RU200408U1 - Bandpass filter with tunable frequency range for continuous spectral analysis of cardiointervalogram - Google Patents

Abstract

The utility model relates to analog low-pass filtering circuits and, more specifically, to a broadband active RC filter. The proposed tunable bandpass filter of the 4th order Butterworth type can be used in devices for diagnosing the human cardiovascular system, providing the ability to assess the state of the cardiovascular system based on analysis spectral power of the cardiointervalogram, as well as in biofeedback systems that use the current values of this power to generate feedback signals. The filter consists of a series-connected active low-pass and high-pass filters of the second order. Simultaneous tuning of the low and high cutoff frequencies of the band-pass filter is provided, i.e. bandwidth, and tuning the center frequency while maintaining a constant bandwidth using a single dual (synchronously variable) potentiometer. The choice of the operating mode of the bandpass filter is carried out using a double switch of the potentiometer outputs to control the cutoff frequency of one of them (HPF or LPF). Tuning the cutoff frequency within a decade does not affect the quality factor of the filters.

Description

The utility model relates to analog frequency filtering circuits, and more specifically to bandpass filter circuits with center frequency and bandwidth tuning.

The proposed tunable bandpass filter (PF) can be used in devices for diagnostics of the human cardiovascular system, which provide the ability to assess the state of various levels of regulation of the cardiovascular system. This is carried out on the basis of analysis and assessment of the spectral power of the cardiointervalogram (RIT) in various frequency ranges. The current values of the spectral power of the cardiointervalogram are also used in biofeedback systems, where a biological feedback signal is generated from them (Poskotinova L.V., Semenov Yu.N. Patent RU 2317771 dated 04/03/2006; Suvorov N.B .; Yarmosh I.V. ., Sergeev T.V., Belov A.V., Agapova E.A. Patent RU 2655883 dated 05/29/2018; Yabluchansky N.I., Martynenko A.V .. Heart rate variability. To help a practitioner. Kharkov, 2010, 131 s).

In such systems, it is especially important to determine the spectral power of individual components of frequency ranges in real time. The values of the frequency ranges used in the analysis of heart rate variability (HRV) and their physiological interpretation in the regulation of the cardiovascular system are presented in the table.

The use of continuous spectral analysis based on the frequency filtering of the cardiointervalogram makes it possible to quantitatively evaluate the frequency components of the heart rate oscillations, which, in turn, makes it possible to carry out biocontrol according to the amplitudes of the frequency components of the heart rate associated with the activity of certain links of the regulatory mechanism of the cardiovascular system.

In medical practice, when conducting spectral studies in the region of low and infra-low frequencies, band-pass filters in the range from hundredths to units of Hertz are required. In this case, it is necessary to ensure that they can be tuned both by the center frequency while maintaining the bandwidth, and the bandwidth while maintaining a constant center frequency.

Known RC filters LPF and HPF of the second order with fixed parameters of the cutoff frequency and Q-factor, in which for tuning the cutoff frequency it is required to simultaneously vary two or more frequency-dependent resistors or capacitors. Since the restructuring of the cutoff frequency by changing the nominal capacitance in the region of low and infra-low frequencies seems impossible, it is really possible to ensure the restructuring of the frequency of the low-pass filters only by changing the nominal values of the frequency-dependent resistors.

A known filter (Chepurnova G.V., Bespalov A.I., Efanov V.N., PM RU 93601 dated 04/27/2010), consisting of a fixed unregulated second-order bandpass filter and an adjustable second-order low-pass filter, where by changing the coefficients transfer function, both positive and negative polarity and two adders, an adjustable frequency and Q-factor bandpass filter is formed, which makes it possible to increase its reliability and controllability due to separate regulation of the center frequency and the bandwidth of the bandpass filters.

However, in order to change the filter parameters, it is necessary to set the numerical values of the coefficients precisely, and at the same time, the operational restructuring of its parameters is not provided.

Known tunable high-order bandpass filters (Kapustyan V.I. High-order active RC filters. M .: Radio and Communication, 1985), where frequency tuning is carried out by digital controlled resistances requiring generators of the control code, or a pulse-width control signal, which greatly complicates the filter circuit.

The most rational construction of fourth-order band-pass filters is by serially connecting a high-pass filter and a second-order low-pass filter, since it is possible to provide the setting of the required bandwidth of the synthesized band-pass filter by tuning the cutoff frequency of each of the filters.

To maintain the constancy of the transmission coefficient of the PF in the passband without ripples, inherent in Butterworth filters, it is advisable to build the PF as a maximally flat filter. In this case, the second-order high-pass and low-pass filters are required to maintain a constant Q-factor of each of the filters corresponding to the tabular values of the Butterworth filter coefficients. The cutoff frequencies must be different, and the cutoff frequency of the high-pass filter must be lower than the cutoff frequency of the low-pass filter. The disadvantages of this solution are the need to simultaneously change the values of two resistors in the frequency-driving circuit of each filter, as well as to synchronously change all four frequency-driving resistors in the PF.

The use of a low-pass filter and a high-pass filter, constructed by the state-variable method, allows independent tuning of the cutoff frequencies and Q-factors of each filter. However, tuning the cutoff frequency of a high-pass filter or low-pass filter without changing the filter Q-factor requires two tunable resistances in the frequency-driving circuit.

The closest to the proposed utility model is US patent US 4516078 dated 05/07/1985, in which two filters connected in series, a dual potentiometer for controlling filter parameters and a dual filter operating mode switch are used.

The disadvantage of this circuit is its complexity associated with the use of a synchronous detection system with several analog multipliers and a voltage-controlled generator.

The problem to be solved by the claimed utility model is to provide independent tuning of the center frequency of the bandpass filter without changing the passband, as well as tuning the passband without changing the center frequency of the bandpass filter using one control element and a switch, which ensures the convenience of filter operation.

To achieve the technical result, two consecutively connected active RC filters of the second order are used, namely a low-pass filter (patent RU 128043 dated 05/10/2012) and a high-pass filter (patent RU 135206 dated 11/27/2013), which provide a cutoff frequency tuning within a decade without significantly affecting the Q value. The change in the quality factor at the edges of the frequency range is no more than 2%. These filters contain potentiometers for controlling their cutoff frequencies, and these two potentiometers are made in the form of one double potentiometer. For the operating modes of the device, a double switch is introduced, to the moving contacts of which the extreme terminals of the potentiometer of the active RC low-pass filter are connected, the fixed contacts of this switch are cross-connected with each other and with the output of the differential operational amplifier of the low-pass filter, the rest of the fixed contacts of the switch are connected with the output of the inverting operational amplifier low-pass filter.

In the case of changing the cutoff frequencies of both filters in the same direction (both cutoff frequencies decrease or increase), the tuning of the center frequency of the BPF is provided while maintaining the constancy of the bandwidth of the BPF. In the case of changing the cutoff frequencies of both filters in different directions (the cutoff frequency of the lowpass filter cutoff decreases, and the cutoff frequency of the highpass filter cutoff increases), the bandpass frequency of the BPF is re-tuned while the center frequency of the BPF remains constant. Thus, two modes of operation of the PF are possible when changing the cutoff frequencies of the LPF and HPF with one double potentiometer.

Changing the operating modes of the PF is carried out using a double switch of the potentiometer outputs of only one of the filters (for example, a low-pass filter) with a fixed position of the potentiometer outputs of the other filter - a high-pass filter.

The essence of the utility model is illustrated by drawings, where Fig. 1 shows a graph of changes in the central frequency f ₀ (f ₀ = var) of the proposed bandpass filter by the value ± Δf ₁ while maintaining the bandwidth f _P = f _B -f _N (f _P = const), this graph corresponds to the first mode of operation of the PF.

FIG. 2 shows a graph of the change in the bandwidth f _P = f _B -f _N (f _P = var) of the proposed bandpass filter by the value ± Δf ₁ while maintaining the central frequency f ₀ (f ₀ = const), this graph corresponds to the second mode of operation of the PF.

FIG. 3 shows the block diagram of the proposed PF corresponding to the first mode of its operation, where: 1 - active RC low-pass filter; 2 - active RC high-pass filter; 3 - double potentiometer; 4 - LPF potentiometer; 5 - HPF potentiometer; 6 - double switch; 7 - the first movable contact of the double switch; 8 - the second movable contact of the double switch; 9, 10, 11, 12 - fixed contacts of the double switch (6); 13 - output of the differential operational amplifier (DOW) LPF; 14 - output of the LPF inverting operational amplifier.

FIG. 4 shows a block diagram of the proposed PF corresponding to the second mode of its operation, where: 1 - active RC low-pass filter; 2 - active RC high-pass filter; 3 - double potentiometer; 4 - LPF potentiometer; 5 - HPF potentiometer; 6 - double switch; 7 - the first movable contact of the double switch; 8 - the second movable contact of the double switch; 9, 10, 11, 12 - fixed contacts of the double switch (6); 13 - output of the LPF differential operational amplifier; 14 - output of the LPF inverting operational amplifier.

FIG. 5 shows the frequency response of three PFs, made according to the proposed scheme, tuned in accordance with three standard ranges of heart rate variability (HRV) - HF (15), LF (16) and VLF (17). FIG. 6 shows an example of using three PFs, made according to the proposed scheme, to isolate frequency components corresponding to three standard HRV ranges: the initial cardiointervalogram (CIG) (18), the results of CIG filtering in the ranges: HF (19), LF (20) and VLF ( 21), 22 is the total voltage of the outputs of the three band-pass filters corresponding to the original CIG (18). These graphs illustrate the process of continuous spectral analysis of RIG.

The introduction of switching the outputs of the potentiometer allows the proposed PF circuit to operate in two modes (Fig. 1, 2) and provides a convenient transition from one mode of operation (Fig. 3) to another (Fig. 4).

PF works as follows. The cutoff frequency of the low-pass filter (1) is changed with the potentiometer (4). When you move the potentiometer slider (4) to the output of the LPF differential operational amplifier (13), the transmission coefficient in the frequency-dependent feedback loop increases, which leads to an increase in the filter cutoff frequency. When moving the potentiometer slider (4) to the output of the LPF inverting operational amplifier (14), the gain of the DOA also decreases in the frequency-dependent feedback loop, which leads to a decrease in the cutoff frequency. Changing the cutoff frequency of the high-pass filter (2) is performed using a potentiometer (5). Thus, the required setting of the bandwidth of the PF is provided using one double potentiometer, and the switching of the filter operating modes using a switch, this increases the usability of the bandpass filter with a tunable frequency range for continuous spectral analysis of the cardiointervalogram.

Claims (1)

A bandpass filter with a tunable frequency range for continuous spectral analysis of a cardiointervalogram in real time, consisting of two tunable active RC filters connected in series, namely a low-pass filter and a high-pass filter containing filter cutoff frequency control potentiometers, characterized in that two potentiometers control of the cutoff frequencies of the filters are made in the form of a single double potentiometer, a double switch of operating modes is introduced, to the movable contacts of which the extreme leads of the potentiometer of the RC low-pass filter are connected, the fixed contacts of this switch are cross-connected with each other and with the output of the differential operational amplifier of the low-pass filter, the remaining fixed contacts of the switch are connected to the output of the inverting operational amplifier of the low-pass filter.

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