RU2453985C1 - Highly selective band-pass tuneable lc filter - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: invention relates to radio electronics. The highly selective band-pass tuneable LC filter has: two structurally identical band-pass circuits, each having a first, second, third, fourth, fifth, sixth, seventh and eighth inductance coil, a first, second and third capacitor, a common bus, an amplifier, an input potential terminal for the device, an output potential terminal for the device, four signal buses, the filter also has N structurally identical sections of a first group, each having a first electronic switch, M structurally identical sections of a second group, each having a third electronic switch.

EFFECT: high bandwidth ratio of the filter attenuation characteristic, higher level of attenuation in the attenuation band while maintaining low variation in frequency response in the pass band, high transfer constant and manufacturability of the device.

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Description

The proposed device relates to electronics and can be used as selectors of transmitting and receiving professional devices.

For frequency separation of signals in transmitting and receiving equipment, in some cases, band-pass discrete tunable LC filters are used.

A number of band-pass LC filters are known in which discrete variable capacitors (DKPE) are used to tune their average frequency, while the inductive elements of the filter remain unchanged.

There are a fairly large number of bandpass filter circuits used for this purpose, while each of the original circuits has a number of differences that most fully satisfy the set of requirements for the filter in each particular embodiment of the transmitting and receiving equipment.

In our case, when it is necessary to perform a tunable filter with attenuation in the retention band of more than 40 dB with a squareness factor of not more than 3 and a relative passband of 2-5%, the most acceptable is a circuit consisting of the first inductor, the first output of which is the input of the filter, its second terminal is connected to the first capacitor, the second terminal of which is connected to the second and third capacitors, the second terminal of the second capacitor is connected to a common bus, the second terminal of the third capacitor is connected with a second inductor, the second output of which is the output of this circuit [1]. This filter is selected as a prototype. Since three capacitors of this circuit can be used as DKPE using the smallest possible number of electronic keys, and two cascade-connected links of this circuit form a second-class filter by attenuation, which allows the filter to be tuned in frequency over a wider range (compared to odd-class filters attenuation), while maintaining the input impedance at a constant load, this filter is convenient for implementing a tunable circuit. However, this filter does not have a sufficiently high coefficient of squareness and, when relative bandwidths of 4 ÷ 5% and more are realized, do not fulfill the requirements for attenuation at a ten percent frequency offset.

The objective of the invention is to increase the squareness coefficient of the filter attenuation characteristics, increase the attenuation level in the delay band while maintaining a small unevenness of the frequency response in the pass band, high transmission coefficient and manufacturability of its manufacture.

The problem is solved by introducing into the well-known circuit a filter consisting of two identical in structure of the strip circuits, each of which contains the first inductor, the first output of which is the input of the strip circuit, its second output is connected to the first capacitor, the second output of which is connected to the second and by the third capacitors, the second terminal of the second capacitor is connected to a common bus, the second terminal of the third capacitor is connected to the second inductor, the second terminal of which is the output of this a strip circuit, additionally a third inductor connected to the first terminal of the first inductor and a fourth inductor connected to the second terminal of the second inductor, the second terminals of the third and fourth inductors are connected to a common bus, an amplifier is additionally introduced into the device circuit, while the input the amplifier through the fifth inductor is connected to the output of the first strip circuit, the output of the amplifier through the sixth inductor is connected to the input of the second strip pi, the input of the first strip circuit through the seventh inductor is connected to the input potential terminal of the device, the output of the second strip circuit through the eighth inductor is connected to the output potential terminal of the device, in addition, four signal buses are added to the device, the first of which is connected to the second output the first inductance coil of the first strip circuit, the second bus is connected to the first terminal of the second inductance coil of the first strip circuit, the third bus is connected to the second pin an ode of the first inductance coil of the second strip circuit, the fourth bus is connected to the first terminal of the second inductance coil of the second strip circuit, the device contains N identical in structure sections of the first group, each of which contains a first electronic key, the first terminal of which is connected to the first signal bus, to the second the fourth electronic capacitor is connected to the output of the first electronic key, the second output of which is connected to the fifth and sixth capacitors, the second output of the fifth capacitor is connected to the common bus, the second pin the sixth capacitor is connected to the second electronic key, the second output of which is connected to the second signal bus, and also contains M sections of the second group identical in structure, each of which contains the third electronic key, the first output of which is connected to the third signal bus, its second output is connected to the seventh capacitor, the second terminal of which is connected to the eighth and ninth capacitors, the second terminal of the eighth capacitor is connected to a common bus, the second terminal of the ninth capacitor is connected to the fourth key, the second terminal of which is connected to the fourth signal line.

Comparative analysis shows that the claimed technical solution differs from the prototype in that the third inductor is connected to the first output of the first inductor, the fourth inductor is connected to the second output of the second inductor, the second conclusions of the third and fourth inductors are connected to a common bus, in the circuit of the device, an amplifier is additionally introduced, while the input of the amplifier through the fifth inductor is connected to the output of the first strip circuit, the output of the amplifier through a clean inductor is connected to the input of the second strip circuit, the input of the first strip circuit through the seventh inductor is connected to the input potential terminal of the device, the output of the second strip circuit through the eighth inductor is connected to the output potential terminal of the device, in addition, four signal buses are additionally introduced into the device the first of which is connected to the second terminal of the first inductor of the first strip circuit, the second bus is connected to the first terminal of the second inductor In particular, the first strip circuit, the third bus is connected to the second terminal of the first inductance coil of the second strip circuit, the fourth bus is connected to the first terminal of the second inductor of the second strip circuit, the device contains N sections of the first group that are identical in structure, each of which contains the first electronic key, the first the output of which is connected to the first signal bus, the fourth capacitor is connected to the second output of the first electronic key, the second output of which is connected to the fifth and sixth capacitors, in The second terminal of the fifth capacitor is connected to a common bus, the second terminal of the sixth capacitor is connected to a second electronic key, the second terminal of which is connected to the second signal bus, and also contains M sections of the second group identical in structure, each of which contains a third electronic key, the first terminal of which connected to the third signal bus, its second output is connected to the seventh capacitor, the second output of which is connected to the eighth and ninth capacitors, the second output of the eighth capacitor is connected to the common bus, the second terminal of the ninth capacitor is connected to the fourth electronic key, the second terminal of which is connected to the fourth signal bus.

When comparing the proposed solution not only with the prototype, but also with other technical solutions known in science and technology, solutions with similar features were not found.

The figure shows the electrical circuit of the proposed device. The device consists of two identical in structure of the strip circuits 1 and 2, each of which contains the first inductance 3, the first terminal of which is the input of the strip circuit, the first capacitor 4 is connected to the second terminal of this inductor, the second capacitor 5 is connected to the second terminal of the first capacitor, the second terminal of which is connected to the common bus, and the third capacitor 6, the second terminal of which is connected to the second inductor 7, the second terminal of which is the output of this strip circuit. A third inductor 8 is connected to the first terminal of the first inductor, a fourth inductor 9 is connected to the second terminal of the second inductor 9, and second terminals of the third and fourth inductors are connected to a common bus. The device also contains an amplifier 10, the input of which through the fifth inductor 11 is connected to the output of the first strip circuit, and its output through the sixth inductor 12 is connected to the input of the second strip circuit, the input of the first strip circuit through the seventh inductor 13 is connected to the input potential terminal of the device , the output of the second strip circuit through the eighth inductor 14 is connected to the output potential terminal of the filter. In addition, the device contains four signal buses, the first connected to the second terminal of the first inductance coil of the first strip circuit, the second connected to the first terminal of the second inductor of the first strip circuit, the third connected to the second terminal of the first inductance of the second strip circuit, the fourth connected to the first output of the second inductance of the second strip circuit. In addition, the device contains N identical in structure sections of the first group 15, each of which contains a first electronic key 16, the first output of which is connected to the first signal bus, the fourth capacitor 17 is connected to its second output, the fifth capacitor 18 is connected to the second output of the second the output of which is connected to the common bus, and the sixth capacitor 19, the second output of which is connected to the second electronic key 20, the second output of which is connected to the second signal bus. The device also contains M sections of the second group 21, identical in structure, each of which consists of a second electronic key 22, the first terminal of which is connected to the third signal bus, its second terminal is connected to the seventh capacitor 23, and the eighth capacitor 24 is connected to the second terminal of the second the output of which is connected to a common bus, and the ninth capacitor 25, to the second output of which a fourth electronic key 26 is connected, the second output of which is connected to the fourth signal bus.

The device operates as follows.

The first band-pass circuit 1 is a known band-pass filter circuit of the first class for attenuation and the second class for characteristic impedance [1]. Connecting inductors 8 and 13 at the input of this filter, as well as inductors 9 and 11 at the output, convert this circuit into a filter of the second class for attenuation and the first class for characteristic resistance. In the case when the inductances 3 and 7, 8 and 9, 11 and 13 are equal in pairs and the capacitances of the capacitors 4 and 6 are the same, the filter circuit will be symmetrical and its input impedance in accordance with the data given in [2], will be determined by the following relation

, где

where

W is the input impedance of a symmetric filter,

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

Z _with - characteristic resistance of the filter,

α is the characteristic phase of the filter.

From this relation it follows that

,

,

and, therefore, at the average frequency ω ₀ , when for filters of an even damping class α = π, ReW (ω ₀ ) = R ₂ .

That is, at a frequency ω _{0, the} input filter resistance does not depend on the characteristic resistance Z _c , and is equal to the load resistance R ₂ , and when the filter is tuned by a corresponding change in the capacitance of the capacitors, it remains constant (at R ₂ = const), regardless of Z _c during adjustment changes in proportion to the change in ω ₀ .

This property of the bandpass filter allows the filter to be tuned over a sufficiently wide range, keeping the relative bandwidth, insertion attenuation, and squareness coefficient of the amplitude-frequency characteristic (AFC) almost unchanged. For filters of the second class according to attenuation during the tuning of the operating frequency “up”, the frequency response unevenness in the passband changes slightly (0.2–0.3 dB with an overlap factor of 3–4). When choosing a higher damping class, equal, for example, to the fourth, the characteristic phase of the filter α when tuning from ω ₀ to the edges of the passband changes twice as fast, which leads to the appearance of frequency response unevenness equal to 2 ÷ 3 dB. In this regard, the introduction of an additional amplifier between the two tunable filters provides the necessary isolation between them and allows you to get the best total frequency response unevenness. The attenuation of both filters in the delay band is added.

Two groups of sections, consisting of capacitors 17, 18 and 19, as well as 23, 24 and 25, serve to change the average frequency of the filter. Initially, when all keys are open, the filter is tuned to the upper operating frequency. Connecting one (or several) sections of the first group to capacitors 4, 5, 6 increases their capacitance and leads to a decrease in ω _{0 of the} first strip circuit. Similarly, the second group of sections works in conjunction with capacitors 4, 5, 6 of the second strip circuit. The keys of the first and second groups are included by command from a common control device.

It should be noted that with the proposed option for constructing a tunable bandpass filter, each of the filters included before and after the amplifier has a sufficiently high isolation between them, which virtually eliminates the influence of their input resistances on each other. This allows you to rebuild each of these filters over a wider range, reduce the requirements for the coefficient of squareness for each of them. In this case, the amplifier turns out to be protected by the input of the first filter, as a result of which the level of third-order intermodulation components in the frequency range located in the delay band decreases. The output circuit reduces the noise level at the output of the amplifier at frequencies outside the passband.

The introduction of inductors 8, 13, and 9, 11 at the input and output of the strip circuits, in addition to increasing the filter class for attenuation, together with inductors 3 and 7, allows matching the filter with the loads at the input and output and at the same time obtain the most suitable capacitance values for capacitors 4, 5 , 6 and capacitors included in the DKPE section.

An analysis of this tunable filter circuit using modern modeling methods showed that the influence of losses in coils 8, 9, 11, 13 can almost be neglected (in the KB range, their quality factor can be 20-30 units, without practically affecting the filter frequency response), to the coils Inductors 3, 7 need to make higher demands. With the quality factors of these inductors 150-200 units. it is possible to provide insertion attenuation in the passband of not more than 3 dB in the tuning range, with an overlap factor of 3.

Reducing the influence of losses introduced by electronic keys is achieved in each case by the appropriate choice of the maximum capacitance values of capacitors 17, 20 of the DKPE section, and the total stray capacitance of electronic keys is taken into account by a corresponding recount of capacitors 4, 5, 6.

Information sources

1. Cerne H.I. Inductive coupling and transformations in electric filters. Svyazizdat, Moscow, 1962, p. 206, Table 5.1.

2. Yakovlev A.N., Yasinsky I.M. Analysis of input impedances of electric filters. Radio engineering. Vol. 14, 2009.

Claims (1)

A tunable band-pass LC filter containing two identical strip structures in structure, each of which contains a first inductor, the first output of which is the input of the strip circuit, its second output is connected to the first capacitor, the second output of which is connected to the second and third capacitors, the second output the second capacitor is connected to a common bus, the second terminal of the third capacitor is connected to the second inductor, the second terminal of which is the output of this strip circuit, characterized in that to a third inductor is connected to the first output of the first inductor, a fourth inductor is connected to the second output of the second inductor, the second outputs of the third and fourth inductors are connected to a common bus, an amplifier is additionally introduced into the device circuit, while the amplifier input is connected to the fifth inductor the output of the first strip circuit, the output of the amplifier through the sixth inductor connected to the input of the second strip circuit, the input of the first strip circuit through gray the inductance coil is connected to the input potential terminal of the device, the output of the second strip circuit through the eighth inductance coil is connected to the output potential terminal of the device, in addition, four signal buses are added to the device, the first of which is connected to the second terminal of the first inductor of the first strip circuit, the second bus is connected to the first terminal of the second inductance coil of the first strip circuit, the third bus is connected to the second terminal of the first inductance coil of the second a strip circuit, the fourth bus is connected to the first terminal of the second inductance coil of the second strip circuit, the device contains N identical in structure sections of the first group, each of which contains a first electronic key, the first terminal of which is connected to the first signal bus, connected to the second terminal of the first electronic key the fourth capacitor, the second terminal of which is connected to the fifth and sixth capacitors, the second terminal of the fifth capacitor is connected to a common bus, the second terminal of the sixth capacitor is connected to the second an electronic key, the second output of which is connected to the second signal bus, and also contains M sections of the second group identical in structure, each of which contains a third electronic key, the first output of which is connected to the third signal bus, its second output is connected to the seventh capacitor, the second output which is connected to the eighth and ninth capacitors, the second terminal of the eighth capacitor is connected to a common bus, the second terminal of the ninth capacitor is connected to the fourth electronic key, the second terminal of which is connected to the fourth signal bus.