RU2656728C1 - Arc-filter of bottom frequencies with an independent setting of main parameters - Google Patents

Abstract

FIELD: radio engineering and communications.

SUBSTANCE: invention relates to radio engineering and communication and can be used as an interface for matching the signal source, for example, with analog-to-digital converters of various functional purposes. Circuit solution is proposed that allows adjust LPF parameters one-by-one when a previously configured parameter is not changed when setting the next parameter.

EFFECT: creation of an ARC-low-pass filter scheme that provides independent adjustment of the main parameters – a pole frequency,a pole attenuation, and the DC filter transmission factor.

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Description

The invention relates to radio engineering and communication and can be used as an interface for matching a signal source, for example, with analog-to-digital converters for various functional purposes.

Active low-pass RC filters (LPFs) are among the common analog devices that determine the quality indicators of many radio signal processing devices [1-23].

One of the problems in designing a low-pass filter is to ensure their specified basic parameters under the conditions of dispersion and instability of frequency-setting resistors and capacitors [1, 3, 4]. In practice, the precision of the low-pass filter is ensured by fine tuning the passive elements. However, in the known low-pass filter circuits [1-23], when setting one parameter, for example, the pole frequency (ω _p ), another parameter changes - the pole attenuation (d _p ) or the transmission coefficient (M).

The closest prototype of the claimed device is an ARC filter according to A. St. USSR 1187241. It contains (Fig. 1) the input of device 1 connected to the signal source 2, the first 3 operational amplifier, the output of which 4 is the output of the device and connected to the inverting input of the first 3 operational amplifier through the first 5 resistor, second 6, third 7 , the fourth 8 and fifth 9 resistors, the first 10 capacitor connected between the combined first terminals of the fourth 8 and fifth 9 resistors and the output 4 of the first 3 operational amplifier, and the second output of the resistor 9 is connected to the non-inverting input of the first 3 operational amplifier and the first terminal of the second capacitor 11, a second matching amplifier 12, power supply common bus 13.

A significant disadvantage of the ARC filter prototype of FIG. 1 consists in the fact that in the process of tuning its one parameter, other parameters of the amplitude-frequency characteristic (AFC) are changed. This makes it difficult to manufacture products of this class.

The main objective of the alleged invention is to create a circuit ARC low-pass filter, which provides independent sequential adjustment of the main parameters.

The object is achieved in that in the ARC filter of FIG. 1, containing the input of device 1, connected to signal source 2, the first 3 operational amplifier, the output of which 4 is the output of the device and connected to the inverting input of the first 3 operational amplifier through the first 5 resistor, second 6, third 7, fourth 8 and fifth 9 resistors , the first 10 capacitor connected between the combined first terminals of the fourth 8 and fifth 9 resistors and the output 4 of the first 3 operational amplifier, and the second output of the resistor 9 is connected to a non-inverting input of the first 3 operational amplifier and the first output ohms of the second capacitor 11, the second 12 matching amplifier, a common bus of power supplies 13, new elements and connections are provided - a matching operational amplifier 12 is used as the second 12 matching amplifier, whose non-inverting input is connected to a common bus of power supplies 13, the output is connected to the second output resistor 8 and through the first 14 an additional resistor is connected to the inverting input of the matching operational amplifier 12, between the inverting input of the first 3 operational amplifier and the inverting input m matching operational amplifier 12 includes a second 6 resistor, the input of device 1 is connected to the inverting input of the matching operational amplifier 12 through a second 15 additional resistor, and the third 7 resistor is connected between the common bus of power supplies 13 and the inverting input of the first 3 operational amplifier, and the second 11 condensates connected between the common bus power supply 13 and the non-inverting input of the first 3 operational amplifier.

In the drawing of FIG. 1 shows a diagram of a prototype filter, and in the drawing of FIG. 2 is a diagram of the inventive ARC filter.

In the drawing of FIG. 3 shows graphs of changes in amplitude-frequency (AFC) and phase-frequency (PFC) characteristics when tuning the pole frequency (ω _p ), and in the drawing of FIG. 4 - when setting the pole attenuation (d _p ) using resistors 14 and 6 (R14, R6) and resistors 5 and 7 (R5, R7), respectively.

In the drawing of FIG. Figure 5 shows the graphs of the frequency response when adjusting the transmission coefficient M using resistor 15 (R15).

Low-pass ARC filter with independent tuning of the main parameters of FIG. 2 contains the input of device 1, connected to signal source 2, the first 3 operational amplifier, the output of which 4 is the output of the device and connected to the inverting input of the first 3 operational amplifier through the first 5 resistor, second 6, third 7, fourth 8 and fifth 9 resistors, the first 10 capacitor connected between the combined first terminals of the fourth 8 and fifth 9 resistors and the output 4 of the first 3 operational amplifier, and the second output of the resistor 9 is connected to the non-inverting input of the first 3 operational amplifier and the first output a second 11 capacitor, a second 12 matching amplifier, a common bus of power supplies 13. As a second 12 matching amplifier, a matching operational amplifier 12 is used, the non-inverting input of which is connected to a common bus of power supplies 13, the output is connected to the second output of the resistor 8 and through the first 14 additional the resistor is connected to the inverting input of the matching operational amplifier 12, between the inverting input of the first 3 operational amplifier and the inverting input of the matching operational amplifier 1 2, the second 6 resistor is turned on, the input of device 1 is connected to the inverting input of the matching operational amplifier 12 through the second 15 additional resistor, and the third 7 resistor is connected between the common bus of power supplies 13 and the inverting input of the first 3 operational amplifier, and the second 11 capacitor is connected between the common bus power supplies 13 and a non-inverting input of the first 3 operational amplifier.

Consider the operation of the ARC filter of FIG. 2.

The passage of the signal from input 1 of the claimed low-pass filter to its output 4 is determined by the transfer function

where M is the transmission coefficient of the DC filter,

ω _p is the frequency of the pole,

d _p is the pole attenuation.

At high amplification factors of the first 3 and second 12 operational amplifiers, the main parameters of the low-pass filter of FIG. 2 (frequency ω _p and attenuation d _{p of the} pole, as well as the transmission coefficient of the filter M) depend only on the parameters of a strictly defined group of passive elements and correspond to the following formulas [2]:

- gear ratio

- pole frequency

- pole attenuation

The following notation is used in formulas (2) - (4): R ₅ , R ₆ , R ₇ , R ₈ , R ₉ , R ₁₄ , R ₁₅ are the resistances of resistors 5, 6, 7, 8, 9, 14, and 15, respectively , and the capacitance of the first 10 (C ₁₀ ) and second 11 (C ₁₁ ) capacitors.

Independent adjustment of the circuit parameters is possible when, when configuring the next circuit parameter, its previous previously configured parameter will not be changed.

From the analysis of formulas (2) - (4) it follows that in the proposed low-pass filter of FIG. 2, such a setting is possible in the following sequence:

The first stage: adjusts the frequency of the pole ω _p (Fig. 3) by changing the resistances of the resistors 14 and 6 (R ₁₄ and R ₆ ). Further, these resistors are fixed.

The second stage: adjusts the pole attenuation d _p (Fig. 4) by changing the resistances of the resistors 5 and 7 (R ₅ and R ₇ ). In the next step, the resistances R ₅ and R _{7 are} not changed.

Third stage: the transmission coefficient M is adjusted (Fig. 5) by changing the resistance of the resistor 15 (R ₁₅ ).

The above conclusions are confirmed by the results of computer simulation of FIG. 3-fig. 5.

In FIG. 3 shows that when the resistances of the resistors R ₁₄ or R ₆ change, the frequency of the pole ω _r changes, i.e. the frequency changes at which the phase shift is 90 °.

In FIG. 4 shows that when the resistances of the resistors R ₅ or R ₇ change, the pole attenuation d _p changes, i.e. the rise in frequency response at the pole frequency and the slope of the frequency response in the region of the pole frequency are changed. In this case, the frequency of the pole litter remains unchanged.

In FIG. 5 shows that when the resistance of the resistor R ₁₅ changes, the phase response does not change, i.e. the frequency and attenuation of the pole remain unchanged. The shape of the frequency response also remains unchanged, and only the transmission coefficient of the filter M at constant current changes.

It should be noted that the low-pass filter prototype and other well-known schemes of ARC filters do not possess these properties.

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

BIBLIOGRAPHIC LIST

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Claims (1)

An ARC low-pass filter with independent adjustment of the main parameters, containing the input of the device (1) connected to the signal source (2), the first (3) operational amplifier, the output of which (4) is the output of the device and connected to the inverting input of the first (3) operational amplifier through the first (5) resistor, the second (6), third (7), fourth (8) and fifth (9) resistors, the first (10) capacitor connected between the combined first terminals of the fourth (8) and fifth (9) resistors and the output (4) of the first (3) operational amplifier, and the second output of the resistor RA (9) is connected with the non-inverting input of the first (3) operational amplifier and the first output of the second (11) capacitor, the second (12) matching amplifier, the common bus of power supplies (13), characterized in that as the second (12) matching amplifier a matching operational amplifier (12) is used, the non-inverting input of which is connected to a common bus of power sources (13), the output is connected to the second output of the resistor (8) and through the first (14) an additional resistor is connected to the inverting input of the matching operational amplifier (12), between the second (6) resistor is connected to the inverting input of the first (3) operational amplifier and the inverting input of the matching operational amplifier (12), the input of the device (1) is connected to the inverting input of the matching operational amplifier (12) through an additional resistor (15), the third (7) a resistor is connected between the common bus of power supplies (13) and the inverting input of the first (3) operational amplifier, and the second (11) capacitor is connected between the common bus of power supplies (13) and the non-inverting input of the first (3) operational amplifier Itel.

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