DE2058298A1 - Control circuit - Google Patents

Description

Patent attorney

Dipl.-Ing. H. Strohschänk November 26th, 1970. _{OT (5)}

8 Munich 60 i9o, 6-88op

Musäusstrasse 5

Novametric Aktiebolag Fack, S- ^ OO 22 Gothenburg (Sweden )

Control circuit

The invention relates to a control circuit for controlling the Amplitude of the output AC voltage of a feedback branch with a controllable voltage divider having an amplifier, the one Form part of a feedback oscillator or an automatic one May have gain control.

A feedback oscillator can be viewed as an oscillator with an amplifier, a gain-determining feedback circuit and a frequency-dependent feedback path, the attenuation of which can be referred to as β, the amplifier and the gain-determining feedback circuit can be viewed as an equivalent amplifier, its gain can be denoted by A. To generate sinusoidal oscillations in such an oscillator, it is necessary to comply with the oscillation condition A «ß =. If, on the other hand, A * ß> 1, the oscillation amplitude increases continuously until the amplifier reaches the non-linear operating range, which limits the oscillation amplitude. However Α · β ^<1, the vibrations subside. To satisfy the condition A'ß = 1, it is necessary to regulate the gain attenuation automatically so that the condition is met. This is usually done so that the gain-determining feedback path from one

109824 / 11-96

Voltage divider, which determines the gain of the amplifier, and that the voltage division is made dependent on a signal fed to the voltage divider. For a less common type of oscillator the gain is determined by a fixed voltage divider, with the feedback branch determining the gain and the frequency-dependent feedback branch also for controlling the oscillator amplitude can be exploited by making their attenuation dependent on the amplitude. For amplitude control it is common to use an incandescent lamp or to use a thermistor as an amplitude-dependent resistor.

In general, the amplifier has little non-linearity, and In some applications it is necessary to make the amplifier non-linear, as this improves the properties for the Amplitude control result, which is particularly true when the oscillator is exposed to interference phenomena. Only wear symmetrical ones Nonlinearities, i.e. nonlinearities of odd order, to improve the amplitude stability, while both symmetrical and asymmetrical non-linearities also affect the oscillator frequency. About a change in the oscillator frequency due to the non-linearities To avoid this, it is therefore necessary to keep the oscillator amplitude constant.

™ For the oscillator type with fixed gain of the amplifier and the amplitude dependence of the frequency-dependent feedback path is also included in the voltage divider in addition to components with ohmic properties Capacitive or inductive components also behave, which means that the voltage divider is dependent on both amplitude and frequency.

When using an oscillator of this type as a transmitter oscillator However, with the previously known method it is not possible to achieve as precise an amplitude control as this application. In this context, a transmitter oscillator should be understood to mean an oscillator in which a sensor, the ohmic one, is more capacitive or inductive type, py with the frequency-dependent

SCX

connected feedback branch of the oscillator, let the output

109824/1195

output voltage of the oscillator is an alternating voltage whose period or frequency according to a certain function of the output variable of the probe varies. The reason why it was not previously possible the desired precise amplitude control in such a transmitter oscillator to achieve, was that the above-mentioned amplitude-dependent * Resistance represented its own reference element, was at the same time a sensor and control element and was also dependent on environmental influences such as the ambient temperature.

For precise amplitude control is for such an oscillator a circuit known in which the output AC voltage of the oscillator first in an inverted rotating field converter in one of its amplitudes converted into proportional DC voltage, then compared this DC voltage with a reference voltage and finally the difference between these tensions after their amplification to control the die Gain determining voltage divider is used, so that a constant amplitude is obtained. This known circuit has undoubtedly certain advantages, but also has certain disadvantages which can initially be seen in the fact that a relatively large number of components are required to carry out the various steps listed above.

r borrowed. In addition, the accuracy of the amplitude control depends other From the reversed rotating field transducer, and therefore the amplitude the oscillator output voltage directly proportional to the reference voltage.

The invention is therefore based on the object of a control circuit indicate that, while avoiding the deficiencies listed above, the known circuit is accurate and free from external interference Amplitude control for the oscillator output voltage guaranteed.

The object set is achieved according to the invention in that a comparator which has the output AC voltage at a first input of the amplifier and a fixed or an adjustable reference voltage is supplied to a second input, a pulse generator is connected which depends on the relationship between the

109824/1195

led voltages-dependent impulses and generated via a low-pass filter controllable voltage divider so that it outweighs the amplitude of the output AC voltage of the amplifier over the Absolute value of the reference voltage in the sense of a decrease in the amplification of the amplifier, when the absolute value of the reference voltage predominates is adjusted in the sense of a gain increase.

With the control circuit designed according to the invention, one obtains the Ability to adjust the amplitude of the AC output voltage of an amplifier to be kept constant at a value which in turn can be varied within wide limits by appropriate selection of the reference voltage leaves.

For the construction of the comparator is a development of the invention an embodiment is preferred in which two transistors are connected in a differential circuit are connected together and the interconnected emitters of these two transistors from a constant current source be fed.

For the between the pulse generator and the controllable voltage divider Provided low-pass filters are several embodiments within the scope of the invention cheap; According to one of them, the low-pass filter consists of a combination of a capacitance and a resistance or an inductance, while others use a combination of an incandescent lamp and a photoresistor or an indirectly heated thermistor are, wherein the variable resistance component is part of the controllable voltage divider.

A controllable component in the voltage divider comes into play According to the invention, a current or voltage controllable component such as the emitter-collector path of a field effect transistor or a combination a photodiode with a photoresistor or a coil with a magnetic diode component or the capacitance of a capacitance diode into consideration.

109824/1 195

In the drawing, the invention is illustrated by way of example; the single figure shows a circuit diagram for a device according to the invention trained control circuit for regulating the output amplitude of the voltage of an oscillator.

The oscillator shown has an amplifier 10, at which Output a voltage divider from a fixed resistor 11 and a connected in series to this controllable resistor, the controllable resistor in this case through the emitter-collector path a field effect transistor 12 is formed. The connection point between the two resistors of the voltage divider is with the negative input of the amplifier 10 connected. In addition, a frequency-dependent feedback branch 13 is connected to the amplifier 10, which in this embodiment shows a maximum in-phase transmission at the oscillator frequency. The voltage divider from the resistor 11 and the field effect transistor 12 determines the amplitude of the alternating voltage output by the oscillator and keeps it in the following described way constant.

The base of a transistor is connected to the output of the amplifier 10 and, together with a further transistor 15, forms a conventional differential circuit, the emitters of these two transistors Ik and 15 being connected to one another and being fed by a constant current source 16 which is connected to a terminal 25 for the supply of a positive voltage is in connection. A reference voltage with negative polarity can be fed to the base of the transistor 15 via a connection 17. A negative voltage is fed from a terminal 18 to the collector of the transistor 15 directly and to the collector of the transistor Ik via a load resistor 19. The output voltage of transistor 1A is used to control a further transistor 20, in whose output branch a low-pass filter consisting of a capacitor 21 and a resistor 22 parallel thereto and a series resistor 23, which in turn is connected to the control electrode of the field effect transistor 12, are located. The collector-emiiter resistance of the field effect transistor 12 is on the one hand in a known manner by means of the series resistor

109824/1195

Resistor 23 and on the other hand linearized by means of a further resistor 2k.

The circuit described above operates in the following manner. Every time the. AC output voltage of the oscillator becomes more negative than the reference voltage fed in via terminal 17, the transistor becomes conductive, which leads to an increase in the voltage drop across resistor 19, so that transistor 20 also becomes conductive. As a result, current flows into the capacitor 21 and charges it. In the pauses W between the charging current pulses thus generated, the capacitor 21 discharges via the parallel resistor 22 and also via the combination of the resistors 23, 2k and 11 and the above-mentioned collector-emitter resistor of the field effect transistor 12.

In this way, a voltage is formed on the capacitor 21, which is proportional to the current pulses. This voltage is now used to control the collector-emitter resistance for the field effect transistor 12, which resistor, as mentioned above, together with resistor 11, determines the gain-determining voltage divider in the amplifier of the oscillator forms. In this way it is possible to set the controllable voltage divider so that the gain of the oscillator def Increases when the amplitude of the output alternating voltage of the oscillator is smaller than the absolute value of the reference voltage. Is against the amplitude of the output AC voltage of the oscillator is greater than the absolute value of the reference voltage, so the controllable voltage divider adjusted so that the gain of the oscillator amplifier decreases.

When the reference voltage applied to terminal 17 has a constant Value, a constant amplitude for the alternating voltage emitted by the oscillator is obtained in this way. However, it is obvious that the same circuit also enables a controlled variation to be achieved for the amplitude of the alternating voltage output of the oscillator, if the one at port 1? supplied reference voltage by a with a AC voltage superimposed DC voltage is formed, then the

109824/1 195

circuit described above works as a modulator. In this case it is just make sure that the amplitude of the superimposed alternating voltage does not exceed the amount of the direct voltage on which it is superimposed will.

Should the illustrated oscillator be used as a transmitter oscillator in the above-mentioned To be used in the sense, one or more components must be frequency-dependent Feedback branch 13 can be designed as a sensor, with which then the frequency or period of the output AC voltage of the oscillator varies according to a certain function of the output of the sensor.

Although the invention has been described above on the basis of its use in a feedback oscillator, the invention can just as well, as mentioned in the introduction, be used in an amplifier with automatic gain control. A gain control of this type is assumed to be carried out as a function of a supplied control voltage which, in this embodiment of the invention, is supplied to an input of the comparator instead of the reference voltage. The output voltage of the amplifier is supplied ^v comparator is the second input of the grain, and the output pulses of the! Comparators control the variable resistor, which forms together with a fixed resistor a voltage divider as in the above-described embodiment of the invention, at the back as above, a Voltage for controlling the gain of the amplifier is taken. In this embodiment of the invention, the frequency-dependent feedback branch 13 is omitted, and it is also possible, as indicated in the drawing with dashed lines, to have a resistor 26 between the voltage divider consisting of the resistor 11 and the field effect transistor 12 and the input of the amplifier 10 insert, past which a signal voltage can be applied via a terminal 27 and a further resistor 28 to the input of the amplifier 10.

The invention is not limited to those shown in the drawing and in Connection therewith described embodiments limited, but rather

109824/1195

can be varied in many ways. So the low pass can take place by the resistor 22 and the capacitor 21 are also formed by the combination of a capacitance and an inductance, and also a low-pass filter effect can be achieved thermally, for example in an indirectly heated thermistor or by a combination of an incandescent lamp and a photoresistor, with the variable Resistance is built into the controllable voltage divider. In addition, a circuit is also conceivable in which instead of the field effect transistor 12 as a current or voltage controllable component a combination of k a photodiode and a photoresistor or a coil and a magneto-diode component, d. H. a component with a magnetic field dependent Resistance, or the capacitance of a varactor diode is used.

It is also obvious that different combinations of npn and pnp transistors can be used for the transistors Ik and 15, the voltages supplied to the connections 17, 18 and 25 possibly also having different signs. The field effect transistor 12 can be of the n- or p-type. In addition, the low-pass filter can be connected to positive or negative voltage.

When using a frequency-dependent feedback branch with m maximum in-phase transmission, this feedback branch is to be connected to the positive input of the amplifier, while the feedback branch determining the gain is to be connected to the negative input of the amplifier. In the case of feedback branches that result in a phase-shifted signal instead of a signal in phase at the oscillator frequency, both feedback branches must be connected to the same amplifier input.

After all, it is taking into account modern technology conceivable, the comparator with the transistors 1 * f and 15 by a computing amplifier to replace, which is placed in a known manner between the reference voltage and the output AC voltage that sets a pulse generation that is basically the same.

Patent claims:

109824/1195 ^E.

Claims (3)

Claims Control circuit for regulating the amplitude of the AC output voltage a feedback branch with a controllable voltage divider having amplifier, which is part of a feedback oscillator can form or have an automatic gain control, characterized in that a comparator (14, 15, 16) which is connected to a first input the AC voltage of the amplifier (10) and on a second input a fixed or an adjustable reference voltage receives supplied, a pulse generator (19j 20) is connected to the on the ratio between those fed to the comparator (1 ^, 15 »16) Voltage-dependent pulses are generated and fed via a low-pass filter (21, 22) to the controllable voltage divider (11, 12) in such a way that it predominates the amplitude of the output alternating voltage of the amplifier (10) compared to the absolute value of the reference voltage in the sense of a decrease in the gain of the amplifier (10), if the absolute value of the additional voltage predominates however, is adjusted in the sense of a gain increase. 2. Control circuit according to claim 1, characterized in that the comparator contains two transistors (1 * 1-, 15) connected together in a differential circuit, the emitters of which are jointly connected to a constant current source (16) are connected. 3. Control circuit according to claim 1 or 2, characterized in that the low-pass filter consists of a combination of a capacitance (21) and a resistor (22) or an inductance. H. Control circuit according to Claim 1 or 2, characterized in that the low-pass filter consists of a combination of an incandescent lamp and a photoresistor or of an indirectly heated thermistor, the resistance variable component being part of the controllable voltage divider. 109824/1195 5 · Control circuit according to claim 1 or 2, characterized in that as a controllable component in the voltage divider, a current or voltage controllable Component such as the emitter-collector path of a field effect transistor (12) or a combination of a photodiode with one Photoresistor or a coil with a magneto-diode component or the capacitance of a capacitance diode is provided. 109824/1 195