KR100342940B1 - Surface acoustic wave filter taking account of an external matching circuit - Google Patents

Abstract

According to the present invention, the SAW filter is designed and manufactured by compensating the characteristics of the SAW filter considering the mutual effect of the peripheral circuit and the external matching circuit in the initial design of the SAW filter, thereby exhibiting the ideal filter characteristics when matched with the actual external matching circuit. A SAW filter considering an external matching circuit, in which the center frequency of the input electrode is fixed and the center frequency of the output electrode differs by a value set for the center frequency of the input electrode so that the upper frequency is higher than the set value in the set frequency pass band. It provides a SAW filter considering an external matching circuit, which is designed to be adjusted low.

Description

Surface acoustic wave bandpass filter considering external matching circuit {SURFACE ACOUSTIC WAVE FILTER TAKING ACCOUNT OF AN EXTERNAL MATCHING CIRCUIT}

The present invention relates to a surface acoustic wave bandpass filter (hereinafter, abbreviated as SAW filter). More specifically, the SAW filter is designed and manufactured in consideration of the characteristics of a circuit matched with the SAW filter. The present invention relates to a SAW filter suitable for improving the output characteristics of the filter.

In general, the SAW filter is an element for selecting only a frequency of a specific band using a surface acoustic wave, and is used as a high frequency circuit bandpass filter of various communication devices.

The basic configuration of the SAW filter forms an interdigital transducer (IDT) for converting an electrical signal and a surface wave into a piezoelectric substrate surface. Aluminum is generally used as the material of the IDT, and is formed using a thin film forming technique and a photography technique.

Fig. 1 shows the basic structure of such a typical SAW filter, which includes a piezoelectric plate 11, an input IDT electrode 12, an output IDT electrode 13, and absorbers 14-1 and 14-2.

First, the SAW filter shown in FIG. 1 is a typical transmission type SAW filter. The SAW filter having such a structure is mainly used as an intermediate frequency bandpass filter of a TV or a VCR or an intermediate frequency bandpass filter of a mobile communication device. .

The basic principle of the SAW filter is that when an electrical signal is applied to the input IDT electrode 12, the electrical energy is converted into mechanical energy by the piezoelectric effect of the piezoelectric plate 11, and a surface wave is generated. Proceeds in both directions of the electrode (12). At this time, the surface wave proceeding in one direction is absorbed by the absorber 14-1 provided on the input IDT electrode 12 side, and the surface wave propagating in the other direction is transmitted to the output IDT electrode 13. The output IDT electrode 13 detects the surface wave transmitted from the input IDT electrode 12 and receives it as a mechanical signal, and then converts it into an electrical signal and outputs it.

Meanwhile, the frequency characteristic implementation of the SAW filter 10 is determined by the structure of the input IDT electrode 12 and the output IDT electrode 13, and this electrode structure corresponds to the weighting time of the time impulse. The FFT (Fast Fourier Transform) in the form of frequency yields a frequency characteristic, and the sum of the convolutions of the frequency characteristics of the input IDT and the output IDT is the total frequency characteristic of the SAW filter 10. do.

On the other hand, the SAW filter 10 used as such an intermediate frequency filter generally performs impedance matching by using L and C coupling elements from the outside. In this case, when the SAW filter 10 performs impedance matching with an external circuit, the insertion loss of the filter is improved and the stopband attenuation is increased, thereby improving the characteristics of the filter.

In this regard, FIG. 2 is a diagram illustrating a circuit in which a SAW filter and an external circuit are matched, and illustrates a SAW filter for a TV including a SAW filter 10, a tuner 20, and an IC 30. do.

On the other hand, Figure 3 shows the characteristics of the ideal filter that does not include the physical properties (mechanical coupling coefficient, dielectric constant, etc.) and external circuit effects of the piezoelectric plate 11 in the intermediate frequency SAW filter 10 for TV or VCR as described above. The figure is shown in graph form. That is, the SAW filter 10 is designed such that the SAW filter 10 has the characteristics as shown in the same drawing when the initial filter is designed. In general, the piezoelectric substrate 11 includes 112 ° LiTaO 3, 128 ° LiNbO 3, Y-Z LiNbO 3, and quartz.

On the other hand, FIG. 4 is a diagram showing the characteristics of the filter when considering the physical properties of the piezoelectric plate 11 and considering the circuit for external impedance resistance, unlike in FIG. It can be seen that distortion occurs.

In this case, the frequency characteristics of the filter are different from those of a given filter and thus cannot be used in actual products. Therefore, when the SAW filter is actually mounted, it works together with the matching circuit components and other peripheral components, so it is necessary to design the characteristics of the filter to be obtained in consideration of the peripheral circuit and the matching circuit effect.

In view of this, conventionally, the characteristics of the SAW filter were adjusted by using a trial and error technique, that is, a method of fabricating a filter and then measuring the characteristic and correcting the characteristic by the difference in redesign.

However, the conventional method for compensating the characteristics of the SAW filter requires a time and a manpower for remanufacturing the filter, thereby reducing the productivity of the SAW filter 10.

Accordingly, the present invention has been made in view of the above-mentioned point, and by designing and manufacturing a SAW filter by compensating the characteristics of the SAW filter considering the mutual effect of the peripheral circuit and the external matching circuit in the initial design of the SAW filter, the actual external matching The purpose of the present invention is to provide a SAW filter considering an external matching circuit that can exhibit ideal filter characteristics when matched with a circuit.

According to an embodiment of the present invention, when a first electrical signal is applied to an input electrode, a surface wave is generated by converting the first electrical signal into a mechanical signal by a piezoelectric effect of a piezoelectric plate and outputting the same. A surface acoustic wave (SAW) filter for receiving a mechanical signal by the surface wave at an electrode and converting the mechanical signal into a second electrical signal to output a set frequency pass band, wherein the center frequency of the input electrode is fixed and the center of the output electrode is fixed. The frequency is set so that the upper frequency in the set frequency pass band is adjusted to be lower than the set value by a difference by a set value with respect to the center frequency of the input electrode.

1 shows the basic structure of a typical SAW filter;

2 exemplarily illustrates a circuit in which a SAW filter and an external circuit are matched;

3 is a view showing the characteristics of the ideal SAW filter that does not include the physical properties and external circuit effects of the piezoelectric plate,

4 is a view showing the characteristics of the SAW filter when considering the properties of the piezoelectric plate and the circuit for the external impedance resistance,

5 shows frequency characteristics for a uniform input IDT electrode;

6 shows frequency characteristics of an output IDT electrode;

7 is a diagram illustrating frequency characteristics of a SAW filter having compensated for a passband in consideration of an external matching circuit effect according to the present invention.

<Explanation of symbols for the main parts of the drawings>

11 piezoelectric plate 12 input IDT electrode

13: output IDT electrode 14-1, 14-2: absorber

Hereinafter, a SAW filter considering an external matching circuit according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, a key technical aspect of the present invention is to design and fabricate a SAW filter that compensates for the distortion characteristics of the filter in consideration of the mutual effect of the peripheral circuit matched with the actual SAW filter when designing the SAW filter. Is designed to characterize the ideal filter when matched with an external circuit.

Hereinafter, an SAW filter considering an external matching circuit according to the present invention will be described in detail by taking an intermediate frequency SAW filter for a TV or a VCR shown in FIG. 1 as an example.

Referring to FIG. 1 described above, the final frequency characteristic Hf (f) of the transmission type SAW filter shown in FIG. 1 is the frequency characteristic Hi (f) of the input IDT electrode 12 and the frequency of the output IDT electrode 13. It is calculated by the characteristic Ho (f) and the distance between these two electrodes, which is expressed by Equation (1).

Here, β = 2πλ = 2πf / v, λ = IDT electrode cycle, V = SAW speed, and d = distance between input / output IDT electrodes 12,13.

In general, in such an intermediate frequency SAW filter for TV / VCR, since the input IDT electrode 12 uses IDT having a constant electrode diameter, the frequency Hi (f) of the input IDT electrode 12 has a sin function characteristic as shown in FIG. 5. Therefore, the frequency Hf (f) of the final filter is determined by the frequency characteristic Ho (f) of the output IDT electrode 13 as shown in FIG.

Therefore, in the present invention, the input IDT electrode 12 is formed in a single shape and the output IDT electrode 13 is changed to the final filter so that the SAW filter 10 has an ideal filter characteristic when used in matching with an external matching circuit. Calculate the characteristic.

That is, as shown in FIG. 4, when the SAW filter is matched with an external circuit, distortion occurs at the top frequency of the final output frequency pass band Hf (f). Therefore, in order to compensate for this, the present invention is intended to fix the center frequency at Hi (f) of the input IDT electrode 12 and the center frequency at Ho (f) of the output IDT electrode 13 when designing the original SAW filter. When the SAW filter operates in line with the actual external circuit, the gap is set by the value set for the center frequency of (12) so that the upper frequency is adjusted lower than the set value in the frequency pass band Hf (f) which is the final filter output. The distortion of the top frequency is compensated for to achieve normal frequency passband characteristics.

In other words, since the frequency characteristic Hi (f) of the input IDT electrode 12 is constant, the frequency pass band Hf (f) of the final filter shown in FIG. 4 by optimizing the frequency characteristic Ho (f) of the output IDT electrode 13. In order to compensate for the amount of distortion), as shown in FIG. 7, the center frequency of the output IDT electrode 13 is changed so that Hf (f) is inclined slightly downward.

In this case, the inclination angle of the Hf (f), that is, the compensation angle, is appropriately between 1 ° and 2 ° in the case of the intermediate frequency SAW filter for TV / VCR, which is an inclination value calculated by an experiment. The inclination angle for compensation of the final frequency characteristic Hf (f) depends on the system and application frequency to which the SAW filter is applied, but in general, only 112 °, 128LN, and YZ-LN compensate only about 1 ° to 2 °. Thus, the present invention can be applied to both NTSC, PAL and SECAM SAW filters for TV / VCR and intermediate frequency SAW filters for mobile communication devices having a center frequency of 70 to 300 MHz.

On the other hand, in order to make the final filter characteristic incline than the set frequency characteristic, if the center frequency of the input IDT electrode 12 and the center frequency of the output IDT electrode 13 are slightly different, that is, each IDT electrode 12, 13 Adjust the period of) to be different from each other. Preferably, the present invention is more effective in tilting the upper frequency of the frequency pass band, which is the output of the final filter, by adjusting the center frequency ratio of the input IDT electrode 12 and the output IDT electrode 13 at 0.9965 to 0.997.

For example, in order to fabricate an NTSC intermediate frequency SAW filter having the characteristics as shown in FIG. 7, the center frequency of the input IDT electrode 12 is set to 43.6 MHz, and the center frequency of the output IDT electrode 13 is set. It is effective to set the final filter characteristic Hf (f) in the range of 1 ° to 2 ° as described above to set 43.75MHz with a difference of about 0.15MHz.

As described above, according to the present invention, in the initial design of the SAW filter, the characteristics of the SAW filter are compensated for in consideration of the mutual effects of the peripheral circuit and the external matching circuit, and then the SAW filter is designed and manufactured to match the actual external matching circuit. In this case, the SAW filter having the ideal filter characteristics can be designed and manufactured, and the time and manpower required for the SAW filter can be omitted by omitting the redesign process of the SAW filter according to the conventional trial and error technique. There is a saving effect.

Claims (3)

When the first electrical signal is applied to the input electrode, the piezoelectric effect of the piezoelectric plate converts the first electrical signal into a mechanical signal, thereby generating a surface wave, and receiving the mechanical signal by the surface wave at the output electrode to receive a second electrical signal. In the SAW (Surface Acoustic Wave) filter which converts the signal and outputs a set frequency pass band, The center frequency of the input electrode is fixed and the center frequency of the output electrode is designed to be adjusted so that the upper frequency is lower than the set value in the set frequency pass band by a difference by a value set for the center frequency of the input electrode. SAW filter considering external matching circuit. The SAW filter of claim 1, wherein the SAW filter is in a state of matching with an external connection circuit and the upper frequency is 1 ° to 2 ° lower than a set value in the frequency pass band. The SAW filter of claim 1, wherein the ratio of the center frequency of the output electrode to the center frequency of the input electrode is 0.9965 to 0.997.