DE912582C - Arrangement for the interconnection of the outputs of several high-frequency amplifiers with different amplification ranges - Google Patents

Description

Arrangement for the interconnection of the outputs of several high-frequency amplifiers with mutually different reinforcement areas The invention relates to an arrangement for the interconnection of the outputs of several high frequency amplifiers with each other different gain ranges., especially for the connection of television antenna amplifiers with several channels on a distribution network common to all channels.

An output circuit for television antenna amplifiers has already become known in which the amplifier outputs are each connected to a common distribution network via a high-frequency band filter with a corresponding pass band. The band filter circuits are designed as a parallel resonant circuit, and the secondary circuits of the band filters are connected in series to the common consumer. With this arrangement, the internal resistance of the output tube of the individual amplifiers can be transformed down to an average output resistance of up to about 300 ohms, and the consumer, ie the characteristic impedance of the distribution network, must be adapted to this resistance value. Since the cables commonly used for the distribution network have a significantly lower wave impedance, e.g. B. 60 ohms, the series-connected secondary circuits of the band filter must be adapted to the distribution network by means of a transformer. Such a transmitter is difficult to manufacture in view of the broad frequency band to be transmitted and, in addition to being more expensive, has the disadvantage of additional linear distortions and losses. In order to save this matching transformer, the band filters could indeed be dimensioned in such a way that a low-ohm output resistance results which corresponds to the characteristic impedance of the distribution network. Such a dimensioning of the band filter encounters considerable difficulties because of the extremely small inductances required and because of the large capacities that can hardly be produced with sufficient low induction and would have one. poor efficiency of the filter and possibly an asymmetry of the transmission curve.

Another circuit has become known in which the aperiodic Amplifier outputs are connected by chokes in such a way that the chokes together a coil line with the output capacitances of the individual amplifier output stages form. The ends of this coil line are connected to the distribution network. There the cross resistance of the coil line is equal to the wave resistance of the distribution network is made, there is an extremely low work resistance for the The output tubes of the amplifier, which is half the characteristic impedance of the connected lines is equivalent to. The amplification of the output stages is therefore low and requires additional expenditure on tubes.

The arrangement according to the invention is characterized in that it Adaptation to low-resistance ones without additional effort on amplifier stages and switching elements Consumer enables. This is done according to the invention using band filters achieved in such a way that the preferably in the anode circuit of the end tube of the concerned The amplifier's primary circuit of the band filter as a parallel resonant circuit, the secondary circuit of the band filter, however, is designed as a series resonant circuit and that the series schw ing circles of the band filter among themselves in parallel to the consumer, z. B. to a line, are connected. The secondary circuits of the band filters are particularly important in antenna amplifier systems for television reception, for example, with, if necessary, locally separated travel points connected to a common line, at both ends of which a consumer, z. B. a wiring harness of a distribution network is connected, and the output resistance the amplifier in the pass band is reduced to about half by the band filter Characteristic impedance of the common line transformed. The transformation on such With the arrangement according to the invention, low resistance values have good efficiency of the band filter and perfect symmetry of the transmission curve possible. Also permitted the new arrangement with a corresponding structure of the secondary circuit either the connection symmetrical or asymmetrical consumer, what with the known arrangement is not easily possible with band filters made of parallel resonant circuits.

According to a development of the inventive concept, primary and Secondary circuit of the band filter connected between the amplifier output and the consumer tunable and preferably for the purpose of changing the frequency position of the pass band both inductively and capacitively coupled to one another in such a way that the Tuning range results in an at least approximately constant passage width. Such an arrangement allows, for example, the individual channels of a television antenna amplifier according to the. local conditions within the individual television areas without having to replace any parts of the amplifier. Of the to achieve a constant passage width over the entire tuning range required proportion of inductive and capacitive coupling can be determined by experiment will. In the higher frequency ranges, e.g. B. in the television sector from r7 ¢ to 223 MHz, the required coupling capacity is usually so small that the 'switching capacity between the primary and secondary coil of the belt filter is sufficient and by choosing one corresponding spacing of the coils can be set. For deeper ones. Frequencies, z. B. for the television range from 4.o to 68 MHz, the additional activation a coupling capacitor may be necessary. The inductive coupling takes place either directly between the circular coils, or it is a special one from one of the filter circuits branched coupling coil is provided, which is preferably on the winding support of the Coil of the other circle is movably arranged. When the tuning of the band filter circuits takes place by shifting a core with respect to the primary and secondary coil, see above the arrangement is advantageously made so that the core movement at the same time effected coupling change takes place in the sense of constant passage width. Significant is that the winding direction and polarity of the coils are chosen so that there is a negative Mutual inductance of the coils coupled to one another results. This avoids that the inductive and capacitive coupling at any point in the tuning range cancel and the transfer rate and the shape of the transmission curve adversely affected will.

The invention and related details are illustrated in FIG. i to 4. for example explained.

Fig. I shows schematically the connection of the output tubes i of three differently tuned amplifiers to a common unbalanced, for example Line 2 designed as a coaxial cable. In the anode circuit of each end tube i there is a parallel resonant circuit as the primary circuit of the band filter, the from a coil 3 and a capacitor q. consists, which by switching and tube capacities can be formed. The secondary circuit of each band filter consists of a coil 5 and capacitor 6 in series, with one end of each series circuit to ground, the other end connected to an en route point of the common line 2 is. The two ends of the line 2 are through consumers with their wave impedance completed, e.g. B. through the two cable strands of a distribution network one Communal television reception system. Of course, it is also possible to have one larger number of amplifier outputs in a manner according to the invention to a common Line to be connected, furthermore, band filters with more than two can be used for the connection Circles apply.

In Fig. 2, the connection of the output tube i of an amplifier is on two lines 7 connected in parallel are shown. The parallel connection of two Lines results in a load resistance for the band filter equal to that of the one corresponds to the arrangement according to FIG and 7 is the same. The coil pair 3, 5 is directly inductively coupled to one another, while the capacitive coupling through the capacitance between the two coils 3 and 5 is formed, which is indicated by the capacitor 8 in the equivalent circuit diagram is.

In the example according to FIG. 3, one of the secondary circuit of the band filter is Coupling coil 9 branched off, which is inductively coupled to coil 3 of the primary circuit and is located, for example, on the bobbin of the bobbin 3.

Fig. Q. shows the course of the locus curve of the complex output resistance of each band filter. The middle one, highlighted by a larger line width Part To of the locus corresponds to the pass band, the two branches i i to the stop band of the band filter. The high capacitive or inductive resistance in the blocked areas allows differently tuned outputs to be connected in parallel without a impermissible mutual influence of the individual gain areas occurs. The cable lengths between the individual. Connection points of the band filter secondary circuits are not critical as long as the frequency ranges are determined by the relevant line section connected amplifier outputs are not directly adjacent to one another, since the line loaded by the consumer works in adaptation. With small Frequency spacing of connected amplifiers does result in a certain mismatch, which, with cable lengths of a multiple. a quarter wavelength of a medium, between the. both gain ranges to a slight frequency Increasing or reducing the diameter of the individual band filters leads to however, it is mostly permissible.

Claims (5)

PATENT CLAIMS: i. Arrangement for the interconnection of the outputs several high-frequency amplifiers with different gain ranges, in which the amplifier outputs each have a high-frequency band filter with a corresponding Passband at a common consumer, e.g. B. connected to a line especially for connecting. TV antenna amplifiers with several Channels, on all channels. common distribution network, characterized in that da.8 which is preferably in the anode circuit of the output tube (i) of the amplifier in question lying primary circuit (3, q.) of the band filter as a parallel oscillating circuit, the secondary circuit (5, 6) of the band filter, however, is designed as a series resonant circuit and that the Series oscillating circuits (5, 6) of the band filters among themselves in parallel to the consumer, z. B. line (2) are connected. 2. Arrangement according to claim i, characterized in that that the primary and secondary circuit of the switched on between amplifier output and consumer Band filter for the purpose of changing the frequency position of the. Passage, B-range can be tuned and preferably both inductively and capacitively coupled to one another in this way are that there is an at least approximately constant over the tuning range Pass width of the filter results. 3. Arrangement according to claim i and 2, characterized in that da.ß for inductive coupling of the primary and secondary coil (3 or 5) of the belt filter a special coupling coil (9) branched off from one of the filter circuits is provided is, which is preferably on the winding carrier of the coil: of the other circle ge: -given.fall movable, arranged. is. q .. Arrangement according to one of Claims 1 to 3, characterized by such a winding direction and such a polarity of the coils (3, 5, 9) that there is a negative mutual inductance of the coils coupled to one another. 5. Arrangement according to one of claims i to q., Characterized in that the Secondary circuits (5, 6) of the band filter with, if necessary, locally separated road points a common line (2) are connected, at both ends of which there is a consumer, z. B. a cable of a distribution network, is connected and wherein the output resistance the amplifier in the pass band through the band filter to about half the characteristic impedance the common line (2) is transformed.