DE752003C - Circuit arrangement for amplitude control - Google Patents

Description

Circuit arrangement for amplitude control During speech transmission, especially over telephone connections, is the volume of the incoming call due to the different attenuation of the lines used or wireless Transmission links are often subject to strong fluctuations. The volume is also different depending on the speech volume of the participants. Likewise found frequently during the conversation of one and the same participant fluctuations due to different talking loudly instead. For many purposes, however, an average is always the same Volume required to avoid overloading amplifiers, transmitters, recording devices or the like to avoid. A volume that is too low must also be taken into account Noise level can be avoided. Devices to achieve a constant as possible Volume have become known as so-called amphitheater controls.

The amplitude regulators are allowed to control the dynamics of the speech, i. H. normal Volume differences as they occur within individual words or syllables, not affect. Only the average voice volume should be reduced to one constant value can be adjusted. The known circuits are but not able to meet the requirements of an amplitude controller to meet. This is to be explained in more detail below with reference to FIGS. From Fig. I, only the switching elements i, 2, 3, 4 and 8 are initially taken into account, which represent a known circuit for amplitude control. Between the entrance E and the output A of the control circuit are the control element i and the amplifier 2 switched on. The control element i can be controlled by a control amplifier or formed by a controlled attenuator, for example a rectifier will. The switching elements for generating the control voltage are upstream of the control element branched off, so that the example shown is a so-called forward regulator acts. However, the considerations made below also apply to the known ones Reverse regulator closed.

In Fig. 2 the characteristic curve of the controlled regulating element i is shown, namely, the output voltage U2 of the element is a function of the input voltage U1 applied. The mean output voltage therefore remains within a certain range regardless of the size of the input voltage. The one in front of the input of the control element The voltage branched off is amplified in the amplifier 3 and rectified in the rectifier 4. The rectified voltage controls the regulating element via the amplifier rectifier 8. The link 4 has an average response time, i.e. H. of about 2 seconds, and a long one After-effect time, d. H. of about 20 seconds.

It is assumed that an input voltage Up, is applied, the course of which is shown in Fig. 3a as a function of time t is. The output voltage then has the curve shown in FIG. 3b. As a result the long response time of the element 4 is used to regulate the control element i required control current only slowly, so that the output voltage also only is slowly turned down. This is due to the gradually decreasing amplitude curve in Fig. 3 b can be seen. The input voltage is switched off and after the time t 'switched on again (cf. FIG. 3 a), it arises as a result of the long after-effect time of the element 4 immediately the correct output voltage.

An amplitude controller built in this way would not work satisfactorily, because after every pause that lasts longer than the active time of link 4, first an overload of the following devices would occur. This could in itself can be prevented by reducing the response time of the link 4. This is but not possible, since otherwise every short-lasting pulse, e.g. B. Shift shocks, occasional very loud speech peaks, etc. during the very long period of after-effect of the limb 4 would falsify the correct adjustment for a long time. On the other hand can also the after-effect time cannot be shortened, otherwise the dynamics of the language will change would be.

The invention aims to eliminate the explained imperfection the previously known controller from the idea, during the response time of the circuit 4 to switch on a circuit with a short response time, in order to reduce the output voltage quickly to bring it to the right value. So that the change in speech dynamics through this Circuit is prevented, it must be switched off after the response time of circuit 4 has elapsed will. According to the invention, this is done in a circuit arrangement for amplitude control by controlling variable resistors or variable amplifiers with the help of a through Rectification of the control voltage obtained from the useful voltage is achieved by that to avoid incorrect regulation as a result of delayed generation of the control voltage these are composed additively from a main control voltage and auxiliary control voltages is by dividing the auxiliary control voltages by subtracting from rectifications DC voltages generated from the useful voltage are obtained, one of which is a circuit the same time constant as the main control voltage circuit, the other one has a much smaller time constant than this.

A circuit for dynamic control has become known in which two control voltages generated in circuits with different time constants are switched against each other. The purpose of this circuit is to overload by using the dynamic controller. So it will have a different effect than at aimed at the circuit according to the invention. It is also known in a circuit arrangement for amplitude control more than two control voltages with different time constants to use. In the known arrangement of this type, however, there is a subdivision of the frequency band is made into several sub-bands and one for each sub-band Control voltage generated. A difference formation of the derived from the individual sub-bands, however, there is no voltage corresponding to the envelopes of these bands. Only an addition is carried out by connecting them in series. It can therefore the effect achieved by the invention cannot be achieved either.

The further development of the inventive concept is explained in more detail with reference to the exemplary embodiments shown in the figures. According to the invention, the known circuit consisting of elements i, 2, 3, 4 and 8 is supplemented by elements 5, 6, 9 and 7. 5 and 6 are rectifiers, of which the rectifier 6 has the same time constants as the rectifier 4, ie the after-effect time has a large value and the response time has a medium value. The rectifier 5, on the other hand, has a short response time and a relatively short after-effect time. In the network 9, the difference between the voltages supplied by the rectifiers 5 and 6 is formed. This differential voltage is applied via the amplifier rectifier 7 to the input of the amplifier rectifier 8 in such a way that it is added to the voltage supplied by the rectifier 4.

It is assumed that, for example, due to low attenuation of the Transmission path or loud speaking a relatively large input voltage is fed to the amplitude controller. The control voltage supplied by circuit 5 Ur then has the course shown in FIG. The one supplied by the link 6 Control voltage U6 shows, however, due to the longer response time and the longer Post-action time shows the course shown in FIG. 5 as a function of time. The differential voltage U, -U formed in the network 9 then changes as a function from time t in the manner shown in FIG. It is assumed that that the negative tensions that may arise when forming the difference are suppressed. This can be achieved, for example, in that the differential voltage is placed on the grid of a tube whose operating point is chosen so that negative components are suppressed. This is shown in FIG. 7, for example. The anode current, I "can only flow when the grid voltages U9 are applied, which are positive. It is evident that if the voltage U.-U, is added to the Voltage U4 supplied by the rectifier 4, the course of which is shown in FIG. 3c is the disturbing increase in output voltage Ug seen from FIG. 3 b during the response time of the link 4 is avoided. By the circuit according to the invention becomes the disadvantage that leads to an overload of the connected devices of the known circuits eliminated without affecting the dynamics of the language significantly is changed.

The circuit according to the invention offers the further advantage that the strength of the limitation of particularly loud speech peaks by changing the ratio the size of the control voltages U5 and U6 can be set as desired. Both 4 to 6 underlying relationships would, for example, after expiration the response time of the member 4, the initially designated normal speech peaks unchanged are transmitted, while the large speech peak drawn at the end of the curve (Fig. 4) limited due to the difference voltage U5 UB present at this point (see Fig. 6) would be.

Because, according to FIG. 7, the negative components of the differential voltage U "-U, are suppressed, there will be a sudden and prolonged decrease the input voltage UE only after the post-action time of the element 4 has elapsed, d. H. after a long time (about ao seconds) balanced. For many purposes, however, it is necessary to bring about such a balance more quickly. This can be done according to Another idea of the invention done in the following way: After the in Fig. 8 shown circuit, for the sake of simplicity, only the parts 4, 5, 6, 9, 7 and 8 of the circuit according to FIG Differential voltage fed to a further DC amplifier io. The feed occurs with such a polarity that in this amplifier not the negative, rather, the positive components of the differential voltage are suppressed. The output voltage Uio of the amplifier rectifier io thus shows the course shown in FIG. 9, when an input voltage U.E is supplied from the curve shown above. The control voltage Ulo becomes that supplied by the amplifier rectifier 7 Control voltage, the course of which corresponds to that shown in FIG. 6, was added. This has the consequence that the too low volume during the time t "(Fig. 9) is balanced. The time constant of the element io is chosen so that the The dynamics of the language are not influenced too much, d. H. the response time will be chosen to be about 5 seconds. So there is no subsequent increase in volume leads to an overdrive, the link io receives a short after-effect time of about zoo ins. In this way and through a suitable choice of the size ratio of the Tensions from links 5 and 6 can be achieved that shut down doesn't happen too often. The connection of the input circuit of the amplifier rectifier io can also be carried out before the difference-forming network 9. You get then the possibility of a different ratio on the amplifier rectifier io of the voltages U5 and U6 act than on the amplifier rectifier 7 by using separate links 5 and 6.

In order to prevent the device from being used immediately during pauses in speaking upregulation, a device can be provided that stops completely the language, for example with the help of a relay, the amplifier rectifier io makes ineffective.

The device described would be used in the case of longer speech pauses that exceed the After-effect time of the link 4 go out to the greatest reinforcement adjust. To the disadvantages associated with it, such as large noise volume at the exit, endangerment the stability of the speaking circuit, etc., can avoid an additional device be provided, which causes a down regulation if the noise is too high.

In the circuit shown in FIG. I, there is feedforward control been applied. A reduction in the large ones that may occur here Changes in the control voltages can be achieved if, as in Fig. = O schematically indicated, a composite forward and reverse control is used. Two control elements i and i 'are provided here, which depend on the output voltage of the amplifier rectifier 8 can be controlled. Before the amplifier rectifier 8 are the links 4, 5, 6, 7 and g explained in more detail in connection with FIG indicated schematically.

Claims (2)

PATENT CLAIMS: i. Circuit arrangement for amphitheater regulation by controlling regulating resistors or regulating amplifiers with the aid of a regulating voltage obtained by rectification from the useful voltage, characterized in that, in order to avoid incorrect regulation due to delayed generation of the regulating voltage, the regulating voltage is additively composed of a main regulating voltage and auxiliary regulating voltages by forming the auxiliary regulating voltages by subtracting from Rectifications of the useful voltage generated DC voltages are obtained whose one circuit has the same time constant as the circuit of the main control voltage, the other has a much smaller time constant than this. 2. Circuit arrangement according to claim i, characterized in that the two circuits (4 and 6) have the same time constant, relatively long after-effects, for. B. 20 seconds, and medium-long response times, e.g. B. 2 seconds. 3. Circuit arrangement according to claim i, characterized in that the third circuit (5) has a very short response time, ie of about 2o ms, and a fairly short after-effect time, ie of about zooms. 4. Circuit arrangement according to claims i,: z or 3, characterized in that negative voltage components which arise in the formation of the difference are suppressed. 5. Circuit arrangement according to claim 4, characterized in that the negative components are suppressed in that the differential voltage is fed to a tube with an operating point selected in such a way that negative half-waves are not transmitted by the tube. 6. Circuit arrangement according to one of the preceding claims, characterized in that the ratio of the voltages forming the differential voltages is adjustable. 7. Circuit arrangement according to one of the preceding claims, characterized in that a further differential voltage containing only negative differential components is added to the differential voltage which contains only positive differential components via a circle (= o) which has a response time, e.g. B. 5 seconds, which is longer than that of the circle (5), but shorter than the after-effect time of the circle (4). B. Circuit arrangement according to claim 7, characterized by a device, for example a relay, which makes the circuit (= o) ineffective when the speech completely ceases. G. Circuit arrangement according to one of the preceding claims, characterized in that forward and backward regulation is used. = o. Circuit arrangement according to one of the preceding claims, characterized in that if the noise level is too high, a downward regulation is effected. To distinguish the subject matter of the invention from the state of the art, the following publications were taken into account in the grant procedure: German Patent No. 657 057; British Patent No. 450,468; U.S. Patent No. 2 O52 110; Magazine >> Funk ", 1938, issue 5, p. = 25, section" Avoidance of overloading "; Journal "Electrical News Technology", 1936, issue 2, p. 47 ff.