RU168664U1 - BANDFILTER LC FILTER SUPPRESSED WITH FOCUSED INTERFERENCE IN THE FREQUENCY WORKBAND - Google Patents

Abstract

The proposed utility model relates to electronics and can be used as an input device of a professional radio receiver. The objective of the utility model is to improve the operational parameters of the device, expand its functionality to compensate for the level of concentrated interference during operation of the RPU. LC bandpass filter, consisting of two filters on, the input of the first of them is the input of the device, the output of the second is the output of the device, while the first fi the liter contains a first capacitor connected to the input of the filter, the second terminal of this capacitor is connected to the first terminals of the second capacitor and the first inductor, the second terminal of which is connected to the second inductor and the third capacitor, the second terminal of which is connected to the fourth capacitor and the output of the first filter, the second terminals of the second inductor, the second and fourth capacitors are connected to a common bus, a second band-pass filter is connected to the output of the first filter, containing e to its input are the fifth and sixth capacitors, the second terminal of the sixth capacitor is connected to the third and fourth inductors, the second terminal of the fourth inductor is connected to the first terminals of the seventh and eighth capacitors, the second terminals of the third inductor, fifth and seventh capacitors are connected to a common bus, the second output of the eighth capacitor is connected to the output of the second filter, in addition, one or more additional inductors are connected to the output of the first filter, to the second output to zhdoy of

Description

The proposed utility model relates to radio electronics and can be used as an input device of a professional radio receiver.

In some cases, one or more bandpass LC filters with an overlap factor of 1.5–3 are used as preselectors, dividing the entire operating frequency range into several subbands. As a prototype, we selected a strip LC circuit consisting of two cascade-switched and matched filters, as the closest in technical essence to the proposed solution.

The disadvantage of the prototype is that the interference located in the passband of this filter can have a high level and thereby degrade the processing of the received signal.

The objective of the utility model is to improve the operational parameters of the device, expand its functional capabilities, allowing to compensate for the level of concentrated interference during operation of the RPU.

The problem is solved in that in a device containing two matched bandpass filters, the input of the first one is the input of the device, the output of the second is the output of the device, the first filter contains the first capacitor connected to the input of the filter, the second output of this capacitor is connected to the first outputs of the second the capacitor and the first inductor, the second output of which is connected to the second inductor and the third capacitor, the second output of which is connected to the fourth capacitor and the output the first filter, the second terminals of the second inductor, the second and fourth capacitors are connected to a common bus, the second filter is connected to the output of the first filter, containing the fifth and sixth capacitors connected to its input, the second output of the sixth capacitor is connected to the third and fourth inductors, the second the output of the fourth inductor is connected to the first terminals of the seventh and eighth capacitors, the second terminals of the third inductor, the fifth and seventh capacitors are connected to a common otherwise, a second terminal of the eighth capacitor connected to the output of the second filter, in addition to the output of the first filter connected to one or more additional inductors, to the second terminal of each of the inductors is connected variable capacitor, the second terminals of the variable capacitors connected to the common bus.

Comparative analysis shows that the claimed utility model differs from the prototype in that the first filter contains a first capacitor connected to the input of the filter, the second output of this capacitor is connected to the first terminals of the second capacitor and the first inductor, the second output of which is connected to the second inductor and the third capacitor, the second terminal of which is connected to the fourth capacitor and the output of the first filter, the second terminals of the second inductor, the second and fourth capacitor The s are connected to a common bus, the second filter is connected to the output of the first filter, containing the fifth and sixth capacitors connected to its input, the second terminal of the sixth capacitor is connected to the third and fourth inductors, the second terminal of the fourth inductor is connected to the first terminals of the seventh and eighth capacitors , the second terminals of the third inductor, the fifth and seventh capacitors are connected to a common bus, the second terminal of the eighth capacitor is connected to the output of the second filter, in addition to During the first filter, one or more additional inductors are connected, a variable capacitor is connected to the second terminal of each of these inductors, and the second terminals of the variable capacitors are connected to a common bus.

When comparing the claimed utility model not only with the prototype, but also with other technical solutions in science and technology, no solutions were found that have similar characteristics.

In FIG. 1 shows an electrical diagram of a utility model.

The device contains the first 1 and second 2 bandpass filters. The first filter contains a first capacitor 3, the second output of which is connected to the second capacitor 4 and the first inductor 5, the second output of which is connected to the second inductor 6 and the third capacitor 7. The second output of the capacitor 7 is connected to the output of the first filter and the fourth capacitor 8. The second the findings of capacitors 4 and 8 and inductors 6 are connected to a common bus.

The second bandpass filter 2 contains a fifth 9 and a sixth 10 capacitors connected to the input of the filter. The second terminal of the capacitor 10 is connected to the third 11 and the fourth 12 inductors, the second terminal of the inductor 12 is connected to the seventh 13 and eighth 14 capacitors. The second output of the capacitor 14 is connected to the output of the second filter, the second outputs of the capacitors 9 and 13 and the inductor 11 are connected to a common bus. One or more inductance coils 15 are connected to the output of the first filter, variable capacitors 16 are connected to the second terminals of each of these inductors, the second terminals of which are connected to a common bus.

The device operates as follows.

The first filter has a lower output resistance compared to the input, the second, on the contrary, has a small input and a higher output. Between them, a series circuit is switched on, which shunts the band circuit at the frequency of the series resonance, forming a notch band. When changing the capacitance of a variable capacitor, the notch circuit can be tuned to the interference frequency and reduce its level. If necessary, you can enable additional sequential notch circuits, and thereby provide a rejection of several interference, or to provide greater suppression of one of them. The attenuation level in the notch band is greater, the higher the quality factor of successive notch contours. At the same time, when detuning from the frequency of the notch, the unevenness of the amplitude-frequency characteristic (AFC) of the strip chain worsens.

The frequency band near the notch frequency can be quite large, which leads to a decrease in the amplitude of the processed signal. To reduce this frequency band, it is necessary to increase the inductance of the series notch circuit, because in this case, the modulus of its reactance increases and its shunting effect on the strip circuit decreases.

For structural and technological reasons, the increase in the inductance of the serial circuits is significantly limited. Therefore, it is necessary to reduce the input resistance of the strip circuit at the connection point of the notch circuits, increasing the ratio of its resistance to the resistance of the strip circuit. This function is performed by the first and second filters, ensuring coordination of the load resistances at the input and output of the device with a lower resistance at the point of connection of the notch circuits.

, а после пары индуктивностей L₁ и L₂ второго звена введен идеальный трансформатор с коэффициентом трансформации

. После дальнейших преобразований по Нортону [2] получаем схему, приведенную на фиг. 1.Each of the bandpass filters shown in FIG. 1 is a second class attenuation filter obtained as shown in FIG. 2, by cascading two antimetric filters, in which, after the first pair of capacitors C ₁ and C ₂ , an ideal transformer with a transformation coefficient is introduced

and after a pair of inductances L ₁ and L _{2 of the} second link, an ideal transformer with a transformation coefficient is introduced

. After further transformations according to Norton [2], we obtain the circuit shown in FIG. one.

This filter allows you to implement a strip transformer, the output impedance of which R ₂ is determined by the ratio

Note that this circuit provides the widest operating frequency band at a given transformation ratio compared to other bandpass filters containing the same number of inductors, acting simultaneously as a subband bandpass filter.

Elements of the original antimetric strip chain are calculated using the formulas

,

,

where Z _m1 - input nominal characteristic impedance of the filter;

ω ₁ , ω ₂ are the frequencies of the lower and upper edges of the passband.

Thus, in the presented solution, the first and second filters form a band-pass filter, providing the necessary transformation of resistances in the working frequency band, and connected serial circuits provide frequency-tunable notch bands.

In FIG. 3 shows the calculated amplitude-frequency characteristic of a tunable notch filter, made according to the scheme of FIG. 1 with one serial circuit operating in the frequency range from 15 to 30 MHz.

Information sources:

1. Barefoot N.D. Electric filters. State Publishing House., Kiev, 1957.

2. Cerne H.I. Inductive coupling and transformations in electric filters. Svyazizdat, M., 1962.

Claims (1)

A band-pass LC filter consisting of two matched filters, the input of the first one is the input of the device, the output of the second one is the output of the device, characterized in that the first filter contains the first capacitor connected to the input of the filter, the second output of this capacitor is connected to the first outputs of the second a capacitor and a first inductor, the second terminal of which is connected to the second inductor and the third capacitor, the second terminal of which is connected to the fourth capacitor and the output of the first filter, The other conclusions of the second inductor, the second and fourth capacitors are connected to a common bus, the second filter is connected to the output of the first filter, containing the fifth and sixth capacitors connected to its input, the second output of the sixth capacitor is connected to the third and fourth inductors, the second output of the fourth coil the inductance is connected to the first terminals of the seventh and eighth capacitors, the second terminals of the third inductance coil, the fifth and seventh capacitors are connected to a common bus, the second terminal d eighth capacitor connected to the output of the second filter, in addition to the output of the first filter connected to one or more additional inductors, to the second terminal of each of the inductors is connected variable capacitor, the second terminals of the variable capacitance capacitors connected to a common bus.

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