DE1949396B2 - Circuitry for self regulation of AC voltage amplitude - control magnitude taken from output voltage of operational amplifier - Google Patents

Abstract

The circuitry is designed for self regulation of the amplitude of AC voltages and especially for carrier frequency systems. The voltage to be regulated is conducted to an operational amplifier via an adjusting component. A control magnitude is taken from the output voltage of this amplifier to set the adjusting component so that the actual value approaches the stipulated amplitude value. The output AC from the amplifier which is to be regulated is conducted to an amplitude limiter with divided current branches for both half-waves. The control section of an electronic switch (T1) is installed in one of these branches. A capacitor (C1) is connected in parallel with the transistor (T1) and can be rapidly discharged through it. The charging voltage or current can be used to regulate the adjusting component.

Description

The invention relates to a circuit arrangement for automatically regulating the amplitude of AC voltages, especially for carrier frequency systems, in which the voltage to be regulated is above a Actuator is fed to an amplifier connected to the line and from the output voltage of this Amplifier a controlled variable is derived with which the actuator in the sense of an approximation of the actual value the nominal value of the amplitude is adjustable.

In the case of communication systems, the

voltage values exceeding a half-wave ₂ o Compensation of attenuation fluctuations often auto

can be controlled in the conductive state that the threshold voltage of the amplitude limiter through the setpoint of the amplitude is set that parallel to the switching path of the electronic switch (Transistor 71) a capacitor (Ci) is arranged, which via the electronic switch (transistor Ti) can be quickly discharged and slowly recharged from a power source, and that the charging current or the Charging voltage of the capacitor (Ci) can be used as a control variable for adjusting the actuator.

2. Circuit arrangement according to claim 1, characterized in that the output voltage amplitude limiters flicker over the amplifier an additional amplifier (V.) is fed that i i d i

matic gain controls are used. To change the gain in the controlled system, it is known to use controllable non-linear resistors such as tubes, Use transistors, rectifiers or thermally dependent resistors (DT-PS 10 67 848. DT-PS 9 70 134 Austrian patent application A 7833/60, issued on September 15, 61). In the DTPS 7 09 138 describes an arrangement that also automatically regulates the amplitude of alternating voltages serves, in which the voltage to be regulated is switched on via an actuator to one in the line Amplifier is fed. It uses indirectly heated thermistors. Such thermally dependent resistances can usually run so slowly thermally

in one of the two current branches of the amplitude 35, that the alternating current flowing through it is not limited in series with a Zener diode (Di) and a distorted one. This is important for controlled systems to which the diode (Ch) are arranged in such a way that the Zener diode (Ch) only conducts in the breakdown direction and

that in the other of the two current branches linearity requirements are placed in a row. the However, NTC thermistors have a noticeable time constant. which is taken into account for the stability of the control loop

he must be the base-emitter path of a transistor (Ti) 40, and they are also from the Um- and a diode (Di) are arranged. ambient temperature can be influenced as a disturbance

3. Circuit arrangement according to claim 1, characterized in that the actuator is a Spandie Regulation acts.

The invention is based on the object of a

Circuit arrangement for the automatic control of the temperature compensation to specify a thermistor (HLa) influenced only by the amplitude of the amplitude of the AC voltages, the ambient temperature, a high level of control accuracy with improved stability

voltage divider is provided in the longitudinal branch

with a high thermal conductivity and in whose cross arm an externally heated thermistor (HL ·) is arranged, and that the heating winding (/ · / 1) of the externally heated thermistor (HL ·) is in the charging circuit of the capacitor (Ci).

4. A circuit arrangement according to claim 1, characterized in that to increase the control range of the amplifier (V) following the actuator is counter-coupled via a voltage divider, in the shunt branch for temperature compensation a thermistor (HL ·) influenced only by the ambient temperature with high thermal conductivity and in its longitudinal branch a stranger

properties and improved transient response.

According to the invention, this object is achieved by the characterizing features of the patent claim.

The essence of the invention is seen in the fact that the comparison between the nominal value and the actual value of the amplitude is done without prior rectification. Sieving is therefore not necessary, and the controlled variable is generated without any significant delay set to a value corresponding to the actual value of the amplitude. The control loop therefore also remains high control accuracy or control gain stable.

heated thermistor (HL ·) is arranged, and that the heating winding (H2) of the externally heated thermistor is favorably influenced (HL ·) in the charging circuit of the capacitor (Ci) by the elimination of the control delay. In the circuit arrangement according to the invention. does not become a stabilized reference voltage for the Ver-5. Circuit arrangement according to Claim 2, between the actual value and the setpoint value and characterized in that no transformer is required between the collector fts. The power loss of the electrical transistor (Ti) and the capacitor (Cl) tronic switch is less than that of a contact (Si) arranged by a Pe current amplifier. The charging current of the capacitor gel monitoring device in the event of a sudden level becomes steep with very short switching times

Changed transition from zero to its upper value. The transition is theoretically so steep that it is only in the Interaction with non-ideal buckling characteristics of the amplitude limiters or amplitude thresholds ju combine practically usable control steepnesses leaves. It is possible to build the circuit using integrated sound technology.

In a further development of the invention, a voltage divider is provided as the actuator, in the longitudinal branch of which a thermistor is only influenced by the ambient temperature and has a high thermal conductivity and in the transverse branch of which an externally heated thermistor is arranged for temperature compensation. The heating coil of the externally heated thermistor is in the charging circuit of the capacitor. With this arrangement it is achieved that the disturbing influence of the ambient temperature when using thermistors, which narrows and shifts the control range, is compensated (both thermistors have the same temperature coefficient. The disadvantage of every thermistor control, namely the strongly temperature-dependent initial value, is eliminated. The control element is designed in such a way that the regulated voltage is mainly effective at the thermistors thus also not influenced in their regularity.

It is advantageous to counter-couple the amplifier following the actuator via a voltage divider, in its cross-branch for temperature compensation one which is only influenced by the ambient temperature NTC thermistor with high thermal conductivity and an externally heated thermistor arranged in its longitudinal branch is. The heating coil of the externally heated thermistor is in the charging circuit of the capacitor. With this Switching, an enlargement, for example a doubling of the control range, can be achieved. In Another embodiment of the invention is between the collector of the working as an electronic switch Transistor and the capacitor a contact arranged by a level monitoring device is opened in the event of a sudden drop in level. The control path is parallel to the capacitor Field effect transistor switched, which is controllable by the charging voltage of the capacitor and in its Working circuit the actuator is arranged. This configuration is particularly useful in the event of a sudden level drop advantageous because the setting of the actuator remains almost unchanged for a certain time and control processes can be avoided if the connection between the collector of the transistor and the capacitor is separated by a contact and the level within the delay time appears again in full. This shortens the time in which the level falls below the setpoint.

An embodiment of the invention is shown in the drawing and is described in more detail below. It shows

F i g. la the principle and

F i g. Ib an embodiment of the circuit according to of the invention for controlling the actuators, <\ s

F i g. 2 an embodiment of the entire control device according to the invention,

F i g. 3 shows an embodiment in which, in the event of failure the level the setting of the actuator is held for a long time.

In the control device according to the invention, the charging current is used to control the actuators in the controlled system a capacitor is used, the charging voltage of which is set by a switching transistor. This The principle is described in more detail below and shown in FIG. 1, where F i g. la represents the principle and in Fig. Ib shows an embodiment.

According to FIG. la is a capacitor Ci via a resistor Ri to a supply voltage Lh. Parallel to the capacitor, a resistor Ri is connected in series with a switch Si. If the value of the resistor Ri is large compared to that of the resistor R2, the capacitor Ci can be discharged quickly by closing the switch, while the latter is over after opening the switch Si the resistor R \ can only be recharged slowly. If the switch Si is periodically closed for a short time, a voltage i7 is established across the capacitor Ci - depending on the closing time fi and the opening time ro. Corresponding to the difference between the voltages Uo and U , a current I flows through Ri, which can be used to control the actuators. As shown in FIG. Ib executed, the resistor R: and the switch Si replaced by a switching transistor Γι and this is also used in a branch of an amplitude limiter A , this switching transistor Ti is actuated as soon as the signal voltage applied to the amplitude limiter A exceeds the threshold value. The switching transistor is thus controlled to be permeable by the peak of a half-wave of the signal voltage. Due to the steepness of the current change, it is possible that this, combined with the less steep transition characteristic of an amplitude limiter that can be implemented in practice, results in a steepness that can be used for the entire control range. The small linearity range of the control device has the effect that when the value falls below the threshold value, the current immediately becomes zero and when the value is exceeded, the maximum control current immediately flows. This prevents an unstable behavior of the control loop in the event of larger level jumps. In the practical embodiment according to FIG. Ib, the transient behavior can be improved even further by WC elements /? 3, Cs between the collector and base of the switching transistor Γι

F i g. 2 shows an embodiment of the amplifier arrangement with automatic control according to the invention. At the input Ai, Ai of the controlled system, there is a voltage divider HLi, HL · which can be set by the NTC thermistor HLi in the shunt arm. The setting of the thermistor HLi is done by a heating wire Hi. the heated by the charging current of a capacitor Ci; will. The thermistor HLi is cold at the lower control limit, so that complete temperature compensation is possible with the thermistor HL · in the series branch, which has an equally large temperature coefficient. The control range is not restricted by high input levels , because the thermistor HIa in the series branch barely heats up due to the signal due to its high thermal conductivity. The control range can be adjusted with a second voltage divider HLi. Hl *, increase in the negative feedback branch of the amplifier V approximately to double. Is z. B., as in FIG. 2, a voltage-controlled voltage negative feedback is used, which results in an increase in the input resistance and a decrease in the output resistance of the amplifier V, so it remains

due to the large input resistance, the preceding voltage divider HLi, HIa is unaffected. The negative feedback and thus the amplification can be controlled by the thermistor HL in the series branch, the heating wire Hi of which is also traversed by the charging current of the capacitor Ci. At the beginning of the control range, the thermistor HLs is also cold, so that the compensation of the influence of the ambient temperature by the thermistor HU is complete with the same temperature coefficient in the shunt branch. An additional heating of the thermistor HL does not take place with large input signals, since it is only controlled by the already regulated signal. The derived output variable of the alternating voltage is at the input of a second amplifier V3, which is followed by an amplitude limiter. This amplitude limiter consists of a Zener diode Di which, with the aid of a diode Di, can only become transparent in a certain direction. In parallel, there are a diode Di and a transistor Γι, which can only be controlled to be permeable in the opposite direction. This amplitude limiter, which is asymmetrical in itself, is made symmetrical for the alternating voltage by means of a capacitor Co, across which a direct voltage is generated. As soon as the input voltage exceeds the threshold voltage inherent in the amplitude limiter, the positive half-wave briefly causes a base current in transistor Ti, which controls it to be permeable. Thus, the capacitor Ci is briefly discharged quickly. A charging direct current is established, which is strongly dependent on the current flow angle, with which the heating wires Hi, Ηϊ of the indirectly heated thermistors HL ·. HL · are fed.

F i g. 3 shows an exemplary embodiment according to the invention, in which, if the level fails, the setting of the actuator is retained for a longer period of time. The collector-emitter circuit in which the capacitor Ci is located can be interrupted by means of a switch S \ in the event of a sudden level failure. The voltage across the capacitor Ci determines the on-resistance of a field effect transistor M. so that the current required for the last Regclstatus flows through the heating conductors Hi and Hi until the capacitor Ci has discharged through the high input resistance of the field effect transistor M.

For this purpose 2 sheets of drawings

Claims (1)

Patent claims: 1. Circuit arrangement for the automatic control of the amplitude of AC voltages, in particular for carrier frequency systems, in which the voltage to be controlled is fed via an actuator to an amplifier connected to the line and a control variable is derived from the output voltage of this amplifier, with which the actuator in the sense of a Approach of the actual value to the nominal value of the amplitude is adjustable, characterized in that the output alternating voltage of the amplifier (V) to be regulated is fed to an amplitude limiter with separate current branches for both half-waves, that the control path of an electronic switch (transistor Γι) is arranged in one of the current branches is, which is opened when the threshold voltage of the amplitude limiter fails, that the control path of a field effect transistor (M) is connected in parallel to the capacitor (Ci), which is controllable by the charging voltage of the capacitor (O) and the actuator in its working circuit ed is arranged.