DE1090277B - Circuit arrangement for limiting the voltage amplitude of high-frequency oscillations in an oscillating circuit - Google Patents

Description

Circuit arrangement for limiting the voltage amplitude of high-frequency oscillations on an oscillating circuit The invention relates to a circuit for limiting the voltage amplitude on an oscillating circuit, especially for purposes of FM reception. Except for the limiter circuits, which are based on an overdrive of grid-controlled Tubes are based, mainly diodes come into consideration for such a limitation. The common diode limiter circuits work on the principle of load of the oscillation circuit through a biased diode. As soon as the peak tension the value of the DC voltage serving as the diode bias voltage on the resonant circuit exceeds, a current flows through the diode, which is a strong additional load represents the resonant circuit voltage, so that with a further increase in the exciting EMF or inflow only increases slowly. Instead of a fixed bias is also often one generated by the rectifying effect of the diode itself and by means of a capacitor of very large capacitance over the duration of interference pulses used bias voltage held away, e.g. B. in the very common ratio detector circuit.

With the well-known principle of loading the oscillation circuit described above by a diode there is necessarily an increase in the emf with increasing emf Bandwidth of the oscillatory circuit connected. In the case of the ratio detector, this is necessary, because this is the only way to get a full circuit with this circuit Compensation for AM interference is given. However, if you want a load diode on one Use an oscillating circuit that is not used for FM-AM conversion at the same time, so is the increase in bandwidth is undesirable because it reduces the selection.

An amplitude limiter is known (French patent specification 929 003) in which this disadvantage of worsening the selection is avoided. It consists of a diode which is placed in series with a capacitor in a coupling line feeding the oscillating circuit and at the same time connected in series with a DC voltage source and an impedance. The bias voltage supplied by the direct voltage source is polarized and dimensioned in such a way that no direct current flows through the diode up to a desired threshold value. The impedance is a choke at which the amplitude modulation to be eliminated generates a low-frequency voltage which is superimposed on the bias voltage in such a way that the positive high-frequency pulses passed by the diode are all of the same size, while the envelope of the high-frequency oscillations in the blocked area is on the negative. Side has twice the amplitude of the original amplitude. This results in, although a suppression of the amplitude modulation, JE but the amplitude of the transmitted pulses is changed at a slow change of the input amplitude, and stronger than the input amplitude. If the bias voltage is not taken from a DC voltage source, but instead is generated according to the same reference from the diode current at an ohmic resistor connected in series with the choke, the slow fluctuations are smaller, but still present.

The invention, however, shows one. Amplitude limiter, which is also slow Eliminates amplitude fluctuations and thereby has the advantage of the amplitude limiter described above, namely, no impairment of selectivity is retained.

The invention relates to the circuit arrangement described to limit the voltage amplitude of high-frequency oscillations in an oscillating circuit using a single diode in series with a capacitor in a coupling line feeding the oscillation circuit is laid and at the same time in series is connected to a DC voltage source and an impedance. According to the invention the DC voltage of the DC voltage source is large compared to the peak value of the highest occurring high-frequency voltage and polarized so that the diode, in particular a semiconductor diode through which a bias current flows in the forward direction, and the impedance consists only of an ohmic resistance that is so large is that the bias current determining the threshold value of the limitation flows. With increasing Alternating clamping in the input of the circuit enlarged see how is explained in more detail below, the effective impedance of the diode, and it thereby becomes the Inflow into the oscillation circuit is limited.

It is known per se to have two diodes with one another in an LF amplifier reverse polarity to switch so that a coupling alternating current through both Diodes flowing through in the forward direction, by means of a high series resistance is limited in its strength fixed direct current. At every half oscillation of the supplied alternating current, the diode in the reverse direction has a limiting effect. The coupling alternating current can then not rise significantly above the direct current value: Interfering impulses that are superimposed on the NF and briefly reach high peak tverte, can thereby be cut off.

The invention is based on the knowledge that in the application this principle only requires a single diode on circuits with an oscillating circuit is because the corresponding harmonics are outside the transmission range fall, and that this has the particular advantage of avoiding harmful damping occurs. Furthermore, by using a single diode, the advantage of a achieved sharper limitation use. For the alternating voltage only occurs at this a diode a voltage drop on; whereby the energetic efficiency of the circuit is improved at small amplitudes.

The capacitor in series with the diode according to the invention should receive such a capacitance value that its impedance for the working frequency of the oscillating circuit is smaller than the impedance of the one operated in the forward direction Diode is. On the other hand, the capacity should be so small that the through it together with the series resistor, a sufficiently fast time constant Limitation use enabled. At the usual intermediate frequency of 10.7 MHz in FM receivers is e.g. B. to choose a capacitance of the order of 100 pF.

Can a suitable compromise between sufficiently small impedance of the capacitor for the working frequency and a sufficiently small time constant are not achieve, according to a development of the invention in series with the capacitor correspondingly smaller capacitance switched an additional inductance, which with this capacitance together results in series resonance for the operating frequency.

The invention is illustrated by the figures described below explained in more detail. Of these: FIG. 1 shows a current limiter circuit according to FIG Invention, Fig. 2 the time course of the diode current with a low input voltage, 3 shows the same course with a large input voltage, FIG. 4 shows a limiter characteristic the circuit according to the invention, FIG. 5 shows a current limiter circuit according to the invention with neutralization of the residual capacitance of the diode, FIG. 6 shows a current limiter circuit according to the invention in front of a ratio detector.

In the circuit shown in Fig. 1, an intermediate-frequency input voltage U, is fed via a capacitor C1 to a voltage divider whose upper divider resistance consists of a diode D and whose lower divider resistance consists of a tapped oscillating circuit LC. The stepped-up output voltage is labeled U ". The diode D is fed a direct current in the forward direction from a direct voltage source B, which can be the anode voltage source, via a high series resistor R - @ -. Because of the direct current I- flowing in it, the diode D is for IF alternating currents, the amplitude of which is smaller than the direct current value, fully conductive In FIG. 2, the course of the total diode current ID is shown as a function of the time t for this case.

If you now apply a much higher input AC voltage U, where but is again presupposed; that the tension of B is still great compared to the Peak value of U, sup, then there is a strong increase in the over a period averaged resistance of the diode D. The current curve in this for large tle is shown in FIG. 3. The power surges are of relatively short duration, so that the instantaneous values are relatively high, but the mean DC value is nonetheless remains approximately unchanged: This diode current curve results in the context in order to; that the capacitor occupancy of C1 facing the diode has a negative charge except for a span width slightly below the amplitude value of U. Maintaining the mean direct current value then also requires it to remain constant the fundamental wave amplitude of the diode current, which is responsible for the excitation of the oscillation circuit is decisive in its resonance frequency.

In Fig. 4 is shown; how with increasing input voltage U, in the circuit according to FIG. 1, the output voltage produced at the oscillating circuit U "changes: The result is the typical limiter characteristics.

Appropriately, from the coupling line to the oscillation circuit in Fig. 1 applied such a transformation that its resonance resistance to the one to three times the value of the forward resistance that the diode has in its Having supply with the selected direct current; is adapted. This represents the cheapest A compromise between a sharp use of the limitation and good efficiency the arrangement: If one wants the circuit according to the invention for limiting the amplitude at a relatively high frequency (e.g. VHF-IF with 10; 7 MHz), so does the alternating current conductance formed by the diode capacitance is disadvantageously noticeable; the limiting effect is worsened. According to a further development of the invention therefore becomes a neutralization circuit for the capacitance of the limiter diode provided and the neutralization for the operating state with the greatest input amplitude set. In Fig. 5, an embodiment is shown, which such Includes neutralization circuit. The neutralization branch consists of a T-circuit from three capacitors C2, C3, C4, to despite the small Diodenkapäzität with larger ones To be able to work capacities in the neutralization branch. The neutralization branch is coupled to L by means of the coupling winding L3, while the diode branch is via L, is coupled. The remaining designations in FIG. 5 correspond to those in FIG. 2. CD represents the harmful capacitance of the diode D, which results from the junction capacitance and is composed of the building capacity. The former is known to decrease with increasing voltage in the reverse direction, d. H. with increasing loading of the Capacitor C1 through the DC voltage switching of the diode. One will for the neutralize the highest possible charge, as the resulting The impedance of the diode should be as large as possible.

L in Fig. 5 represents the above-mentioned additional inductance through which even with a small Ci value, e.g. B. 30 pF, a small one due to series resonance Impedance is achieved in front of the diode. Said inductance can also be achieved by the Leakage inductance of coupling coils in the coupling line is shown be e.g. B. the leakage inductance of L2 in Figs.

The diode limiter circuit according to the invention is used as an additional limiter applicable to a ratio detector. An additional limiter is used either for this reason because the limiting effect of the ratio detector alone is not sufficient (interference interference through multi-way reception of frequency-modulated broadcasts!) or if there is a risk of occurrence Inadmissibly high directional voltages on a ratio detector equipped with germanium diodes consists. In Fig. 6 is an embodiment for a ratio detector circuit with the diode limiter according to the invention shown as a pre-limiter. An additional Oscillating circuit C5, L5 is in the anode line of an IF driver tube V. Von a tap a at L5 passes the intermediate frequency via a capacitor Ci and a diode D to a coupling coil L2, which is coupled to the oscillating circuit LC is. This oscillating circuit represents the primary circuit of the actual ratio detector from three capacitors C2, C3, C4 and one, for example, symmetrical to L2 Coupling coil L3 is a branch to neutralize the harmful capacitance the diode D. The high resistance R1 serves to remove the diode D from the anode voltage source to supply the tube V with a direct current in the forward direction. The left end of this Resistor R1 could also be connected directly to the positive pole of the anode voltage source.

The further circuit is known. A secondary circuit of the ratio detector consisting of a center-tapped inductance L6 and a capacitance C6 forms the secondary circuit of the ratio detector, to which two diodes D1 and D2, a capacitor C9 with a large capacitance and a variable resistor R2 for setting the AM minimum are connected. L6 is inductively coupled to L on the one hand, and galvanically coupled on the other hand via a line from a tap on coil L to the center tap of L6. From the base of the oscillating circuit L6, C., the low-frequency voltage NF is picked up via a low-pass filter formed from a resistor R3 and two capacitors C and C8.

With the addition of the oscillating circuit C5, L5 and the diode pre-limiter, not only the limitation but also the selection can be significantly improved compared to the conventional ratio detector circuit without a pre-limiter.

Claims (5)

PATENT CLAIMS: 1. Circuit arrangement for limiting the voltage amplitude of high frequency oscillations on an oscillating circuit using a single one Diode, which in series with a capacitor in one of the oscillating circuit feeds Coupling line is laid and at the same time in series with a DC voltage source and an impedance is connected, characterized in that the DC voltage of the DC voltage source large compared to the peak value of the highest occurring high-frequency voltage and is polarized in such a way that the diode, in particular a semiconductor diode, is fed by a bias current is traversed in the forward direction, and that the impedance is only from an ohmic Resistance exists, which is dimensioned so large that the threshold of the limitation determining bias current flows. 2. Circuit arrangement according to claim 1, characterized in that that to the capacitor of relatively small capacitance an additional inductance in Is connected in series, which together with this capacitance series resonance for the working frequency results (Fig. 5). 3. Circuit arrangement according to claim 1, characterized by a such a transformation from the coupling line to the oscillation circuit, e.g. B. by Connection of the coupling line to a corresponding tap of the oscillation circuit, that its resonance resistance is one to three times the value of the forward resistance, which the diode has when it is fed with the selected direct current is. 4. Circuit arrangement according to claim 1, characterized in that a neutralization circuit for the capacity of the limiter diode is provided and that the neutralization for the operating state is set with a large input amplitude (Fig. 5). 5. Circuit arrangement according to claim 1, characterized in that the oscillating circuit is the primary circuit of a ratio detector operated in particular with germanium diodes (Fig. 6). Documents considered: German Auslegeschrift No. 1007 387; French patent specification No. 929 003.