RU2722752C1 - Band-pass filter with independent adjustment of pole frequency, pole attenuation and transmission coefficient - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to means used as an interface for selecting a predetermined spectrum of a signal source, for example, during its further processing by analog-to-digital converters of various modifications. Filter comprises first (3) and second (4) differential operational amplifiers, first (5) and second (6) series-connected resistors connected between device input (1) and output of second (4) differential operational amplifier, common node of which is connected to inverting input of second (4) differential operational amplifier. Output of second (4) differential operational amplifier is connected to inverting input of first (3) differential operational amplifier through in-series connected first (14) capacitor and fourth (9) resistor, output of first (3) differential operational amplifier is connected to non-inverting input of first (3) differential operational amplifier through series-connected sixth (11) and seventh (12) resistors, common node of which is connected to common unit of in-series connected first (14) capacitor and fourth (9) resistor through fifth (10) resistor, output (2) of the device is connected to inverting input of first (3) differential operational amplifier through second (15) capacitor and is connected to inverting input of second (4) differential operational amplifier through third (8) resistor.

EFFECT: technical result consists in providing band-pass filter circuit with lower parametric sensitivity with independent adjustment of three main parameters of AFC – frequency of pole (ωs), pole attenuation (ds), as well as transmission coefficient in pass band (M).

1 cl, 5 dwg

Description

The invention relates to radio engineering and can be used as an interface for highlighting a given spectrum of a signal source, for example, during its further processing by analog-to-digital converters of various modifications.

Bandpass ARC filters (PF) are among the fairly common analog devices that determine the quality indicators of many radio systems, including for digital signal processing [1-28]. In this class of devices, filters with an independent adjustment of the main parameters occupy a special place [29-33].

The closest prototype of the claimed device is a band-pass filter according to patent RU 2694134, FIG. 2, 2019. It contains (Fig. 1) input 1 and output 2 of the device, the first 3 and second 4 differential operational amplifiers, the first 5 and second 6 series-connected resistors connected between the input 1 of the device and the output of the second 4 differential operational amplifier, the common node of which is connected to the inverting input of the second 4 differential operational amplifier, the non-inverting input of which is connected to the common bus of power supplies 7, third 8, fourth 9, fifth 10, sixth 11, seventh 12, eighth 13 resistors, first 14 and second 15 capacitors, moreover, the eighth 13 resistor is connected between the non-inverting input of the first 3 differential operational amplifier and the common bus of power supplies 7, and the output of the first 3 differential operational amplifier is connected to the output 2 of the device.

A significant disadvantage of the bandpass prototype filter of FIG. 1 is that it does not provide low parametric sensitivity when setting the quality factor.

The main objective of the proposed invention is to create a bandpass filter circuit with lower parametric sensitivity with independent adjustment of the three main parameters of the frequency response - pole frequency (ωs), pole attenuation (ds), and transmission coefficient in the passband (M).

The problem is achieved in that in the band-pass filter of FIG. 2, containing input 1 and output 2 of the device, the first 3 and second 4 differential operational amplifiers, the first 5 and second 6 series-connected resistors connected between the input 1 of the device and the output of the second 4 differential operational amplifier, the common node of which is connected to the inverting input of the second 4 differential operational amplifier, the non-inverting input of which is connected to a common bus of power supplies 7, third 8, fourth 9, fifth 10, sixth 11, seventh 12, eighth 13 resistors, the first 14 and second 15 capacitors, and the eighth 13 resistor is connected between the non-inverting input of the first 3 differential operational amplifier and a common bus of power supplies 7, and the output of the first 3 differential operational amplifier is connected to the output 2 of the device, new communications are provided - the output of the second 4 differential operational amplifier is connected to the inverting input of the first 3 differential operational amplifier through series-connected the first 14 capacitor and the fourth 9 resistor, the output of the first 3 differential operational amplifier is connected to the non-inverting input of the first 3 differential operational amplifier through series-connected sixth 11 and seventh 12 resistors, the common node of which is connected to the common node of the first 14 capacitor and fourth 9 resistor connected in series through the fifth 10 resistor, the output 2 of the device is connected to the inverting input of the first 3 differential operational amplifier through the second 15 capacitor and is connected to the inverting input of the second 4 differential operational amplifier through the third 8 resistor.

In the drawing of FIG. 1 shows a diagram of a PF prototype.

In the drawing of FIG. 2 shows a diagram of the claimed PF in accordance with the claims.

In the drawing of FIG. 3 shows graphs of changes in the amplitude-frequency (AFC) and phase-frequency (PFC) characteristics of the PF of FIG. 3 when setting the pole frequency in series with resistors R11 and R12.

In the drawing of FIG. 4 shows the frequency response and phase response of the PF circuit of FIG. 2 when adjusting the pole attenuation (ds) using resistors R6, R8, R13.

In the drawing of FIG. 5 shows graphs of changes in frequency response and phase response of the PF circuit of FIG. 2 when adjusting the gear ratio (M) using resistor R5.

The band-pass filter with independent tuning of the pole frequency, pole attenuation and transmission coefficient of FIG. 2 contains input 1 and output 2 of the device, the first 3 and second 4 differential operational amplifiers, the first 5 and second 6 series-connected resistors connected between the input 1 of the device and the output of the second 4 differential operational amplifier, the common node of which is connected to the inverting input of the second 4 differential an operational amplifier whose non-inverting input is connected to a common bus of power supplies 7, third 8, fourth 9, fifth 10, sixth 11, seventh 12, eighth 13 resistors, first 14 and second 15 capacitors, and the eighth 13 resistor is connected between the non-inverting input of the first 3 differential operational amplifier and a common bus power sources 7, and the output of the first 3 differential operational amplifier is connected to the output 2 of the device. The output of the second 4 differential operational amplifier is connected to the inverting input of the first 3 differential operational amplifier through a series-connected first 14 capacitor and fourth 9 resistor, the output of the first 3 differential operational amplifier is connected to the non-inverting input of the first 3 differential operational amplifier through series-connected sixth 11 and seventh 12 resistors the common node of which is connected to the common node of the first 14 capacitors and the fourth 9 resistors connected in series through the fifth 10 resistor, the output 2 of the device is connected to the inverting input of the first 3 differential operational amplifier through the second 15 capacitor and connected to the inverting input of the second 4 differential operational amplifier through the third 8 resistor.

Consider the operation of the PF of FIG. 2.

Scheme properties of a classic second-order bandpass filter, including the circuit of FIG. 2 are determined by its transfer function

where M is the transmission coefficient of the filter at the center frequency; ω _p is the frequency of the pole; d _p is the pole attenuation.

The transfer function coefficients of the proposed PF scheme are determined by the expressions:

- gear ratio

,

,

,

Where

,

- pole frequency

- pole attenuation

Independent adjustment of the PF parameters of FIG. 2 is possible when, when configuring the next parameter of the circuit, it is not necessary to change the resistance of the resistors that determine the already configured parameter. From the analysis of the obtained formulas for ω _p , d _p , M it follows that in the proposed PF of FIG. 2, such a setting is possible in the following sequence:

First step: adjust the frequency of the pole ω_s by changing the resistances of the sixth 11 and seventh 12 resistors (R11 and R12). Further, the values of these resistors are fixed.

Second stage: damping of the pole d is adjusted_s by changing the resistances of the resistors of the second 6 (R6), third 8 (R8) and eighth 13 (R13) resistors. In the second stage of the resistance of the sixth 11 and seventh 12 resistors (R11 and R12) are not changed.

Third stage: the transmission coefficient M is adjusted by changing the resistance of the first 5 resistor (R5). At this stage, the resistance of the second 6 (R6), third 8 (R8), sixth 11 (R11), seventh 12 (R12), eighth 13 (R13) resistors are not changed.

It should be noted that other known PF circuits with low parametric sensitivity, performed on two operational amplifiers, do not possess this property.

The effectiveness of the above PF tuning algorithm of FIG. 2, are confirmed by the results of computer simulation (Fig. 3-Fig. 5).

In view of the phase response of FIG. 3 we can judge that the frequency of the pole ω_s, at which the phase shift is 0 °, changes due to the sixth 11 and seventh 12 resistors (R11 and R12) over a relatively wide range.

In view of the phase response of FIG. 4, it can be established that when the resistances of the second 6, third 8, eighth 13 resistors (R6, R8, R13) change, the slope of the frequency response in the frequency region of the pole changes, as well as the rise in frequency response at this frequency. In this case, the frequency of the pole remains unchanged (ω _s = const). When setting the pole attenuation, the frequencies change at which the phase shift is -45 ° and 45 °.

When adjusting the transmission coefficient by changing the first 5 (R5) resistor, the phase response does not change, but only the overall level of the frequency response changes (Fig. 5).

When designing filters based on the considered circuit, the resistance of the fifth 10 resistor (R10) is desirable to choose much more than the equivalent resistance of the resistive voltage divider, consisting of the sixth 11 and seventh 12 resistors (R11 and R12), that is, the ratio

Compared with the known PF, the claimed PF scheme has a lower parametric sensitivity when setting equal Q factors.

Thus, the proposed device has significant advantages in comparison with the prototype.

BIBLIOGRAPHIC LIST

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Claims (1)

A band-pass filter with independent adjustment of the pole frequency, pole attenuation and transmission coefficient, containing the input (1) and output (2) of the device, the first (3) and second (4) differential operational amplifiers, the first (5) and second (6) series-connected resistors connected between the input (1) of the device and the output of the second (4) differential operational amplifier, the common node of which is connected to the inverting input of the second (4) differential operational amplifier, the non-inverting input of which is connected to the common bus of power supplies (7), the third (8 ), the fourth (9), fifth (10), sixth (11), seventh (12), eighth (13) resistors, the first (14) and second (15) capacitors, and the eighth (13) resistor is connected between the non-inverting input of the first (3) a differential operational amplifier and a common bus of power sources (7), and the output of the first (3) differential operational amplifier is connected to the output (2) of the device, characterized in that the output of the second (4) differential an operational amplifier is connected to the inverting input of the first (3) differential operational amplifier through a first (14) capacitor and a fourth (9) resistor connected in series, the output of the first (3) differential operational amplifier is connected to a non-inverting input of the first (3) differential operational amplifier through a series-connected the sixth (11) and seventh (12) resistors, the common node of which is connected to the common node of the first (14) capacitor and the fourth 9 resistor connected in series through the fifth (10) resistor, the output (2) of the device is connected to the inverting input of the first (3) differential operational amplifier through the second (15) capacitor and is connected to the inverting input of the second (4) differential operational amplifier through the third (8) resistor.

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