RU117754U1 - ACTIVE RC FILTER - Google Patents

Abstract

1. An active RC filter containing an operational amplifier and a frequency setting unit, where the first input of the frequency setting unit is the input of the active RC filter, and the output of the frequency setting unit is connected to the input of the operational amplifier, the output of which is connected to the second input of the frequency setting unit and is the output of the active RC- filter, characterized in that a resistor is introduced, the first terminal of which is connected to the input of the operational amplifier, and the second terminal is connected to the common bus of the active RC filter, while the frequency setting unit is made in the form of an RC element with distributed parameters of the "first resistor-dielectric- second resistor ". ! 2. The device according to claim 1, characterized in that to perform the function of a high-pass filter in the frequency setting unit, the first terminal of the first resistor is the first input of the frequency setting unit, the second terminal of the first resistor is the output of the frequency setting unit, and the first and second terminals of the second resistor are combined and are the second input of the frequency setting block. ! 3. The device according to claim 1, characterized in that to perform the function of a band-stop filter in the frequency setting unit, the first terminal of the first resistor is the output of the frequency setting unit, the second terminal of the first resistor is the second input of the frequency setting unit, and the first and second terminals of the second resistor are combined and are the first input of the frequency setting block. ! 4. The device according to claim 1, characterized in that for performing the function of a low-pass filter with zero transmission in the frequency setting unit, the first terminal of the first resistor is the second input of the frequency setting unit, the second terminal of the first resistor

Description

The utility model relates to microelectronics and can be used to create frequency-selective quadripoles using active elements and RC elements with distributed parameters.

A known filter based on an RC element with distributed parameters, consisting of sequentially alternating dielectric and resistive / conductive layers with leads from resistive layers, moreover, the number of leads is proportional to the number of resistive layers and is at least two from each resistive layer, the input terminal of the middle resistive layer , the input and output terminals of the lower resistive layer are electrically connected to zero potential, the input terminal of the upper resistive layer is electrically connected to the source x signals, and the output terminal of the upper resistive layer is connected to an electric signal meter [RU 2408977, C1, H03H 1/02, 10/10/2011].

The disadvantage of this device is the relatively narrow functionality, since it is not active and can only be used as a notch filter.

An active RC filter is also known, which contains an operational amplifier, two capacitors and five resistors, moreover, the first output of the first resistor is connected to a common bus, and its second output is connected to the second output of the second resistor, the first output of the second resistor is connected to the first output of the third resistor and to the inverting input of the operational amplifier, the second output of the third resistor is connected to the output of the operational amplifier, the first output of the fourth resistor is connected to the first output of the first capacitor, the second conclusions of the fifth resistor and the second capacitor is connected to the non-inverting input of the operational amplifier, in addition, there is a sixth resistor that is connected between the common bus and the inverting input of the operational amplifier, the first conclusions of the first capacitor and the fourth resistor are connected to the first output of the second capacitor, the first output of the fifth resistor is connected to the second conclusions of the first and second resistors, the second conclusions of the first capacitor and fourth resistor are connected to the input of the device and the output of the operational amplifier with accordingly [RU 2149500, C1, H03H 11/14, 05/20/2000].

This device is an active filter, but it has relatively narrow functionality, since it can only be used as a high-pass filter.

The closest in technical essence to the proposed one is a device containing an operational amplifier, a frequency-setting unit, a correction element and a weight adder, the first input of the frequency-setting unit being an input of the device, the outputs of the frequency-setting unit and a weight adder are connected respectively to the inverting and non-inverting inputs of the operational amplifier, the input of the weight adder connected to the output of the operational amplifier, the input of the correction element is connected to the output of the operational amplifier And the output of the correction element is the output device connected to the second input of the frequency control unit [RU 2108660, C1, N03N 11/10, 10.04.1998].

This device is an active filter, but it also has relatively narrow functionality, since it can only be used as a band-pass filter, and various circuitry solutions of the device elements lead only to frequency range variations.

The required technical result is to expand the functionality.

The required technical result is achieved by the fact that in the device containing the operational amplifier and the frequency block, the first input of the frequency block is the input of the device, and the output of the frequency block is connected to the input of the operational amplifier, the output of which is connected to the second input of the frequency block and is the output of the device, a resistor is introduced, the first output of which is connected to the input of the operational amplifier, and the second output of the resistor is connected to the common bus of the device, while the frequency-setting block k is made in the form of an RC element with distributed parameters of the type “first resistor-dielectric-second resistor”.

In addition, the required technical result is achieved in that, to perform the high-pass filter function in the frequency setting unit, the first output of the first resistor is the first input of the frequency setting unit, the second output of the first resistor is the output of the frequency setting unit, and the first and second outputs of the second resistor are combined and are the second input frequency-setting unit.

In addition, the desired technical result is achieved in that, to perform the function of a band-stop filter in the frequency block, the first output of the first resistor is the output of the frequency block, the second output of the first resistor is the second input of the frequency block, and the first and second terminals of the second resistor are combined and are the first input of the frequency setting unit.

In addition, the required technical result is achieved by the fact that, in order to perform the function of a low-pass filter with zero transmission in the frequency setting unit, the first output of the first resistor is the second input of the frequency setting unit, the second output of the first resistor is connected to the device common bus, and the first and second conclusions of the second resistors are the first input and output of the frequency block, respectively.

The drawing shows:

figure 1 is a diagram of an active RC filter;

figure 2 - diagram of an active RC filter with a high-pass filter function;

figure 3 is a diagram of an active RC filter with the function of a band-stop filter;

4 is a diagram of an active RC filter with a low pass filter function with zero transmission.

figure 5 - the frequency response of the high-pass filter (figure 5, a) and the results of its synthesis (figure 5, b, c); 6 - the frequency response of the band-stop filter (figure 6, a) and the results of its synthesis (figure .6, b, c)

Fig.7 - the frequency response of the low-pass filter with zero transmission (Fig.7, a) and the results of its synthesis (Fig.7, b, c)

Active RC filter (figure 1) contains an operational amplifier 1 and a frequency setting unit 2.

In the active RC filter (Fig. 1), the first input of the frequency setting unit 2 is the input of the active RC filter, and the output of the frequency setting unit 2 is connected to the input of the operational amplifier 1, the output of which is connected to the second input of the frequency setting unit 2 and is the output of the active RC filter .

In addition, the active RC filter (figure 1) contains a resistor 3 whose first output is connected to the input of the operational amplifier 1, and the second output of the resistor 3 is connected to the common bus of the active RC filter, while the frequency-setting unit 2 is made in the form of RC- an element with distributed parameters of the type "first resistor-dielectric-second resistor".

In the embodiment of the active RC filter (Fig. 2), which functions as a high-pass filter, in the frequency setting unit 2, the first output of the first resistor 4 is the first input of the frequency setting unit 2, the second output of the first resistor 4 is the output of the frequency setting unit 2, and the first and second conclusions the second resistor 5 are combined and are the second input of the frequency setting unit 2.

In the embodiment of the active RC filter (Fig. 3), to fulfill the function of a band-stop filter in the frequency setting unit 2, the first output of the first resistor 4 is the output of the frequency setting unit 2, the second output of the first resistor 4 is the second input of the frequency setting unit 2, and the first and second the findings of the second resistor 5 are combined and are the first input of the frequency setting unit 2.

In the embodiment of the active RC filter (Fig. 4), in order to fulfill the function of a low-pass filter with zero transmission in the frequency setting unit, the first output of the first resistor 4 is the second input of the frequency setting unit 2, the second output of the first resistor 4 is connected to a common bus of the active RC filter, and the first and second terminals of the second resistor 5 are the first input and output of the frequency setting unit 2, respectively.

The active RC filter works as follows.

The expression for the transfer function in the embodiment of the active RC filter (Fig. 2), which functions as a high-pass filter, has the form

where y _ij are the y-parameters of a two-dimensional RC element with distributed parameters of the "first resistor-dielectric-second resistor" type, α = R ₃ / R ₅ , where R ₃ , R ₅ are the resistance values of resistor 3 and second resistor 5.

The results of high-pass filter synthesis are shown in FIG. 5. The fulfillment of the requirements for the attenuation characteristic is confirmed by the graph of the frequency response of the high-pass filter, shown in figure 5, a.

The design of a two-dimensional RC element with distributed parameters of the type “first resistor-dielectric-second resistor”, resulting from the synthesis, is shown in the form of drawings of resistive layers and contact pads for them in FIGS. 5, b and 5, c. The layer of the second resistor 5 is divided into three sections, two of which have contact pads included in the circuit, and the third section interacts with the rest of the structure through capacitive connections between the layers of the first 4 and second 5 resistors.

The expression for the transfer function in the embodiment of the active RC filter, performing the functions of a band-stop filter (Fig. 3), has the form

Figure 6 shows a graph of the frequency response of such a filter and the results of its synthesis.

The expression for the transfer function in the embodiment of an active RC filter that performs the function of a low-pass filter with zero transmission (Fig. 4) has the form

The results of link synthesis according to the given requirements for the attenuation characteristic are depicted in Fig. 7.

It should be noted that the y-parameters included in formulas (1) - (3) for the transfer functions of the considered options for the active RC filter are calculated not by analytical expressions, but numerically, in the process of analysis on each cycle, for example, by the genetic algorithm method. Thus, these expressions are valid for any patterns of layers and pads of a two-dimensional RC element with distributed parameters of the type “first resistor-dielectric-second resistor”.

Thus, thanks to the introduced improvements, the required technical result is achieved, which consists in expanding the functionality, since the implementation of the frequency-setting unit in the form of an RC element with distributed parameters of the type “first resistor-dielectric-second resistor” and the introduction of a resistor with corresponding connections allows implementing various frequency options characteristics of the active filter.

Claims (4)

1. An active RC filter containing an operational amplifier and a frequency setting unit, the first input of the frequency setting unit being the input of the active RC filter, and the output of the frequency setting unit being connected to the input of the operational amplifier, the output of which is connected to the second input of the frequency setting unit and is the output of the active RC filter, characterized in that a resistor is introduced, the first output of which is connected to the input of the operational amplifier, and the second output is connected to the common bus of the active RC filter, while the frequency setting unit is made in the form of an RC element with distributed parameters of the type “first resistor-dielectric-second resistor”. 2. The device according to claim 1, characterized in that to perform the function of a high-pass filter in the frequency setting unit, the first output of the first resistor is the first input of the frequency setting unit, the second output of the first resistor is the output of the frequency setting unit, and the first and second outputs of the second resistor are combined and are the second input of the frequency setting unit. 3. The device according to claim 1, characterized in that to perform the function of a band-stop filter in the frequency block, the first output of the first resistor is the output of the frequency block, the second output of the first resistor is the second input of the frequency block, and the first and second terminals of the second resistor are combined and are the first input of the frequency block. 4. The device according to claim 1, characterized in that for performing the function of a low-pass filter with zero transmission in the frequency setting unit, the first output of the first resistor is the second input of the frequency setting unit, the second output of the first resistor is connected to the device common bus, and the first and second conclusions of the second resistors are the first input and output of the frequency block, respectively.