RU2429560C1 - Band-pass piezoelectric filter - Google Patents

Abstract

FIELD: radio engineering. ^ SUBSTANCE: band-pass piezoelectric filter includes three in-series connected piezoelectric resonators (PR) (1-3); to the first output of PR (1) there connected is the first capacitor (C) (4), the second output of which is connected to common bus; to outputs of PR (2) there connected is the second and the third C (5,6), the second outputs of which are connected; to the second output of PR (3) there connected is the fourth C (7) the second output of which is connected to common bus. In addition, there is introduced fifth C (8) connecting the first output of PR (1) to input potential terminal of filter and sixth C (9) connecting the second output of PR (3) to output potential terminal of filter. Besides, to the first output of PR (1) there connected is the first inductance coil (10) the second output of which is connected through the seventh C (11) to the second output of PR (1) and through the eighth C (12) to common bus. The second inductance coil (13) the second output of which is connected through the ninth C (14) to the first output of PR (3) and through the tenth C (15) to common bus is connected to the second output of PR (3). The second outputs of the second and the third C (5,6) are connected through the third inductance coil (16) to common bus. ^ EFFECT: improvement of filter selectivity and conditions of connection to external devices without using any additional matching circuits. ^ 2 dwg

Description

The proposed device relates to electronics and can be used in preselectors of professional radios.

Closest to the proposed device is a band-pass piezoelectric filter [1], consisting of several included cascade ladder U-shaped links, each of which contains a piezoelectric resonator in the longitudinal branch, and capacitors in the transverse branches.

This type of filter is quite technologically advanced, it is widely used in practice when implementing relative bandwidths in the range of (0.1-0.2) / r, where r is the capacitive coefficient of the piezoelectric resonator, provides low power losses in the working frequency band, and we have chosen as prototype.

The disadvantage of this filter is that the attenuation poles are always located above the passband, and their detuning from the average frequency is limited by the magnitude of the resonance gap of the piezoresonators used in the circuit. As a result of this, the required attenuation in the delay band at high values of the frequency offset is provided by the use of a large number of links. The use of a large number of links not only increases the cost of the filter, but at the same time the introduced attenuation and unevenness of the frequency response in the passband are worsened.

The objective of the invention is to improve the selectivity of the filter and improve the conditions for interfacing with external devices without the use of additional matching circuits.

The problem is solved in that in the known filter circuit containing three series-connected piezoresonators, the terminals of which are connected to the first, second, third and fourth capacitors, while the first capacitor is connected between the first output of the first piezoresonator and a common bus, the second and third capacitors are connected to the first and second conclusions of the second piezoresonator, and their second conclusions are interconnected, the fourth capacitor is connected between the second output of the third piezoresonator and a common bus, additional but the fifth capacitor is connected, connecting the first output of the first piezoresonator with the input potential terminal of the filter, the sixth capacitor, connecting the second output of the third piezoresonator with the output potential terminal of the filter, in addition, the first inductor is introduced into the circuit, the first output of which is connected to the first output of the first piezoresonator and its second terminal is connected to the seventh and eighth capacitors, the second terminal of the seventh capacitor is connected to the second terminal of the first piezoresonator, the second terminal of the eighth to the capacitor is connected to the common bus, and the second inductor connected to the second terminal of the third piezoresonator, its second terminal is connected to the ninth capacitor, the second terminal of which is connected to the first terminal of the third piezoresonator, and the tenth capacitor, the second terminal of which is connected to the common bus, the circuit contains also a third inductor, the first terminal of which is connected to the second terminals of the second and third capacitors, its second terminal is connected to a common bus.

Comparative analysis shows that the claimed technical solution differs from the prototype in that the device further comprises a fifth capacitor connected between the first output of the first piezoresonator and the input potential terminal of the filter, a sixth capacitor connected between the second output of the third piezoresonator and the output potential terminal of the filter, the first coil inductance, the first output of which is connected to the first output of the first piezoresonator, and the second is connected to the seventh capacitor, the second the water of which is connected to the second terminal of the first piezoresonator, and the eighth capacitor, the second terminal of which is connected to a common bus, the second inductor, the first terminal of which is connected to the second terminal of the third piezoresonator, the ninth capacitor is connected to the second terminal of the inductor, the second terminal is connected to the first terminal the third piezoelectric resonator, and the tenth capacitor, the second output connected to a common bus, the third inductor connected to the second terminals of the second and third condensate s, the second terminal of the inductor is connected to the common bus.

When comparing the inventive device not only with the prototype, but also with other well-known science and technology technical solutions, no solutions are found that have similar characteristics.

Figure 1 shows the electric circuit of the filter, consisting of three series-connected piezoresonators 1, 2, 3, the first capacitor 4 connected to the first output of the first piezoresonator 1, the second capacitor 5 and the third capacitor 6 connected to the first and second terminals of the second piezoresonator 2 respectively, of the fourth capacitor 7 connected to the second terminal of the third piezoresonator 3, while the second terminals of the first and fourth capacitors are connected to a common bus, the fifth capacitor 8 connecting the first a piezoresonator with an input potential terminal of the filter, a sixth capacitor 9 connecting the third piezoresonator with an output potential terminal of the filter, the first inductor 10 connected to the first terminal of the first piezoresonator, the second terminal of the inductor is connected to the seventh capacitor 11, the second terminal connected to the second terminal of the first piezoreson , and the eighth capacitor 12, the second terminal of which is connected to a common bus, of the second inductor 13 connected to the second terminal of the third piez resonator, its second terminal is connected to the ninth capacitor 14, the second terminal of which is connected to the first terminal of the third piezoresonator, and to the tenth capacitor 15, the second terminal of which is connected to the common bus, as well as the third inductor 16 connected to the second terminals of the second 5 and third 6 capacitors, the second terminal of the inductor 16 is connected to a common bus.

The device operates as follows.

The filter shown in figure 1, consists of three cascaded links. The first link of this filter, consisting of a piezoelectric resonator 1, an inductor 10 and capacitors 4, 8, 11, 12, is shown in FIG. A circuit consisting of an inductor 10 and capacitors 4 and 12 is excited by a signal supplied to this circuit through a coupling capacitor (capacitor 8), while the voltage generated on the inductor 10 is supplied to the capacitor 11 and the piezoresonator 1 in antiphase. The currents flowing through the capacitor 11 and the load resistance R and through the piezoresonator 1 and the resistor R are subtracted on this resistor. If the values of the capacitors 4 and 12 are chosen to be approximately equal, then the voltage values at the input of the capacitor 11 and the piezoresonator 1 will also be equal and opposite in phase, as a result of which the transfer function, estimated as the ratio of the voltages across the resistor R and capacitor 4, will be determined by the ratio:

, где

where

X _c is the resistance of the capacitor 11,

X _p is the resistance of the piezoresonator 1.

Thus, the transfer function corresponds to the transfer function of a symmetrical four-terminal bridge loaded with resistance R, in one branch of which a capacitor with resistance X _c is connected, in the second - X _p [2]. The role of the load resistance is performed by the input resistance of the second filter link. As is known [1], such a circuit forms a strip chain, the bandwidth of which is determined by the frequency gap of the piezoelectric resonator, and the position of the attenuation pole is determined by the value of the resistance of the capacitor 11.

The second link containing the piezoresonator 2, capacitors 5, 6 and the inductor 16, due to the symmetry of the circuit, is also the equivalent of a symmetrical four-terminal bridge and also forms a bandpass filter with a passband equal to the frequency gap of the piezoresonator. The attenuation pole of the second link can also be chosen arbitrarily, as in the first link, however, in comparison with the first link at frequencies above the passband, a “spurious" passband is formed. In addition, this link for matching with loads requires the use of additional matching ends, which are performed in the form of half-links of band-pass LC filters, or antimetric LC filters of low or high frequencies [1, 3].

The third link of the filter is made according to the scheme identical to the first. In general, the filter contains three band links that are consistent with each other in terms of characteristic resistance. Coordination with the input and output loads is carried out by selecting the desired capacitors 8 and 9. The inclusion of the second link containing a smaller number of capacitors somewhat simplifies the circuit, and the decrease in attenuation at frequencies where a “spurious” bandwidth is formed is compensated by the first and third links that do not have side bandwidths.

Thus, the proposed circuit implements a band-pass filter of the third class for attenuation, the theoretical bandwidth is equal to the frequency gap of the piezoresonators, the attenuation poles can be selected at any predetermined frequencies of the delay band.

Compared with the prototype, this filter provides a wider passband, a large amount of attenuation in the delay band and does not require the use of additional matching circuits with external loads.

Information sources

1. Velikin Ya.I., Helmont Z.Ya., Zelyakh E.V. Piezoelectric filters. Ed. “Communication” M., 1966, p. 108, 177.

2. A.F. Beletsky. Fundamentals of the theory of linear electrical circuits. Ed. "Communication" M., 1967, p. 440.

3. Issues of matching piezoelectric filters for given loads. Yasinsky I.M., Yakovlev A.N., Radio communication technology, issue 13, Omsk, 2008.

Claims (1)

A band-pass piezoelectric filter containing three piezoelectric resonators connected in series, the first capacitor is connected to the first output of the first piezoelectric resonator, the second terminal of which is connected to a common bus, the second and third capacitors are connected respectively to the terminals of the second piezoelectric resonator, the second terminals of which are connected, and the second terminal of the third piezoelectric resonator is connected a fourth capacitor, the second terminal of which is connected to a common bus, characterized in that a fifth condensate is additionally introduced into the filter circuit connecting the first terminal of the first piezoresonator with the input potential terminal of the filter, and a sixth capacitor connecting the second terminal of the third piezoresonator with the output potential terminal of the filter, in addition, the first inductor is connected to the first terminal of the first piezoresonator, the second terminal of which is connected through the seventh capacitor to the second terminal the first piezoresonator and through the eighth capacitor with a common bus, a second inductor is connected to the second terminal of the third piezoresonator, the second pin d through which the ninth capacitor connected to the first terminal of the third through piezo resonator and the tenth capacitor to the common bus, the second terminals of the second and third capacitors through a third inductor connected to a common bus.

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