a capacitor (152 or 186). 4. Plant according to claim 1,
characterized that the compression circuit arrangement and the expansion circuit arrangement each have a plurality of the bridge circuits (210a, 2106) contain that the reactance element in the one diagonal branch one Has resonance circuit and that the resonance circuits in the individual bridge circuits are tuned to different resonance frequencies. 5. Installation according to one of the preceding claims, characterized in that the control element an NPN and a PNP transistor (155 or 191 and 156 or 192) connected in parallel with one another are. 6. Plant according to claim 1.
characterized. that the compression circuit arrangement and the expansion circuit arrangement each have two bridge circuits have that each of the bridge circuits in a branch with a control element a resistance value that changes as a function of the assigned control voltage and in a diagonal branch has a reactance element with a frequency-dependent reactance value that the compressor has a first signal divider circuit arrangement (73) / for dividing the supplied to it Input signal into two signals of opposite phase and for feeding these signals to the other Diagonal branch of the two bridge circuits and a first phase reversal circuit arrangement (90) which reverses the phase of the output signal from one of the two bridge circuits and the inverted output signal with the output signal from the other of the two bridge circuits mixes, and that the F.xpander a second Signal divider circuitry (105) for dividing the input signal fed to it into two Signals of opposite phase and for feeding these signals to the other diagonal branch of the two bridge circuits and a second phase inversion circuitry (136) which is the phase of the output signal from one of the two Bridge circuits inverts and the inverted output signal with the output signal from the the other of the two bridge circuits mixes. 1. Plant according to claim 1, 2, 3, 4 or 6,
characterized, that the control element is an active element (221) with a variable gain for the purpose of Setting the resistance value has that the Compressor and expander each contain a bias voltage stabilization circuit with an amplifier (226) which amplifies the control voltage and supplies the amplified control voltage to the active element, and that in each case a sounding device with at least one diode (223, 224) detects very small supply voltage fluctuations and both the active element Element as well as the amplifier supplies a bias voltage such that the voltage between the gate and the source of the active element is kept practically at a constant value ^; approx.