DE1111310B - Filter arrangement for short and very short electromagnetic waves - Google Patents

Description

Filter arrangement for short and very short electromagnetic waves The invention relates to a filter for short and very short electromagnetic Waves, whose constancy and phase angle freedom of the input resistance in the pass band and outside of the pass band brings about a two-pole circuit, which of the Filter input feed line branches off at a point at which the outside filter input impedance to be corrected in the pass band as high Resistance appears, which is the input resistance of the two-pole circuit is parallel, the outside of the filter pass band the size of the input resistance assumes that the filter has in the pass band, while in the filter pass band the input resistance of the two-terminal circuit containing an absorption resistor reaches a high amount, which has no effect on the branching point in this area measurable nominal value of the filter input resistance.

Such a filter arrangement is disclosed, for example, in the United States patent 2,640,916 known. However, this known filter circuit produces the required adaptation only with two discrete frequencies or narrow frequency bands, of which the one frequency or one frequency band corresponds to the filter passband and the other Frequency or the other narrow frequency band to one of the two filter stop ranges listened to.

For filters, primarily for use in antenna switches for operation a transmitter and a receiver on a common antenna, however, is common given the requirement that the input impedance of the filter is real within wide limits and to make it independent of frequency. Since a filter, such as a bandpass filter, has a predominantly real input impedance only in the pass band, im Blocked area or in the blocked areas, however, a pure reactance as Has input impedance, it is very difficult to meet this requirement.

It is true that microwave band-pass filters are state-of-the-art, which are tunable over a smaller or larger frequency range and which have an input resistance in the filter pass band and in the stop bands constant and real on both sides of the passband by means of a two-pole connection is. In contrast to the arrangement according to US Pat. No. 2,640,916 and to Sieve circuit according to the invention is, however, in these microwave filters for also containing an absorption resistor two-pole circuit, which the Brings about constancy and phase angle freedom of the input resistance of the overall arrangement, essentially the same expenditure on components is required as for the one required Four-pole reactance resulting in selectivity.

Furthermore, circuits are known from the field of low-frequency technology, with their help a constant, real input resistance over a larger frequency range is achieved. However, these circuits can be used in particular in the area of the very Short waves can no longer be easily realized, since it is in this wave range in contrast to the low-frequency range, essentially only switching elements with distributed There are inductances, capacitances and resistances.

The invention is based on the object of showing a way that it enables short and very short electromagnetic waves to realize a filter arrangement that has one over a wide frequency range has essentially real and constant input impedance.

This task is, starting from a filter arrangement for short and very short electromagnetic waves, their constancy and freedom from phase angles the input resistance in the pass band and outside the pass band a two-pole circuit brings about the filter input feed line to a Point branches off at which the outside of the pass band to be corrected Filter input impedance appears as a high resistance to which the Input resistance of the two-pole circuit is parallel, which is in the blocking range The size of the input resistance that the filter has in the pass band while the input resistance in the filter passband the one absorption resistance containing two-pole circuit reached a high amount without affecting the nominal value of the filter input resistance that can be measured at the junction in this area is solved according to the invention in such a way that the intended for the two-pole circuit Branch line, the length of which corresponds to half the operating wavelength of the filter and its characteristic impedance with the characteristic impedance of the filter input feed line at least approximately coincides with one serving as an absorption resistor Effective resistance divided into two i./4 pieces by the size of the wave resistance and that the branch line end remote from the branch point terminates an impedance, those in the filter pass band have a characteristic impedance compared to the stub line impedance high and outside the filter pass band a compared to the stub line impedance has low impedance. In contrast to the known circuit, will in the subject matter of the invention, the adaptation to be required between the generator and the subsequent feed line not only in two discrete narrow frequency bands ensured, but from the lower stop band of the filter through the pass band far into the upper restricted area.

The filter circuit according to the invention is described below with reference to Embodiments explained in more detail.

In FIG. 1 there is a bandpass filter 1, for example three-circle switched into line 2, which is a high frequency transmitter, for example for Decimeter or centimeter waves, with a consumer 3, possibly one Antenna, connects. A bandpass filter is known to have the property in the pass band in the case of reflection-free termination on the output side, an input input resistor with practically almost exclusively real components, which, however, are in the Converts the blocking range into a pure, frequency-dependent reactance. In the restricted area of the filter 1, the feed line 2 on the filter inlet side is therefore strongly mismatched, which often results in undesirable repercussions on the sending side.

In order to eliminate the effects of this mismatch, the feed line 2 is bridged by means of a two-pole 4 upstream of the filter 1, of which the following properties are known to be required. In the pass band of the filter, the two-pole 4 should have a high impedance compared to the wave resistance of the feed line. In the blocking range of the filter 1, the two-pole 4 should have an impedance which corresponds at least approximately to the characteristic impedance of the feed line 2.

Waves entering the feed line at point A therefore find provided that their frequency is in the pass band of the filter 1, its real, the Feed line 2 essentially reflection-free final input impedance before. On the other hand, for electromagnetic waves, the frequency of which corresponds to the blocking ranges belongs to both sides of the pass band of the filter 1, which is the characteristic impedance the feed line 2, the same impedance of the two-terminal network 4 is decisive.

In the field of very short electromagnetic waves in which concentrated Switching elements are practically no longer realizable, is suitable for the two-pole o the circuit configuration shown in FIGS. 2 and 3 as an equivalent circuit diagram. In this case, the two-terminal network is formed by a line section that has at least has approximately the same wave resistance as the feed line 2. The length this line section corresponds to half the mean operating wavelength. At a distance from connection point B which is a quarter of the operating wavelength is the same, the;: / 2 line section of the two-terminal network 4 becomes by means of an absorption resistor 5 bridged by the value of the wave resistance of this line section. To the the end facing away from the connection side B, that is, at a distance from the absorption resistance 5, which corresponds to a quarter of the operating wavelength, is the line section completed by means of a parallel resonance circuit, which is set to the band center frequency of the pass band of the filter 1 is matched.

With regard to the influence of the dipole 4 on electromagnetic Waves, which the bandpass filter 1 has to transmit without attenuation, is to be noted that the parallel resonance circuit 6 in the frequency range of the pass band of the filter 1 has a very high impedance caused by the;, / 4 line running between the Parallel resonance circuit 6 and the absorption resistor 5 extends at the point of attachment of the absorption resistor 5 is effective as an infinitely high conductance. The on this way at the place of attachment of the absorption resistor 5 resulting short-circuit point the 2/2 line occurs through the transforming effect of its% / 4 section, which connects the absorption resistor 5 to the connection point B, at the latter as a very high impedance. This high impedance then interferes with the feed line 2 practically not, because their wave resistance is much lower and is much lower for example on the order of 60 ohms.

At frequencies that match the stop bands on both sides of the pass band of the bandpass filter 1 belong, however, is the impedance of the parallel resonance circuit 6 significantly lower than the wave resistance of the adjacent;, / 4 line section, whereby the impedance of the parallel resonance circuit 6 at the point of the absorption resistor 5 as impedance in the frequency ranges adjacent to the filter passband high amount appears. At the place of attachment of the absorption resistor 5 is thus at these frequencies only its resistance value can be measured. Of this Resistance value has already been assumed in the foregoing that it is compatible with the Characteristic impedance of the d / 2 line of the dipole 4 matches. The absorption resistance 5 thus closes in this case the one between it and the connection point B. nJ4 line section located in a reflection-free manner. Hence the entire bipolar 4 at connection point B has an input impedance equal to the value of the characteristic impedance the i / 2 line, that is, for example, about 60 ohms. That works with the arrangement 1 then so noticeable that the line section 2 at point B is practically appears completed without reflection.

To achieve a special, predetermined frequency dependency the impedance curve of the A / 2 line section on the connection side B end facing away from the final impedance, which in the embodiment according to FIG is realized by a parallel resonance circuit, recommends it in some cases, between this impedance and the subsequent 2nd / 4th line section insert a correspondingly dimensioned transformation device 7. Also is In some cases it is advantageous to have an impedance parallel to the absorption resistor 5 to switch a changeable impedance value, for example an adjustable capacitance, in order to make certain corrections to the adjustment ratios afterwards can.

As with known filter arrangements with real and constant Input resistance in the pass band and outside the pass band is at the embodiment of the arrangement according to the invention shown in FIG. 1 the electrical length, denoted by l, of the between the input of the filter 1 and the connection point B of the dipole 4 located section of the feed line 2 chosen so large that the input impedance of the filter 1 is in the blocking range at connection point B appears as high as possible. It will as a result, depending on the frequency between the filter 1 and the two-pole o a more effective distribution of the waves fed into the line section 2 achieved.

The losses in the two-pole o are expedient by a corresponding Adjustment of the filter with regard to its total impedance taken into account. The individual transformation lines become with a larger tuning range The electrical length of the filter and the two-terminal compensation terminal can be changed appropriately trained, e.g. B. by inserting a line extension like a trumpet.

Claims (5)

PATENT CLAIMS: 1. Filter arrangement for short and very short electromagnetic Waves, whose constancy and phase angle freedom of the input resistance in the pass band and outside of the pass band brings about a two-pole circuit, which of the Filter input feed line branches off at a point at which the outside filter input impedance to be corrected in the pass band as high Resistance appears, which is the input resistance of the two-pole circuit is parallel, the outside of the filter pass band the size of the input resistance assumes that the filter has in the pass band, while in the filter pass band the input resistance of the two-terminal circuit containing an absorption resistor reaches a high amount that has no effect on that in this area at the junction measurable nominal value of the filter input resistance, characterized in that the stub line provided for the two-pole circuit, the length of which is half the Operating wavelength of the filter corresponds and its wave resistance with the wave resistance the filter input feed line at least approximately coincides with one another The effective resistance serving as absorption resistance depends on the magnitude of the wave resistance is divided into two AM pieces and that the branch line end remote from the branch point an impedance terminates, which in the filter pass band a compared to the stub line characteristic impedance high and outside the filter pass band a compared to the stub line impedance has low impedance. 2. Arrangement according to claim 1, characterized in that that a parallel resonance circuit serves as the terminating impedance of the i / 2 stub line, the is matched to the center frequency of the filter passband. 3. Arrangement according to claim 1 or 2, characterized in that parallel to the absorption resistance a controllable impedance, preferably capacitance, is connected to the i / 2 stub line is. 4. Arrangement according to one or more of claims 1 to 3, characterized by a transformation device between the i / 2 stub and its terminating impedance. 5. Arrangement according to one of claims 1 to 4, characterized in that the filter and the two-pole are each provided with a tuning device, which is preferably are coupled by means of a synchronizing device. Considered publications: British Patent No. 709,328; U.S. Patent No. 2,640,916; High frequency technology and Elektroakustik, Vol. 60, H. 1, pp. 11 to 19 (July 1942); Telecommunications Zeitschrift (FTZ), Vol. 7, H.12, pp. 688 to 693 (December 1954).