DE1056199B - Switchable circuit arrangement for the optional selective transmission of two frequency bands with very different band center frequencies - Google Patents

Description

Switchable circuit arrangement for optional selective transmission of two frequency bands with very different band center frequencies The invention relates to a switchable circuit arrangement for optional selective transmission of two frequency bands with very different band center frequencies from the anode circuit an amplifier tube to the grid circle of the subsequent amplifier tube using an oscillating circuit as a selective component for the frequency band with the higher Band center frequency as well as two coupled resonant circuits as selection means for the frequency band with the lower band center frequency, especially for intermediate frequency levels of radio receivers. _ It is known to have several individual circles, e.g. B. in series to switch and with circles of the same type and corresponding coupling to band filters summarize. Also are often z. B. with combined AM-FM receivers circles for frequencies that are a long way apart, connected in series. As a result of the large frequency differences, one circle is next to the other frequency ineffective, either because the capacitor of one circuit at high frequencies as a short circuit (or the inductance as practically infinite high resistance) acts, while the inductance of the other circuit contributes lower frequencies practically as a galvanic connection and the associated capacitor acts as a blocking capacitor.

However, it is often desirable to have a single circle with a Combine band filters. This is necessary, among other things, when high Gain should be achieved or if there are special demands on the edge steepness the transmission curve of the VHF IF amplifier, but on the other hand at AM a band filter should be used.

If you take it now, as it is in order to achieve a high gain Transmission of the greatest possible energy is obvious, a fixed coupling if necessary with a third winding, the band filter curve is a consequence the winding capacities are falsified. To circumvent this effect one has already made a loose coupling. However, this has the disadvantage of being low Energy transfer an occurrence of natural resonances, e.g. B. in the 10.7 MHz circle, and thus also a certain falsification of the band filter curve, since the Tube capacity together with the coupling winding also forms a circle and thus again forms a band filter. The invention overcomes these disadvantages and at the same time saved a number of switching means and individual parts. Simultaneously the arrangement according to the invention has the advantage that the grid of the next tube for the ripple voltage becomes low-impedance and thus causes extensive freedom from interference. The invention is characterized by switching means that have the in the anode circuit first amplifier tube located, for the transmission of the frequency band with the lower band center frequency provided parallel resonant circuit, which together with one of the two arranged in series in the grid circle of the second amplifier tube Parallel resonant circuits with an inductively coupled band filter for the frequency band the lower frequency position forms when switching the circuit arrangement to Split the transmission of the frequency band with the higher band center frequency in such a way that that the coil of this resonant circuit acts as the anode choke of the first amplifier tube becomes effective and the capacitor of this resonant circuit acts as a coupling capacitor serves, which connects the end of the anode choke close to the anode with the connection of the close to the grid second Parallel.s, chwingkrevses, located in the grid circle of the following amplifier tube which connects to the band center frequency of the frequency band with a higher frequency position is matched.

The invention is explained in more detail using an exemplary embodiment.

Fig. 1 shows a known arrangement for a band filter with primary and on the secondary side two different circuits connected in series; Fig. 2 is a known embodiment for the use of a primary and two secondary circuits; Fig. 3 is an embodiment with a switchable capacitor; Fig. 4 is an arrangement according to the invention; 4 and 5 are equivalent circuit diagrams for various switchings according to the invention.

Fig: 1 shows the usual circuit of a band filter with two in Series connected different circles for z. B. an IF circle. The band filter 1 is arranged between the two IF tubes 2 and 3. The primary circuits of the band filter are connected to the anode of the tube 2 and consist aus.einem circle 4 of z. B. 10.7 MHz and a series-connected circuit 5 for z. B. 470 kHz. Appropriate Circles 6, 7 are coupled to circles 4, 5 and are attached to the grid 8 of the tube 3 switched on.

If the coupling is now (Fig. 2) fixed for one of the cases detailed above, for example by providing a third winding 9, the winding capacitance, which is indicated schematically by part 10 , is included in the band filter curve of circles 5 and 7 and falsifies their characteristics (Fig. 3).

Fig. 4 now gives an example according to the invention, according to which these disadvantages are avoided. The anode of the tube 2 is assigned the inductance 11, which when switching the switch 12 in position 12 a, 13 with the capacitance 14 an oscillating circuit from Z. B. supplies 470 kHz. At an IF of 470 kHz, a Coupling with the associated secondary circuit 7. The one connected in series with circle 7 VHF circuit 6 is practically ineffective at these frequencies, since the inductance 6 a represents a galvanic connection for these frequencies. If now z. B. on VHF (FM) switched, the switch 12 is brought to position 13, 15. As As can be seen, the capacitor 14 is now switched to a coupling capacitor while the coil 11 is now connected as a choke coil. In this way the greatest possible energy is supplied to circuit 6. The circle 7 works in this Case as a short circuit, since the capacitance 7 a is practical at the high frequencies represents a short circuit. As can be seen, the special arrangement of the Switch at the same time the grid for the ripple voltage has become low-resistance and a number of switching means and individual parts have been saved. This embodiment therefore appears particularly suitable for realizing the idea of the invention.

4 and 5 illustrate once again the switchover to the switch position 12, 13 (Fig. 5) and 13, respectively; 15 (Fig: 4). The electrically inactive parts are has been omitted here.

The circuit can also be modified in various ways, e.g. B. also interconnect the tubes on the anode side and place the switch on the grid. Fig. 3 shows an embodiment with a switchable capacitor. The series-connected circuits I and II are connected to the contact of the switch a, b, c via the capacitor 10 a. In AM operation, contact b is connected to contact c, while in FM operation, contacts a and b are connected, so that circuit 3 is switched off. However, the invention still saves the capacitor 10a and applies the ripple voltage to ground via circuit 6, 7, while it is grounded according to FIG. 3.

Claims (1)

PATENT CLAIM: Switchable circuit arrangement for optional selective Transmission of two frequency bands with very different band center frequencies from the anode circuit of an amplifier tube to the grid circle of the following amplifier tube using an oscillating circuit as a selective component for "the frequency band with the higher band center frequency and two coupled resonant circuits as selection means for the frequency band with the lower band center frequency, especially for intermediate frequency levels of radio receivers, characterized by switching means, the in the anode circuit the first amplifier tube located, for the transmission of the frequency band with the lower band center frequency provided parallel resonant circuit, which together with one of the two arranged in series in the grid circle of the second amplifier tube Parallel resonant circuits with an inductively coupled band filter for the frequency band the lower frequency position forms when switching the circuit arrangement to Split the transmission of the frequency band with the higher band center frequency in such a way that that the coil of this resonant circuit acts as the anode choke of the first amplifier tube becomes effective and the capacitor of this resonant circuit acts as a coupling capacitor serves, which connects the end of the anode choke close to the anode with the connection of the close to the grid second parallel resonant circuit located in the grid circle of the following amplifier tube which connects to the band center frequency of the frequency band with a higher frequency position is matched.