DE889175C - Model limiter - Google Patents

Description

Model limiter The invention solves the problem, the limitation the amplitude modeling of a high-frequency voltage to a certain extent independent of fluctuations in the effective value or the peak amplitude of the modeling voltage and to carry out the carrier to be modeled by means of an automatic device.

A particular advantage of the method according to the invention is that the time constant of the limitation process can be chosen arbitrarily and that no technical effort in the form of additional amplifier stages or complicated ones Individual parts is required.

The amplitude of a modeled carrier oscillation fluctuates symmetrically around the amplitude value of the unmodulated carrier oscillation according to the shape of the modeling oscillation, namely between the values m = o and m = x, if m, the model degree, as the ratio of half the amplitude difference of the half-waves of a sign of the modeled carrier is defined for the amplitude of these half-waves in the unmodeled state. With the conditions to be assumed almost without exception in high-frequency technology, the model degree m must not be greater than z, because stronger modeling of a wave in the receiving device causes non-linear distortions. In a high-frequency transmitter, the violation of the approved model grade easily leads to the endangerment of individual parts of the transmitter, namely capacitors, cables and coils can be destroyed by voltage flashovers. So that the ratio of the useful level to the interference level at the receiving location is as large as possible, the aim is always to give the highest amplitude value of the model voltage the permitted maximum model degree value, e.g. B. m = x, to be assigned. In practice, however, this requirement is difficult to meet, either because the dynamic range of the Mode1 voltage is too large and, as a result, the mean model degree is too small, or because the level of the model voltage supplied by a cable is subject to strong fluctuations over time . Such fluctuations in time are always to be expected in practice in the case of long-distance lines that lead through many repeater offices. Apart from that, there are cases in which the size of the carrier to be modeled has to be changed in a short time for operational reasons.

To avoid model overrides, model limiters are known, which work as mechanically controlled potentiometers, control amplifiers, etc. at These known limiting devices must be the maximum value for the prescribed model degree required level of the model voltage first of all by measuring the through a certain model voltage in the transmitter. The limiter is then adjusted so that it is at the prescribed model degree maximum value responds (principle of feedforward control). This setting (calibration) remains the same long as the gain of the stages following the limiter remains constant and also does not change the size of the carrier to be modeled. The latter is by no means always the case. There are also in practice Cases in which, as mentioned, the consignment within a short time with another Carrier value must be carried out. This changed carrier value would have to be a corresponding one Model voltage changed by the same ratio can be set if the prescribed The maximum model grade should be adhered to in each case.

To all such in. To meet demands made in practice, is proposed according to the Exfindüng, the principle of backward regulation in the following How to use: When a certain predetermined model degree is reached, m sets a control process, independent of the modulation characteristic of the modulator and regardless of the size of the modeled high-frequency voltage to be monitored in such a way, that the ratio of the amplitude of the model voltage to the amplitude to be modeled Carrier voltage is changed; that the given model degree is only practical negligibly small, depending on the dimensioning = frequent amount exceeded will. Because the limit use depends solely on the actual degree of the model is dependent, changes in the wearer to be modeled no longer have any influence the automatically observed maximum model degree value. The device according to the invention works when the model voltage arrives at normal level, which does not lead to overdriving of the transmitter leads without affecting the modeling process. Only when the model If the specified maximum value is exceeded, a regular action will be set immediately the facility. The featured new model limiter will be beneficial that way set up that demodulates the modeled high-frequency voltage to be monitored and the demodulation product becomes a control voltage through repeated equalization to influence the ratio of the model voltage to the carrier voltage amplitude to be modeled is derived in the form of a directional voltage, the use of which is exclusively from the size ratio of the alternating depends on the DC voltage component of the demodulation product, which in the repeated Rectification involved and are presented for this purpose on their own.

A: simple means of influencing the use of the control process, consists in using the direct voltage component of the demodulation product as the reverse voltage in the second rectifier arrangement, which is used to generate the control voltage, to use.

A circuit example of such model-limiting device in a simple form, Fig. X. The molded decal to monitor high-frequency voltage RF is demodulated by the rectifier I, so that the demodulation voltage can be taken off at the terminals of the leakage resistance i and the capacitor 2. About the choke 3 blocking the high frequency currents, the demodulation voltage via the blocking capacitor q. to the resistor 6, whose terminal voltage can be viewed as Spännüngsqüelle for the second rectifier circuit. The second rectifier II rectifies the alternating current component of the demodulation product; the control voltage thus obtained is the terminal voltage of the resistor 7 and the capacitor B connected in parallel. This is fed to the control amplifier g and there influences the level of the model voltage. In parallel with the capacitor q., Which conducts the alternating current component of the demodulation product to the resistor 6, there is the controllable resistor 5 which, together with the resistor 6, forms a galvanic voltage divider. The size of the direct current component of the demodulation product occurring at the resistor 6 depends on the size of the resistor 5. The forward direction of the second rectifier II is selected so that the direct current component appearing at the resistor 6 acts as a reverse voltage: consequently. is it possible to use the resistor 5 den. To influence the starting point of the control voltage generation. The smaller the resistance -5. is chosen, the higher the model degree, the first. the control voltage generation. It is expedient to provide the control button for the variable resistor 5 with setting marks labeled according to model degree values. When a control voltage generation is used, a downward regulation of the gain in the control amplifier g, which is followed by the model amplifier of the transmitter, begins immediately.

In the circuit according to FIG. I, the AC voltage component is separated from the - DC voltage component of the demodulation product the Capacitor q., The alternating current resistance of which is negligibly small compared to the size of the resistor 6 or the resistance of the second rectifier circuit (6, 1I, 8, 7). If the resistor 5 were not present, it would be on the terminals of the resistor 6 the pure alternating current component and at the terminals of the capacitor q. the pure direct current component of the de-modulation product to be available. Through the variable resistor 5 can accordingly at the terminals of the resistor 6 such an amount of the DC voltage component are superimposed that the Rectifier II remains blocked for all AC voltage amounts that are below of the maximum permitted model grade.

A further exemplary embodiment for the practical implementation of the model limitation measures according to the invention is shown in terms of circuitry in FIG. The modeled high-frequency voltage, which occurs with respect to earth at the node ii, is fed to the linear rectifier I via the capacitor 12. The demodulated voltage is then applied to the terminals of the resistor 17 or the charge capacitor 16. The resistance 1q. and the choke coil 15 serve to block the high frequency from the low frequency part of the arrangement beginning with the capacitor 16. The capacitor 13 forms with the capacitor 12 a capacitive voltage divider for the high-frequency voltage to be demodulated. The input winding Z1 of the transformer T, the output windings of which are denoted by Z2 and Z3, is connected to the resistor 17 via the capacitor 18. The live terminal of the resistor 17 is connected to the tapping point common to the two output windings of the transformer. The output voltages of the transformer work via the rectifiers IId and IIb to the resistor ig, to which the capacitor 2o is connected in parallel to achieve a desired time constant for this rectification process. The control voltage for the control amplifier 2i is tapped at the resistor ig. The rectifiers IIa and IIb are biased against their forward direction by the DC voltage component of the demodulation product prevailing at the resistor 17. The control voltage generation therefore only begins when the model degree for the lower half-wave of the model voltage obtained by demodulation (U71) or if is for the upper half-wave of the model voltage, with z1, z2 and z3 denoting the respective number of turns of the windings Z1, Z, Z3. With this circuit too, the use of the limitation process is independent of the size of the modeled high-frequency voltage to be monitored and is only determined by the selected winding ratio of the transformer.

Figs. 3 and q. illustrate in the diagram the voltage ratios decisive for the rectifier process in the two rectifiers IIa and IIb, namely FIG. 3 shows the voltage curve which does not yet lead to a model limitation application, while FIG. explains the circumstances according to which a model limitation operation takes place. The time is plotted on the abscissa and the voltages U occurring at the terminals of the rectifier elements are plotted on the ordinate; Furthermore, the rectifier forward current IG is plotted on the ordinate (downward); the diagram above the abscissa indicates the blocking range of the rectifier, for which IG = o in general. The voltage Uz induced in the output winding Z2 is added to the terminal voltage UDe "z of the resistor i or 17 ; the sum UDem -f- Uze in the lower half-wave is so large that the bias of the rectifier is just canceled at the prescribed maximum model level If the model degree is greater than it corresponds to the bias in the reverse direction, a current flows through the rectifier IId, the arithmetic mean of which corresponds to the area of the oscillation peaks below the abscissa U = o in FIG Capacitor 2o charged. The upper half-wave of the demodulation voltage UDe "z is shifted by i8o ° according to the winding direction of the winding Z3, which is opposite to the winding direction of Z1 and Z2, so that taking into account the number of turns ratio in relation to the rectification by the Rectifier IIb the same conduction conditions -as for the rectifier circuit of the Wic condition Z2 are given. So that z. B. a directional current can flow with a model degree in = i, the voltage UDem. a voltage U72 can be added in phase, which is so large that the lower oscillation peak reaches the voltage value zero. Since the model voltage U71 recovered by the demodulation is one according to FIG. 3 and q. positive directional DC voltage is superimposed, the voltage must be. In order to use the upper peak of the half-wave to generate a directional current and thus to use a limitation, a voltage U73 must be added to the voltage U71, which is again so large that with the corresponding bias the. The oscillation peak of the half-wave reaches the voltage value zero. Taking into account that this voltage must be phase shifted by 180 °, the voltage for the required transformation ratio of the transformer results in the following relationships.In the illustrated embodiment, both the lower and the upper half-wave are used to generate the control voltage even with asymmetrical modeling of the high-frequency voltage the model voltage obtained by demodulation is used.

The control characteristics of a model limiter according to the invention are shown in FIG. On the ordinate the model degree m and the model voltage Um supplied to the transmitter is plotted on the abscissa. By choosing the voltage across the resistor ig, you have the option of making the limiting curve either practically horizontal (curve a) or slightly increasing (curves b and c). The limitation insert itself is independent of the magnitude of the voltage across resistor 17.

According to the further part of the invention, the model limiting device equipped in such a way that each time the control voltage is used in the anode circuit of the control stage occurring fluctuations trigger an additional second control process, the the model degree limitation is also intended, but a greater time constant than the process causing the current fluctuations and its effect A gain reduction depending on the frequency of the occurring current fluctuations _ causes. This measure runs on a combined fast and slow working Regulation. In the case of the slow-acting regulation, in contrast to the fast working model degree limitation of the gain of the control amplifier via a downregulated for a longer period of time, so to speak, so that both the small as well as the large amplitude of the model voltage by the same ratio is reduced towards smaller values. Such a model limitation scheme is of importance when one at the level of the modeling voltage with strong temporal fluctuations must be expected. Experience shows that especially then from the transmitter operating personnel to protect the transmitter switching elements, the middle modeling chosen so low that even with the strongly falling level there is no dangerous one Override of the transmitter occurs. But this is the useful volume of the modeling on average very low, and the entire available transmitter power is only fully modeled for short and mostly very rare moments. A model limiter that is independent of all external influences, as is the case with the invention is proposed, now allows these disadvantages to be completely avoided by the input level of the model voltage is selected from the outset to be higher than for the full modeling of the high frequency voltage would be necessary. This will So a large usable volume of the modeling is continuously secured.

In the circuit example shown in FIG. 2, the slow one takes place Regulation by changing the negative feedback factor of a second amplifier stage. In the first amplifier stage, designed as a push-pull stage, the at the resistor ig tapped control voltage a fast regulation, namely is the control voltage as the grid bias of the output winding of the low-frequency transformer 23 formed grid circle is used. Reduced when using quick control the anode current of the two tubes connected in push-pull. In the anode circle this push-pull stage, the magnetic amplifier 24 is arranged, which is one of the average anode current supplies proportional output voltage and accordingly of the the corresponding current fluctuations depend on the control input; the output current this magnetic amplifier feeds the heating winding 25, which is based on the temperature-dependent, z. B. from uranium dioxide existing resistor 26 acts. This temperature-dependent Resistor is in series with resistor 2g and blocking capacitor 28 and Together with these forms a negative feedback loop that increases the gain of the Tube 27 affected. Is the negative feedback effect due to the lower heating of the resistor 26 larger, the overall gain of the control amplifier decreases.

In order to avoid crackling noises during audio reception of a transmitter controlled according to the invention, the model degree limitation must not be carried out with a time constant that is too low. Rather, the time constant must be chosen at least in such a way that the limitation of the model voltage on the transmitter side does not appear as a clicking noise. Corresponding physiological measurements known from the literature have shown that control processes of this type whose settling times are greater than 2 m / sec and whose settling times are greater than 100 m / sec are not perceived by the human ear as cracking noises. As far as the duration of the settling time in the device according to the invention is concerned, the charging of the capacitor 2o and thus a down regulation of the control amplifier can take place in a time of the order of a few milliseconds; for this purpose, in the embodiment of FIG. 2, the source resistance for the transformer must be kept small, ie it must be where R7 is the size of resistor 17 and R9 is the size of resistor ig.

With the proposed model limitation device, a regulation which do not cause non-linear distortions and which otherwise inevitable non-linear distortions in the transmitter are avoided; because by Die Modelb; Grenzurg prevents any overloading of the transmitter, and. the duration the settling time is so short that the human ear as a result of its own Settling time the distortions of a few vibrations that still occur during use can not perceive as such. .

Claims (7)

PATENT CLAIMS: i. Model limiting device, its mode of operation is characterized in that it is independent of the modulation characteristic of the modulator and regardless of the size of the modeled high-frequency voltage to be monitored when a certain specified model degree (m) is reached, a control process begins, whereby the ratio of the amplitude of the model voltage to the amplitude of the one to be modeled High-frequency voltage is changed in such a way that the specified model degree only by a practically negligible amount depending on the dimensioning is exceeded. 2. Model limiting device according to claim i, whose mode of operation is further characterized in that the modeled high-frequency voltage is demodulated and from the demodulation product by repeated rectification a control voltage to influence the ratio of the amplitude of the model voltage derived from the carrier voltage amplitude to be modeled in the form of a directional voltage whose use depends exclusively on the given model degree set size ratio of the separately shown for this purpose at the repeated rectification involved AC to DC component of the Depends on the demodulation product. 3. Model limiting device according to Claim 2, whose Operation is further characterized in that in the second rectifier arrangement, which is used to generate the control voltage, the direct voltage component of the demodulation product is effective as reverse voltage. 4. Model limiting device according to claim 2 or 3, the mode of operation is further characterized in that according to the predetermined Model degree for the generation of the control voltage to be set size ratio of the AC to DC voltage component of the demodulation product through the transformation ratio of a transformer is determined. 5. Model limiting device according to Claim4, characterized in that the transformer with the input winding (Z1), which is connected to the linear first demodulator of the modeled high-frequency voltage to be monitored via a capacitor, has two unequal output windings (Z "and Z.) whose number of turns and that the transformer input circuit is connected to its output circuit in such a way that the direct voltage component of the demodulation product in each branch of the push-pull rectifier arrangement arranged in the transformer output circuit acts as a reverse voltage and the alternating current component of the demodulation product of one output voltage (Uz,) is in-phase with the other in the input circuit (UZ3) superimposed in phase opposition. 6. Model limitation device after optionally one of claims 2 to 5, the mode of operation of which is further characterized in that through the control voltage derived as a directional voltage, the gain of a Push-pull control stage is influenced. 7. Model limiting device according to claim 6, whose mode of operation is further characterized in that each time the control voltage is used in the anode circuit of the push-pull control stage an additional current fluctuations Trigger (second) control process, which also aims to limit the model degree, however, a greater time constant than the control process causing the current fluctuations and its effect depending on the frequency of occurring Current fluctuations cause a reduction in the gain. B. Model limiting device according to Claim 7, characterized in that a device is connected to the anode circuit of the push-pull stage (Magnetic amplifier 14) is connected, through which the anode current fluctuations corresponding current is amplified, and that to additionally influence the degree of amplification in the course of the model voltage amplifier an electrically heatable temperature-dependent one Voltage divider is provided, whose heating element is connected to the output of the magnetic Amplifier is electrically connected. Referred publications: German patent specification No. 435 024.