DE1275625B - Amplitude-controlled oscillator circuit - Google Patents

Description

Amplitude Controlled Oscillator Circuit The invention relates to a amplitude-controlled oscillator circuit, consisting of an amplifier with a Input and an output terminal pair, a feedback quadrupole from the output to the input terminals, one located in the series branch of the feedback quadrupole frequency-determining element and a variable damping circuit in the shunt branch of the feedback quadrupole.

Known oscillator circuits generally consist of an amplifier, in which undamped oscillations are generated in that part of its output signal is fed back to its input via a feedback circuit, the phase of the feedback signal must be such that there is an increase in amplitude of the output signal of the amplifier. To determine the frequency with which such an oscillator should oscillate, must be within the feedback loop frequency-determining element are switched on, for example, from a Filter, an oscillating circuit or a quartz crystal can exist. To such a To stimulate the circuit to oscillate, it is necessary that the feedback factor is greater than one, and furthermore, in order to maintain the oscillation process a non-linear operation of the circuit is required.

In general, the amplifier part of this circuit serves as a non-linear one Element. However, if the amplifier reaches its saturation area, then will be Output signal severely cropped. In this case, the fundamental wave must be by means of a additional oscillating circuit or by means of a filter.

The use of inductors to recover the fundamental wave However, due to their high space requirements, the relatively low quality factor and unsatisfactory for price reasons. Also, the clipping level of one will fluctuate amplifier operating in the saturation range as a function of temperature and the supply voltage level, whereby the operational reliability of the circuit is essential is decreased.

If it is necessary that the amplitude of the output voltage have a predetermined value or be adjustable to a certain value should, then the output signal must depend on the impedance of the feedback circuit and be almost independent of fluctuations in the supply voltage.

In order to stabilize the amplitude in oscillator circuits, it is proposed in German patent specification 1103 993 to switch a variable impedance into the feedback path which influences the feedback signal as a function of the oscillator output amplitude. The disadvantage of this oscillator circuit is that the variable impedance affects the feedback signal only after the frequency-determining crystal, so that the undamped feedback signal flows through it. As a result, the crystal can be damaged or destroyed, for example, by large interference signals.

The object of the invention is to provide a circuit in which prevents crystal damage from excessive feedback or interference signals will.

This object is achieved according to the invention in that the connection point for the variable damping circuit in the feedback circuit between the frequency-determining Element and the output terminal is that the variable attenuation circuit consists of at least there is a fixed resistance in the shunt arm of the feedback quadrupole and in parallel the collector-emitter path of a at least part of this resistor Transistor is that the base-emitter path of this transistor via a rectifier circuit is connected to the output terminals of the oscillator so that an increase in the Output signal increases the conductivity of the collector-emitter path and the impedance the damping circuit and the amplitude of the frequency-determining element the signal fed back to the input terminal become smaller.

In the dashed rectangle 5 of the drawing is a known two-stage linear amplifier shown of the two transistors 6 and 7 and an input terminal 8 and an output terminal 9 has.

Such an amplifier can thereby be converted into an oscillator in a known manner be modified that part of the output signal appearing at the output terminal 9 Via a frequency-determining element of the input terminal 8 with such a phase is supplied that the fed back signal tends to the amplitude of the amplifier output signal to increase. Although the amplitude of the feedback signal is the amplitude of the output signal follows and this is proportional, the value of the positive feedback depends on the series impedance of the feedback circuit and the frequency-determining element away. If this impedance is too high, then the feedback factor is too low to cause a To initiate the oscillation process, however, if the impedance is too low, then the works Amplifier in the saturation range.

To ensure that the oscillation process is initiated, the amplifier but does not reach the saturation region, it is necessary that the amplifier operates in A mode and that the impedance of the positive feedback circuit in Depending on the value of the output signal level can be changed. Since the Amplitude of the output signal controlled by the amplitude of the feedback signal can be used, the feedback signal can be used to determine the amplitude of the To determine the output signal.

In the preferred embodiment, a is within the drawing of the dashed rectangle 10 shown emitter follower via a coupling capacitor to the output terminal 9 of the amplifier 5 for the purpose of reducing the output impedance connected so that the oscillator works on a larger load. The emitter follower contains a transistor 11. It goes without saying that this emitter follower can be used not a necessary prerequisite for achieving the method of operation according to the invention the circuit, but only serves to illustrate the versatile application possibilities of the principle according to the invention.

In the embodiment described, the positive feedback signal is tapped from the emitter 12 of the transistor 11 at point 52 and fed back to the input terminal 8 of the amplifier 5 via the feedback circuit containing a resistor 20, capacitors 15 and 16 and a frequency-determining element 17. The frequency-determining element 17 is shown in the drawing as a quartz crystal. Of course, other frequency-determining elements can also be used in this circuit. Part of the output signal appearing at the output terminal 9 of the amplifier 5 is therefore fed back to the input terminal 8 of the amplifier via the emitter follower 10 and the feedback circuit described above. In this exemplary embodiment, the amplitude of the feedback signal fed back to the input terminal 8 is changed in order to control the amplitude of the output signal generated by the amplifier 5.

In order to stabilize the oscillation process an i non-linear characteristic in the feedback circuit is a variable attenuation circuit provided, which contains the two series resistors 21 and 22 between the Point 46 and the voltage reference point 23 in parallel with the feedback circuit described above lie. A part of the feedback current is thus passed through the resistors 21 and 22 branched off, which flows to the reference voltage point 23. Becomes the impedance of the resistors 21 and 22 decreased, then a larger part of the feedback current is through these resistances are derived through to the reference voltage point 23, whereby the Amplitude of the feedback signal is reduced. If, on the other hand, the impedance of the Resistances are increased, then a smaller part of the feedback current is through these resistances are derived through to the reference voltage point 23, whereby the Amplitude of the feedback signal is increased. The amplitude of the feedback signal can thus be changed by varying the impedance of the resistors 21 and 22. As a result, the amplitude of the output signal can also be increased by varying the impedance the resistors 21 and 22 are changed in the inverse proportion.

The impedance of the parallel resistors 21 and 22 can be a function changes in the feedback signal amplitude electronically by varying it the bias values at the base 31 of the regulating transistor 30 as well as at its collector 32 and its emitter 33 can be changed. The collector-emitter range of this Transistor 30 is in parallel with resistor 22, and the change in said Bias values are made as a function of the amplitude of the feedback signal.

The collector 32 of the transistor 30 is connected via resistors 36, 37 and 21 to the negative terminal 35 of a voltage source and the base 31 to the point 29 of a voltage divider, which consists of the combination of the resistors 41 and 42, a diode 45 and the resistor 28 exists between the positive terminal 40 of a voltage source and the reference voltage point 27. As a result of this arrangement, the base 31 of the transistor 30 has a higher positive potential than the emitter 33, which is connected to the reference voltage point 23, at the point in time at which the circuit begins to operate. The conditions for the conductive keying of a pnp transistor are therefore not given, so that the transistor 30 is normally in its non-conductive state. In the blocked state of the transistor 30, the parallel resistances of the damping circuit therefore have their maximum value. This is necessary so that the amplitude of the signal occurring at the output terminal 9 of the amplifier 5, a part of which is fed back to the input terminal 8, has its maximum value in order to initiate the oscillation process. If the amplitude of the output signal of the amplifier increases, then the amplitude of the part of this output signal fed back to the input terminal 8 also increases. Part of the feedback signal occurring at point 47 passes through diode 45 to base 31 of control transistor 30. The negative half-waves of this signal are rectified by diode 45 and fed as a negative bias to base 31 of transistor 30, which now causes the transistor to be conductive necessary conditions are present, ie, the transistor 30 now begins to conduct. This reduces the effective impedance parallel to the resistor 22 of the damping circuit, since the feedback current flowing to the reference voltage point 23 partially flows through the transistor 30. This causes the effective impedance of the variable attenuation circuit to be reduced, so that the amplitude of the feedback signal appearing at point 46 is reduced. If the amplitude of the output signal occurring at the output terminal 9 of the amplifier 5 increases, the larger negative half-waves of the feedback signal caused thereby are rectified by the diode 45 and this rectified negative signal is fed to the base 31 of the control transistor 30, whereby this transistor becomes even more conductive. The resulting increased current flow through this transistor flows in parallel with the resistor 22, whereby the effective impedance of the variable attenuator circuit is further reduced and thereby a further reduction in the amplitude of the feedback signal occurring at the point 46 is caused. This reduced feedback signal strives to reduce the amplitude of the output signal appearing at the output terminal 9 of the amplifier 5 as well. In this way, the impedance of the variable attenuation circuit is influenced in response to changes in the amplitude of the feedback signal.

Because the value of the amplitude of the output signal is the amplitude of the feedback signal is proportional, the output signal generated in the amplifier 5 is dependent regulated and stabilized by fluctuations in the amplitude of the feedback signal.

The signal generated by the oscillator circuit according to the invention can be tapped at the output terminals 50 and 51 and external consumer circuits (not shown) are fed.

In the preferred embodiment, the emitter 10 was, as before mentioned, inserted to reduce the output impedance of the oscillator circuit. It should be noted, however, that this emitter follower, without departing from the inventive concept deviate or impair the operation of the control circuit, also omitted can be, if the point 52 via a capacitor to the output terminal 9 of the Amplifier 5 is connected. In the same way you can without deviating from inventive ideas deviate, changes to the amplifier circuit and the attenuator circuit as well the control.

Although only a preferred embodiment of the invention has been described However, a number of modifications are obvious to a person skilled in the art, which, can be carried out without deviating from the inventive concept.

Claims (3)

Claims: 1. Amplitude-controlled oscillator circuit, consisting of an amplifier with an input and an output terminal pair, a feedback quadrupole from the output to the input terminals, a frequency-determining element located in the series branch of the feedback quadrupole and a variable attenuation circuit in the shunt branch of the feedback quadrupole, characterized in that the connection point (46) for the variable damping circuit in the feedback circuit between the frequency-determining element (17) and the output terminal (52) is that the variable damping circuit consists of at least one fixed resistor (21, 22) in the shunt arm of the feedback quadrupole and parallel to at least one Part of this resistor (22) the collector-emitter path of a transistor (30) is that the base-emitter path of this transistor is connected via a rectifier circuit to the output terminals of the oscillator so that an increase in the output signal the conductivity of the collector-emitter path increases and the impedance of the damping circuit and the amplitude of the signal fed back to the input terminal via the frequency-determining element become smaller. 2. Amplitude-controlled oscillator circuit according to claim 1, characterized in that the output signal controlling the transistor (30 ) is applied to its base (31) via a diode (45). 3. Amplitude-controlled oscillator circuit according to claim 1, characterized in that an emitter follower (10) is provided for output impedance matching. Publications considered: German Patent No. 1103 993.