RU2459349C2 - Tunable lc band-pass filter - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: tunable LC band-pass filter, consisting of an input band-pass filter, having a first inductance coil whose first lead is connected to the input potential terminal of the filter and the second lead is connected to a first capacitor and a second inductance coil, the second leads of the second inductance coil and the first capacitor are connected to a common bus, and an output band-pass filter, having a third inductance coil whose first lead is connected to the output potential terminal of the filter and the second lead is connected to a second capacitor and a fourth inductance coil, the second leads of the second capacitor and the fourth inductance coil are connected to the common bus; the device further includes a first signal bus which is connected to the second lead of the first inductance coil and a second signal bus which is connected to the second lead of the third inductance coil; the device also includes N structure-identical sections, each having a third, a fourth and a fifth capacitor, as well as an input and an output electronic switch, wherein the third capacitor is connected by the first lead to the first lead of the fourth capacitor and simultaneously to the first lead of the input electronic switch, the second lead of which is connected to the first signal bus; the second lead of the fourth capacitor is connected to the first lead of the fifth capacitor and simultaneously to the first lead of the output electronic switch, the second lead of which is connected to the second signal bus, wherein the second leads of the third and fifth capacitors are connected to the common bus.

EFFECT: high transfer constant of the tunable band-pass circuit at operating frequency.

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Description

The present invention relates to electronics and can be used in preselectors of professional radio receivers.

A number of band-pass LC filters are known that can be used to construct discretely tunable band-pass circuits. At the same time, for tuning, as a rule, a change in the capacitance of the capacitors included in the filter circuit is used.

Of the many solutions considered, preference is given to filters containing the least number of inductances, as well as to those circuits in which discretely variable capacitors have a connection to a common bus. In this case, the filter circuit closest to these characteristics is a cascade connection of ladder bandpass filters containing parallel circuits in the transverse branches, and inductors in the longitudinal branches [1]. We selected this type of filter as a prototype. Two cascade-connected links of such a filter have an inductive coupling between the circuits; they realize the second class in attenuation and the first class in characteristic resistance. This allows, when tuning the average filter frequency by changing the capacitance of two capacitors, to change the tuning frequency over a wide range, keeping the relative bandwidth constant, and not to change the equivalent filter loads at the input and output.

The disadvantage of this filter is that the transmission coefficient of the filter when performing narrow bandwidths will not be high enough.

The objective of the invention is to increase the transmission coefficient of the tunable band-pass circuit at operating frequencies.

The problem is solved by introducing into the known circuit a band-pass filter, which consists of an input band-pass filter containing a first inductor, the first output of which is connected to the input potential terminal of the filter, and its second output is connected to the first capacitor and second inductor, the second conclusions of the first capacitor and a second inductor connected to a common bus, and an output bandpass filter containing a third inductor, the first output of which is connected to the output potential filter terminal, and its second terminal is connected to the second capacitor and fourth inductor, the second terminals of the second capacitor and fourth inductance are connected to a common bus, an additional first signal bus connected to the second terminal of the first inductor, and a second signal bus connected to the second output of the third inductor, in addition, N sections are identical in structure, each of which contains a third, fourth and fifth capacitor s, as well as input and output electronic keys, while the third capacitor is connected to the first output of the fourth capacitor by the first output and simultaneously to the first output of the input electronic key, the second output of which is connected to the first signal bus, the second output of the fourth capacitor is connected to the first output of the fifth capacitor and simultaneously to the first output of the output electronic key, the second output of which is connected to the second signal bus, while the second conclusions of the third and fifth capacitors are connected to a common by bus.

Comparative analysis shows that the claimed technical solution differs from the prototype in that the first signal bus connected to the second terminal of the first inductor and the second signal bus connected to the second terminal of the third inductor are additionally introduced into the device, and N identical according to the structure of sections, each of which contains a third, fourth and fifth capacitors, as well as input and output electronic keys, while the third capacitor is its first output connected to the fourth capacitor and simultaneously to the input electronic key, the second terminal of which is connected to the first signal bus, the second terminal of the fourth capacitor is connected to the fifth capacitor and simultaneously with the output electronic key, the second terminal of which is connected to the second signal bus, the second terminals of the third and fifth capacitors connected to a common bus.

When comparing the claimed technical solution not only with the prototype, but also with other well-known technical solutions in science and technology, solutions with similar characteristics were not found.

Figure 1 shows the electrical diagram of the proposed device. The device consists of an input band-pass filter 1 containing a first inductor 2 connected to an input potential terminal and a second output connected to a second inductor 3 and a first capacitor 4, the second terminals of which are connected to a common bus, and from the output band-pass filter 5, containing a third inductor 6, the first output of which is connected to the output potential terminal of the filter, and its second output is connected to the second capacitor 7 and the fourth inductor 8, the second conclusions of which connected to a common bus, the device also contains a first signal bus 9 connected to the second terminal of the first inductor, and a second signal bus 10 connected to the second terminal of the third inductor, in addition, the filter includes N sections 11 identical in structure, each of which contains the input electronic key 12 and the output key 13, as well as capacitors: the third 14, fourth 15, fifth 16, while the input key 12 is connected to the first signal bus 9 and the third capacitor 14, the first output of which is also connected to the four rtym capacitor 15, a second terminal of which is connected to the fifth capacitor 16 and the output key 13, a second end connected to the second signal line 10, the second terminals of capacitors 14 and 16 are connected to a common bus.

The device operates as follows.

When connecting any one section (the keys 12 and 13 of this section are closed, the keys 12 and 13 of the remaining sections are open) we get the bandpass filter circuit shown in figure 2. This circuit differs from the prototype in that a capacitive coupling is introduced between the input and output links (the prototype contains an inductive coupling between parallel circuits). Provided that the inductances of the first and third coils are the same and equal to L ₂ , the inductances of the second and fourth coils are also the same and equal to L ₁ . This circuit can be reduced in accordance with Bartlett’s theorem [2] to a symmetric bridge equivalent containing reactance Z _a and Z _b in the branches, the circuits of which are shown in Fig. 3. With an appropriate choice of the values of the elements of this circuit, one can obtain the frequency dependences of the resistances Z _a and Z _b shown in Fig. 4.

To fulfill this condition, it is necessary to determine the values of the circuit elements L ₁ , L ₂ , C ₁ and C ₂ according to the formulas:

where ω ₀ is the average filter frequency;

ω ₁ , ω ₂ , ω ₃ - resonant frequencies of the two-terminal networks Z _a and Z _b shown in figure 4;

Z _m is the characteristic resistance of the filter at a frequency ω = ω ₀ .

As can be seen from figure 4, the filter has a second class in attenuation and a first class in characteristic impedance, that is, it implements the same parameters as the filter prototype. Unlike the prototype, the original filter contains fewer inductors (four instead of five).

At the same time, the resonant frequencies of the two-terminal circuits, expressed in terms of the values of the circuit elements, are determined by the relations:

These relations are valid provided that L ₁ C ₁ = L ₂ C ₂ , which is necessary for the frequencies of the parallel resonance of the two-terminal Z _a and the serial resonant two-terminal Z _b to coincide.

и остается неизменной относительная ширина полосы пропускания фильтра

. Номинальное сопротивление фильтра Z_m, как видно из соотношений (1), будет изменяться пропорционально частоте ω₀.As can be seen from relations (2), with simultaneous and proportional changes in capacitances C ₁ and C ₂ and constant values of L ₁ and L _{2, the} squares of frequencies ω ₁ , ω ₂ , ω ₃ will proportionally change. In this case, the average filter frequency will change

and the relative filter bandwidth remains unchanged

. The nominal filter resistance Z _m , as can be seen from the relations (1), will vary in proportion to the frequency ω ₀ .

Connection in parallel to the first switched on section of an additional one (or several) sections will lead to a simultaneous and proportional change in the capacitances of the capacitors C ₁ and C ₂ and, consequently, to a change in the average frequency of the filter. The capacitance values of the capacitors 14-16 are selected so that the capacitance of the capacitor 14 of the second section is twice as large as the capacity of the capacitor 14 of the first, in the third section, the capacitance of the capacitor 14 is also twice as large as the capacitor of the second section, etc. The same proportionality was chosen for the remaining capacitors included in the subsequent N-1 sections.

The number of keys in the filter is 2 N and will depend on the requirements for the accuracy of the installation ω ₀ when it is tuned in a given frequency range.

To ensure the maximum possible transmission coefficient of the filter during the adjustment of its operating frequency, it is necessary to ensure the matching of the filter with the resistances of the signal source and load. When ω ₀ changes, the value of the nominal characteristic resistance Z _m changes proportionally, which usually leads to a mismatch of the filter at the input and output. This mismatch leads to an increase in the unevenness of the frequency response and a decrease in the transmission coefficient.

It can be shown that the input impedance of the symmetric filter W, expressed through its characteristic parameters — the characteristic impedance Z _c and the transmission constant q _c , will be determined by the relation [3]:

Here α is the characteristic phase of the filter,

R ₂ - load resistance at the output of the filter.

Expression (3) is valid for the characteristic bandwidth of the symmetric filter when q _c = jα and the characteristic attenuation is zero.

After calculating the real and imaginary components of the input resistance, we get:

It can be seen from formula (4) that for α = π (this corresponds to the initial filter, see Fig. 2 and Fig. 4 at the frequency ω = ω _c ) ImW (ω ₂ ) = 0, ReW (ω ₂ ) = R ₂ .

It follows that at the middle frequency, regardless of the value of Z _c , the necessary matching of the filter at the input and output is provided at constant loads during tuning and the maximum transmission coefficient is maintained.

Thus, the proposed device allows for the same number of keys and fewer inductors in comparison with the prototype to implement a discrete tunable band-pass filter with improved transmission coefficient at the operating frequency.

Information sources

1. Barefoot N.D. Electric filters. Gostekhizdat of the Ukrainian SSR, Kiev, 1959, p. 168.

2. Gillemin E.A. Synthesis of passive circuits. Ed. “Communication” M. 1970, p. 170.

3. Beletsky A.F. Theoretical Foundations of Conductive Communication, Part III. Ed. “Communication”, M. 1959, p. 34, 35.

Claims (1)

Tunable band-pass LC filter, consisting of an input band-pass filter containing a first inductor, the first output of which is connected to the input potential terminal of the filter, its second output is connected to the first capacitor and second inductor, the second conclusions of the second inductor and first capacitor are connected to a common bus, and an output bandpass filter containing a third inductor, the first output of which is connected to the output potential terminal of the filter, and its second output is connected to about the second capacitor and the fourth inductor, the second terminals of the second capacitor and the fourth inductor connected to a common bus, characterized in that the device additionally introduced the first signal bus connected to the second output of the first inductor, and the second signal bus connected to the second output of the third inductor, in addition, N sections identical in structure are introduced into the device, each of which contains a third, fourth and fifth capacitor, as well as input and output th electronic keys, while the third capacitor is connected by the first output to the first output of the fourth capacitor and simultaneously to the first output of the input electronic key, the second output of which is connected to the first signal bus, the second output of the fourth capacitor is connected to the first output of the fifth capacitor and simultaneously to the first output output an electronic key, the second terminal of which is connected to the second signal bus, while the second terminals of the third and fifth capacitors are connected to a common bus.

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