DE1295664B - Circuit arrangement for pilot level control in communication systems - Google Patents

Description

The invention relates to a circuit arrangement for pilot level control in communication systems with the help of one from the respective pilot DC voltage and a comparison voltage and a difference voltage formed in a comparator a controlled resistor located in the transmission path as an actuator.

With storing control devices for level control in communication systems it is known to use a DC motor coupled to a potentiometer. Motor and potentiometer are subject to mechanical wear, albeit low subject.

In the German patent specification 1233, which is to be evaluated as an earlier right 915 describes a pilot control that is free of mechanical control elements.

This circuit arrangement for the pilot control of amplifiers in Transmission systems in which the usable frequency band to be transmitted is a pilot frequency is transmitted is structured so that the amplifier points to be controlled after the amplifier output sifted out and rectified pilot frequency dem one input of a differential amplifier is fed to the other end a DC voltage analogous to the nominal value of the pilot level is present. At the output of the differential amplifier is an actuator that influences the gain of the amplifier in the transmission path arranged, whereby in the event of a pilot failure or in the event of falling below or exceeding predetermined values Limit values a change in the setting of the actuator is prevented. That Actuator is given by an electrolytically variable resistor, whose resistance value determines the gain of the amplifier to be controlled.

From the magazine "IEEE Transactions on Industrial Electronics", May 1963, pp. 91 to 100, the properties and applications of Solion tetrodes as known. In particular, with reference to FIGS. 10 and 12 to 15 known direct current amplifiers with Solion tetrodes.

The invention assumes that direct current amplifiers with Solion tetrodes can be used particularly advantageously in the control loop of a level control device can. However, this has the disadvantage that the Solion tetrode is too large Control currents that result from excessive level fluctuations on the line can, can be destroyed.

The object of the invention is also to provide a mechanical control element to create free control device for level control, in which this disadvantage is avoided will.

To solve this problem, the circuit arrangement designed for pilot level control so that at the output of the comparator in their Amplitude of the differential voltage proportional current pulses of the same width can be removed are that the input electrodes of an electrochemical element in the manner of a Solion tetrode are supplied that the comparator is designed such that the current pulses supplied to the electrochemical element when the maximum is reached permissible value are limited in their height and from then on the pulse width is proportional to the differential voltage is increased and that of the output electrodes of this element a manipulated variable is passed to the actuator.

This measure provides a wear-resistant control device for level control, which is particularly suitable when storing the respective Controlled variable is required. Such storage must be provided, for example if the signal to be controlled is scanned and only at certain time intervals should be brought to the desired starting value, with between the individual Sampling times the set control value must be retained.

It is also advantageous that the maximum allowable voltage the output electrodes of the Solion tetrode can never be exceeded, whereby the tetrode, which is very sensitive to overvoltage, is protected from destruction.

In a further embodiment of the invention, the circuit arrangement for pilot level control also be designed in such a way that a thermistor is used as the actuator is used, which is in the output circuit of a transistor, the input side is connected to the output electrodes of the electrochemical element. In this Case is advantageous that the power supply to the transistor and the output electrodes The battery serving the Solion tetrode has a common pole with the so-called "common" electrode the Solion tetrode and the common electrode of the transistor.

It can also be used as a controlled resistor to simplify the circuit the output resistance of the transistor itself can also be used. If you use a silicon transistor, one obtains the one required for the Solion tetrode favorable voltage for the output electrodes.

To protect the Solion tetrode from excessively high voltage on the control electrodes To protect, two silicon diodes can also be used in antiparallel to the comparator output switch. To compensate for temperature fluctuations, when using a Transistor this by means of a resistor with a negative temperature coefficient be fed back.

Another possibility of compensation is that in the emitter lead a temperature-dependent auxiliary voltage is introduced into the silicon transistor. An even more sensitive temperature compensation is achieved by using the Solion tetrode together with the silicon transistor and another Solion tetrode and one Another silicon transistor forms a bridge circuit.

On the basis of the exemplary embodiments according to FIGS. 1 to 6 becomes the Invention explained in more detail.

F i g. 1 shows the control device according to the invention together with the other elements required for level control of a carrier frequency channel. The pilot signal taken from the output terminals 1, 1 'of the amplifier 2 via the selective network 3 is compared at constant time intervals by a comparator 4 with regard to its amplitude with a comparison voltage. The output signal of the comparator 4 is proportional to the difference between the actual pilot signal level and the reference level. The output signal of the comparator is fed to the input electrodes 5, 5 ′ of the Solion tetrode 6. The Solion tetrode 6 has four electrodes, which are designated with “input” electrode 7, “shield” electrode 8, “readout” electrode 9 and “common” electrode 10. The electrode 8 is a few tenths of a volt negative with respect to the electrode 7. For this purpose, a silicon diode 11 is connected in parallel to the electrodes mentioned, which is biased by the battery 12 via the resistor 13 in the direction of flow. The base-emitter path of a silicon transistor 14 is connected to the output circuit of the Solion tetrode, formed by electrodes 9 and 10. The battery 15 and the heating winding 16 of an externally heated thermistor 18 in the amplifier 2 are connected between the collector and the emitter of the transistor 14. Via the resistor 17, the value of which is large compared to the input resistance of the transistor 14, the electrode 9 of the Solion tetrode receives the prescribed negative bias against the electrode 10. The resistor 17 is shown in FIG. 1 connected in parallel to the base-collector path of the transistor, for example, which results in negative feedback.

The mode of operation of the in F i g. 1 is the following: If the pilot signal arrives at the comparator 4 with an amplitude that is too small, the comparator sends a "control charge" QS = f idt to the terminals 5, 5 ', the size of which is proportional to the difference between the reference and pilot signal is. This control charge brings about a transport of movable charge carriers from the electrode space 7, 8 to the electrode space 9, 10 of the Solion tetrode (or vice versa, depending on the sign of the control charge). This changes the conductivity between the output electrodes 9, 10. The conductivity maintains the set value until a new control charge changes the conductivity. Since the electrodes 9, 10 of the Solion tetrode of the emitter-base path of the transistor 14 are connected in parallel, the operating point of the transistor 14 is controlled accordingly by changing the conductivity between the electrodes mentioned. As a result, after the control charge arrives at terminals 5, 5 ', another collector current flows through the heating coil of the externally heated thermistor. The actual thermistor 18 changes its resistance and causes a change in the gain of the amplifier 2, as a result of which the pilot signal and, accordingly, also the voice frequency channels also running through the amplifier 2 assume the correct level.

F i g. 2 shows a control device for level control, the temperature dependence of which is compensated. For this purpose, a further Solion tetrode 20 and a further transistor 21 are added to the Solion tetrode 6 and the transistor 14 assigned to it in such a way that a bridge circuit is formed. Current changes due to temperature occur simultaneously in both transistors. However, these current changes do not affect the heating coil 16 of the thermistor, since a current flows through it which is proportional to the difference between the two collector voltages.

Since the output resistance of a transistor is known to be dependent on the operating point, the correspondingly controlled output resistance, as in the exemplary embodiment according to FIG. 3 shows to be used to regulate the gain. The transistor 14 is operated with an alternating current with an idling base, so that the output resistance is at an impedance level that is favorable in terms of circuitry. The inductance 31 is used for the alternating current idling of the base of the transistor. The capacitance 32 effects a DC decoupling of the output terminals 19, 19 '. The resistor 33 is expediently dimensioned so that it is large compared to the output resistance of the transistor 14 .

A simple control device, in which an extremely low-distortion, controlled resistance is not important, is shown in FIG. 4 shown. The silicon diode 24 is connected in parallel to the output electrodes of the Solion tetrode 6 . A current is effectively impressed by the battery 23 via the resistor 22, the value of which is expediently large. This current is divided between the Solion tetrode and the diode according to the conductivity. The dynamic resistance of the diode obeys the known relationship Here K is the Boltzmann constant, T the absolute temperature, q the elementary charge and 1d the current flowing through the diode. The inductance 31 is used for alternating current decoupling, the capacitance 32 for direct current decoupling. The controlled resistance can be tapped at terminals 19, 19 '. In this arrangement too, the Si diode desirably limits the voltage occurring at the output electrodes of the Solion tetrode.

A practical embodiment in which the comparator is so designed is that from a certain maximum permissible control current, the amplitude of the output signal limited and the output pulse is broadened for this purpose is shown in FIG. 5 shown.

The difference voltage d U formed from the pilot direct voltage and a comparison voltage charges the capacitor 25 . During charging, the switch 26, which can consist of an electronic switch known per se, is switched over in such a way that the capacitor is charged. If the capacitor is charged, the switch switches over and thus a discharge takes place via the transistor 27, which is a field effect transistor. As is known, field effect transistors have the property that the connections which can be used for the emitter and collector can also be interchanged with regard to their voltage polarity.

Is how F i g. 6 shows that the voltage difference d Uo is very small, so the capacitor 25 is discharged according to the curve 28 according to an exponential function. If the differential voltage increases z. B. to d Ui, the corresponding discharge current IS through the capacitor increases. In the case of a discharge current 1o, corresponding to a differential voltage d U2, which would require a collector current in transistor 27 which would be greater than the emitter current, a limitation occurs. At the same time, the output pulse is thus broadened, as can be seen from curve 29 in FIG. 6 can be seen. The ohmic resistor 30 in the emitter-base circuit of the field effect transistor 27 is used to set the signal output amplitude of the comparator 4.

Claims (10)

Claims: 1. Circuit arrangement for pilot level control in Communication systems with the help of one from the respective pilot DC voltage and a comparison voltage in a comparator differential voltage formed and a controlled resistor located in the transmission path as an actuator, as a result, that at the output (5, 5 ') of the comparator (4) Current pulses of equal width proportional to the amplitude of the differential voltage are removable, the input electrodes (7, 10) of an electrochemical element (6) are fed in the manner of a Solion tetrode that the comparator (4) is such is designed that the current pulses supplied to the electrochemical element on reaching the maximum permissible value are limited in their amount and by since the pulse width is increased proportionally to the differential voltage and that from the output electrodes (9, 10) of this element (6) a manipulated variable to the actuator is performed (Fig. 1). 2. Circuit arrangement according to claim 1, characterized in that a thermistor (16, 18) is used as the actuator, which is in the output circuit of a transistor (14) which is connected on the input side to the output electrodes (9, 10) of the electrochemical element (6) is (Fig. 1). 3. Circuit arrangement according to claim 2, characterized in that the transistor (14) is a silicon transistor (F i g. 1). 4. Circuit arrangement according to claim 1, characterized in that the controlled resistor serving as an actuator is the output resistance of a transistor (14) which is connected on the input side to the output electrodes of the electrochemical element (6) (F i g. 3). 5. Circuit arrangement according to one of the claims 2 to 4, characterized in that the transistor by means of a resistor with negative temperature coefficient is fed back. 6. Circuit arrangement according to one of claims 2 to 4, characterized in that in the emitter lead a temperature-dependent auxiliary voltage is introduced into the transistor. 7. Circuit arrangement according to claim 1 and one of the following claims, characterized in that the Solion tetrode (6) and the transistor (14) together with a further Solion tetrode (20) and a further transistor (21) form a bridge circuit ( Fig. 2). B. Circuit arrangement according to Claim 1, characterized in that the Output electrodes of the electrochemical element (6) one in the forward direction polarized, working with impressed current semiconductor diode (24) is switched on and that the differential resistance of this diode serves as an actuator (F i g. 4). 9. Circuit arrangement according to claim 8, characterized in that the semiconductor diode (24) is a silicon diode (Fig. 4). 10. Circuit arrangement according to one of the preceding Claims, characterized in that two silicon diodes for the comparator output are connected in anti-parallel.