DE972521C - Circuit arrangement for radio receivers based on the superposition principle with tunable ferrite rod antenna for suppressing intermediate frequency interference - Google Patents

Description

When using matched ferrite rod antennas in radio receivers based on the superposition principle it is often common to have a connection for the medium and long wave range Provide external antennas with capacitive base coupling. A trap circuit for the intermediate frequency is normally switched into the line from the antenna connection to the coupling point of the pre-circuit in order to avoid interference from the External antenna to be suppressed by signals that are in the intermediate frequency range (Fig. I).

This and other previously known arrangements with blocking and suction circuits, however, have the disadvantage that the circuit for suppressing the intermediate frequency is only effective when receiving with an external antenna, while it is ineffective with direct reception by the voice coil L _{1 designed} as a ferrite rod antenna, since the interference voltage occurs in the circle itself and takes effect unhindered on the grid of the following tube, ao

In addition to the usual disturbances, this fact can also have the consequence that in the case of crowded areas Build-up due to the interspersion of the amplified intermediate frequency from the device. Feedback step on the ferrite rod antenna, which can lead to self-excitation.

909 571/10

There are now known input circuits for radio receivers in which resonant circuits for filtering out a desired frequency or switching elements of the same are combined with other switching elements in such a way that blocking or suction circuits for suppressing certain frequencies, eg image frequencies, are created. However, the previously known arrangements are not suitable for remedying the above-described case. Due to the known state of the art of such arrangements, it would perhaps be obvious _{to dimension the capacitor C 2 of} the base point coupling to the resonant circuit in such a way that it _{forms a series resonant circuit with the voice coil L 1} that is matched to the frequency to be suppressed, which the interference frequency of the at the upper end of the circular coil L ₁ sucks the grid of the tube. For the case considered here, however, in which the intermediate frequency is to be suppressed below, the capacitor C _{2 would become} so small with the relevant reception frequency ranges and usual intermediate frequencies that the antenna coupling is too tight and thus the values for operational quality, synchronization, image wave selection close can be unfavorable. So this measure is not possible.

The invention now shows a way in which the above-mentioned disadvantages and disturbances can be eliminated. The idea of the invention is that a series circuit of a coil L ₂ and a capacitor C _{6 is} connected in parallel to the base _{capacitor C 2 of the} usual size of the pre- circuit (Fig. 2) and is dimensioned such that the combination of C ₂ , L ₂ and C ₆ at the intermediate frequency f _z acts like a capacitance that _{results in a series resonance circuit with the ferrite antenna circuit coil L 1} (Fig. 3), while it corresponds to _{a capacitance of the value of C 2 at the frequencies further from the receiving ranges.} Due to the suction resonance occurring at f _z , intermediate frequency interferences, which are picked up _{directly by the ferrite rod antenna L 1} , are sucked off and reach the grid of the following tube in a considerably weakened manner. Figs. 1 to 3 are explained in more detail below to understand the invention:

Fig. Ι shows the scheme of a conventional input circuit of a superposition receiver with capacitive base coupling of the antenna. The coil L ₁ in series with the capacitor C ₂ and the capacitors C ₃ and Tr form the input circuit which can be tuned to the input frequency by the capacitance C _{3, which is designed as a variable capacitor.} At the base _{capacitor C 2} , the antenna is coupled to the circuit via the coupling capacitor C _{A in a known manner.} Usually, a trap circuit L _s , C _s tuned to the intermediate frequency f _{z is} connected to the antenna feed line in order to prevent intermediate frequency interference voltages from reaching the circuit from the antenna. As already stated, this arrangement fails, however, if the circular coil L _{1 is designed} as a ferrite rod antenna and picks up intermediate frequency interference voltages directly from the field. Considerable disruptions can then occur as a result.

Fig. 2 shows the diagram of an input circuit with the inventive connection of an LC combination in order to prevent the occurrence of disturbances through direct inclusion of the ferrite rod antenna. The essence of the present invention consists in the connection of a series connection of a coil L ₂ and a capacitor C ₆ parallel to the base _{capacitor C 2 of} normal size and such a dimensioning of L ₂ and C ₆ that in the input _{resonant circuit between the combination C 2} , L ₂ , C ₆ and the resonant circuit coil L ₁ is a Saugresonanz arises, through which the ferrite rod antenna L ₁ received intermediate frequency disturbances are filtered off with suction and the occurrence of the above-mentioned interference and feedback phenomena is suppressed without through the connection of L ₂ and C ₆ of the input value and the Synchronization of the circuit is impaired in the reception frequency ranges that are normally in question. The frequency curve of the combination C ₂ , L ₂ , C ₆ and the occurrence of the desired suction resonance will be explained with reference to FIGS. 2 and 3.

Let the series circuit L ₂ , C ₆ be dimensioned and tuned so that its series resonance f _{t is} lower than the intermediate frequency f _z at which the suppression effect is to be achieved. The series connection of L ₂ is effective at frequencies higher than f _t . and C _e then as an inductance increasing with frequency (Fig. 3, curve 2), which, with the parallel base capacitor C _2, results in a parallel resonance at frequency Z ₂ (Fig. 3, curve 3). The overall circuit L ₉ , C ₆ parallel to C ₂ acts at higher frequencies than f ₂ like a capacitance increasing with the frequency (Fig. 3, curve 3), which with the correct setting of f ₂ and Z ₁ at the intermediate frequency f _z the circular coil L _{1 forms} a suction circuit resonance (Fig. 3, curve 5), which prevents the interferences in the intermediate frequency range picked up directly _{by the ferrite rod antenna L 1 from affecting the grid of the following tube.} In the case of f ₂ further from past frequencies of the normal reception areas is the frequency response of the combined n ₀ nation C _2, L _2, C ₆ (Fig. 3, curve 3) in the capacitor C ₂ (Fig. 3, Curve 1 ) so that the antenna coupling and the synchronization are not impaired.

The circuit arrangement according to the invention therefore suppresses the intermediate frequency interference reached directly by the resonant circuit coil designed as a ferrite rod antenna can be taken out of the field without the normal operation of the circuit in the receiving frequency ranges is disturbed.

Claims (1)

PATENT CLAIM: Circuit arrangement for radio receivers based on the superposition principle with tunable Ferrite rod antenna to suppress Interference frequency interference and connection option for an external antenna by means of a capacitive base point coupling to the ferrite rod antenna, characterized in that a suction circuit (C ₈ , L _{2 ) is connected in parallel to the base point capacitor (C 2} ) of the antenna circuit and is coordinated so that it 'is connected to the base point capacitor ( C ₂ ) and the ferrite antenna coil (L ₁ ) results in a series resonance for the intermediate frequency. Considered publications: German patents No. 297 908, 712 261, 807965; German patent application S 24850 VIII a / 21 a ⁴ (published on November 13, 1952); German utility model No. 1 654 851; British Patent Nos. 415 017, 450272; Pitsch, "Textbook of radio reception technology", 1948, pp. 274 and 278. 1 sheet of drawings © 509 630/90 1.56 (909 571/10 7.59)