阅读说明：本技术 滤波器和多滤波器 (Filter and multi-filter ) 是由 浦田知德 于 2020-02-18 设计创作，主要内容包括：滤波器,包括：形成于第一压电基板上的梯型滤波器单元；以及,与其连接,形成于与所述第一压电基板不同的第二压电基板上的多模式型滤波器单元；所述梯型滤波器及所述多模式型滤波器单元构成一个通带。(A filter, comprising: a ladder filter unit formed on the first piezoelectric substrate; and a multi-mode filter unit connected to the first piezoelectric substrate and formed on a second piezoelectric substrate different from the first piezoelectric substrate; the ladder filter and the multi-mode filter unit constitute a pass band.)

1. A filter, comprising:

a ladder-type filter unit formed on a first piezoelectric substrate, and a multi-mode-type filter unit connected thereto and formed on a second piezoelectric substrate different from the first piezoelectric substrate; the ladder type filtering unit and the multi-mode type filtering unit form a passband.

2. The filter of claim 1, wherein a thickness of electrodes constituting the ladder type filter unit is different from a thickness of electrodes constituting the multi-mode type filter unit.

3. The filter of claim 1 or 2, the corner cut of the first piezoelectric substrate being different from the corner cut of the second piezoelectric substrate.

4. The filter according to any one of claims 1 to 3, the first piezoelectric substrate having a thickness different from a thickness of the second piezoelectric substrate.

5. The filter of claim 4, the ladder filter cell comprising a plurality of resonators connected in a ladder;

the resonator includes an IDT electrode having a plurality of electrode fingers arranged at a pitch p;

the first piezoelectric substrate has a thickness of 2p or less.

6. The filter according to any one of claims 1 to 5,

the ladder-type filter unit is provided with a ladder-type filter unit,

a resonator having one end connected to the antenna terminal and including a plurality of electrode fingers arranged in a repeated pattern;

the thickness of the first piezoelectric substrate is less than 2 times of the distance between the electrode fingers in repeated arrangement;

further comprising a support substrate directly or indirectly connected to the first piezoelectric substrate.

7. A multi-filter comprising a first filter, a second filter and a third filter using the filter of any one of claims 1 to 6;

the center frequency of the pass band of the first filter takes a value between the center frequencies of the second filter and the third filter;

the first substrate or the second substrate is shared by the second filter or the third filter.

8. The multi-filter of claim 7, the second filter being a ladder filter sharing the first substrate.

9. The multi-filter according to claim 7 or 8, the third filter being a multi-mode type filter, sharing the second substrate.

Technical Field

The present disclosure relates to a filter using an elastic wave and a multi-filter including such a filter.

Background

An elastic wave device is known which applies a voltage to IDT (Interdigital transducer) electrodes on a piezoelectric body to generate an elastic wave propagating in the piezoelectric body. As filters using such IDT electrodes, for example, ladder filters and multimode filters are known.

Patent document 1 discloses an example in which a ladder type filter unit and a multimode type filter unit are combined as a reception filter. The ladder filter unit and the multi-mode filter unit are formed in the same substrate.

Documents of the prior art

Patent document

Patent document 1: japanese invention patent No. 5765502

Disclosure of Invention

A filter according to an aspect of the present disclosure includes: a ladder-type filter unit formed on a first piezoelectric substrate, and a multi-mode-type filter unit connected thereto and formed on a second piezoelectric substrate different from the first piezoelectric substrate; the ladder filter unit and the multi-mode filter unit constitute a pass band.

A multi-filter according to an aspect of the present disclosure includes: a first filter, a second filter and a third filter using the above filters; a center frequency of a pass band of the first filter takes a value between center frequencies of the second filter and the third filter, and the first substrate or the second substrate is shared by the second filter or the third filter.

Drawings

Fig. 1 is a diagram showing a schematic configuration of a filter according to an embodiment.

Fig. 2(a) to 2(d) are graphs showing the correlation between the electrode thickness and the electrical characteristics.

Fig. 3 is a block diagram showing a schematic configuration of a multi-filter according to the embodiment.

Fig. 4 is a top view of the multiple filter shown in fig. 3.

Fig. 5 is a cross-sectional view showing a main part of a modification of the filter shown in fig. 1.

Detailed Description

Hereinafter, the technology of the present disclosure will be clarified by explaining specific embodiments of the technology of the present disclosure with reference to the drawings.

[ Filter 1]

Fig. 1 shows a schematic diagram of a filter 1. The filter 1 comprises a ladder filter element 3 and a multi-mode filter element 5 between terminals 11 and 12. In this example, the ladder type filter unit 3 and the multi-mode type filter unit 5 are connected in series to form one pass band.

The ladder filter unit 3 includes: series resonators S1 to S3 connected in series, and parallel resonators P1 to P2 connected in parallel between these series resonators S1 to S3 and a reference potential. In addition, in the ladder filter unit 3, the series resonators S and the parallel resonators P only need to be ladder-connected, and the number, size, and the like of each resonator can be freely selected according to the desired characteristics.

In this example, the multimode-type filter unit 5 includes a DMS (Double Mode SAW) type filter 51. In this example, the DMS-type filter 51 is an unbalanced-type filter, but it may be a filter having a balun function. Further, a plurality of DMS-type filters 51 may be included, or a front stage or a rear stage of the DMS-type filters 51 may be connected with the resonator 53, or an inductor or the like may be connected.

Each filter unit applies a voltage to an IDT (interdigital transducer) electrode on the piezoelectric substrate to generate an elastic wave propagating in the piezoelectric body, resulting in filter characteristics. The IDT electrode is formed by patterning a conductor layer (metal layer), and is made of, for example, Al or an Al alloy. The IDT electrode may be formed of a laminate in which a plurality of different conductor layers are laminated.

Such IDT electrodes include a pair of comb-tooth electrodes. A pair of comb-teeth electrodes, each having a plurality of electrode fingers (corresponding to comb teeth), are arranged to mesh with each other. A standing wave of the elastic wave having twice the pitch p of the electrode fingers as a wavelength is formed, and the frequency of the standing wave becomes a resonance frequency. The ladder type filter unit 3 has a pass band formed of a resonance frequency and an antiresonance frequency, and the multi-mode type filter unit 5 has a pass band formed of a resonance frequency.

Thus, when the filter 1 includes the ladder type filter unit 3 and the multi-mode type filter unit 5, it can be a filter having advantages of both filters. That is, the filter 1 can have a wide frequency band and excellent attenuation characteristics.

In order to further improve the characteristics of such a filter 1, in the filter 1 of the present disclosure, the ladder type filter unit 3 and the multimode type filter unit 5 are formed on different piezoelectric substrates. Specifically, the ladder type filter unit 3 is formed on the first piezoelectric substrate 35, and the multi-mode type filter unit 5 is formed on the second piezoelectric substrate 55. In fig. 1, a portion formed on the same piezoelectric substrate is surrounded by a dotted line. The first piezoelectric substrate 35 and the second piezoelectric substrate 55 may be different substrates, but may be different in material, corner cut, and film thickness.

Fig. 2 shows the relationship between the electrode thickness and the loss of the resonator when a lithium tantalate substrate (hereinafter, LT substrate) is used. Fig. 2(a) and 2(b) are simulation results when an LT substrate with a chamfer angle of 42 ° is used as the piezoelectric substrate, and fig. 2(c) and 2(d) are simulation results when an LT substrate with a chamfer angle of 46 ° is used as the piezoelectric substrate. Fig. 2(a) and 2(c) show the dependence between the loss at the resonant and anti-resonant frequencies and the electrode thickness. Fig. 2(b) and 2(d) are graphs showing the correlation between the average value of the loss between the resonance frequency and the antiresonance frequency and the electrode thickness. In each figure, the horizontal axis represents the thickness of the electrode (unit: λ) and the vertical axis represents the loss (unit: dB).

As is clear from fig. 2, the resonant frequency and the anti-resonant frequency of the electrode thickness with the least loss are also different and vary with the cutting angle. Here, the ladder filter unit 3 selects an electrode thickness that minimizes the average value of the losses at the resonance frequency and the antiresonance frequency so that the losses at both the resonance frequency and the antiresonance frequency constituting the pass band are low. On the other hand, the multi-mode filter unit 5 selects an electrode thickness that reduces the loss at the resonance frequency constituting the pass band. Therefore, in order to improve the characteristics of each of the two filter cells, the optimal thickness of the electrodes between the two filter cells is different, but in order to achieve this on one substrate, a plurality of electrode films must be formed on the same substrate, and there is a risk of a decrease in productivity. In contrast, according to the present disclosure, by disposing the respective filter units 3 and 5 on different substrates, the electrode thicknesses between the two filter units 3 and 5 can be made different without complicating the manufacturing process, so that the filter 1 with high productivity can be provided.

Further, since the resistance value of the wiring decreases with an increase in the thickness of the electrode, the insertion loss can be improved by increasing the thickness of the electrode within a range not less than a decrease in the loss of the resonance characteristic due to the optimum thickness. This tendency is the same even when the chamfer of the piezoelectric substrate is different. Therefore, in order to increase the electrode thickness, the ladder filter unit 3 can increase the chamfer of the piezoelectric substrate (first piezoelectric substrate 35) on which the ladder filter unit 3 is disposed. In this case, the chamfer of the first piezoelectric substrate 35 may be larger than the chamfer of the second piezoelectric substrate 55. For example, an LT substrate having a Y-X cut angle of 46 ° to 50 ° may be used as the first piezoelectric substrate 35, and an LT substrate having a Y-X cut angle of 41 ° to 43 ° may be used as the second piezoelectric substrate 55.

In addition, in the ladder filter, if the stop band on the high frequency side of the antiresonant frequency is located in or near the pass band, both the insertion loss and the steepness are lowered. Here, by increasing the thickness of the electrode film and changing the electrode finger pitch of the IDT electrode, the stop band can be moved to the high frequency side. From this point of view, the corner cut of the first piezoelectric substrate 35 used in the ladder filter unit 3 may be larger than the corner cut of the second piezoelectric substrate 55, and the electrode film thickness may also be increased. By using this method, the insertion loss and the decrease in steepness of the ladder filter can be reduced. Further, even when the chamfer of the piezoelectric substrate is different, it can be confirmed that such a tendency is the same.

In this way, it is possible to enable the ladder filter unit 3 to adjust the electrical characteristics by increasing the electrode thickness. Therefore, in order to increase the electrode thickness, the chamfer of the piezoelectric substrate (first piezoelectric substrate 35) on which the ladder filter unit 3 is arranged can be increased. In this case, the chamfer of the first piezoelectric substrate 35 may be larger than the chamfer of the second piezoelectric substrate 55. For example, an LT substrate having a Y-X cut angle of 46 ° to 50 ° may be used as the first piezoelectric substrate 35, and an LT substrate having a Y-X cut angle of 41 ° to 43 ° may be used as the second piezoelectric substrate 55.

In this way, by forming the ladder type filter unit 3 and the multimode type filter unit 5 on different piezoelectric substrates, the characteristics of each of the filter units 3 and 5 can be enhanced, and as a result, the filter 1 excellent in electrical characteristics can be provided.

The ladder filter unit 3 and the multimode filter unit 5 may be electrically connected by a wiring provided on a mounting substrate on which the first piezoelectric substrate 35 and the second piezoelectric substrate 55 forming them are mounted.

[ multiple filters 100]

Fig. 3 is a circuit diagram showing one example of the multi-filter 100 of the present disclosure, and fig. 4 is a top schematic view of the multi-filter 1 shown in fig. 3.

The multi-filter 100 includes an antenna terminal 120, input/output terminals 130A to 130D, and first to fourth filters F1 to F4 having different pass bands from each other. In a path of each of the four paths of the antenna terminal 120 and each input/output terminal 130, one of the first filter F1 to the fourth filter F4 is connected. In other words, the multi-filter 100 is a so-called multiplexer, and the first filter F1 to the fourth filter F4 are connected in parallel in common to the antenna terminal 120.

Assuming that the center frequencies of the pass bands of the first filter F1 through the fourth filter F4 are F1, F2, F3, and F4, respectively, F1 takes a value other than the maximum value and the minimum value thereof. In this example, the relationship of f2< f1< f4< f3 is satisfied.

The types of the filters of the first filter F1 to the fourth filter F4 are not particularly limited, and filters using the frequency band of the elastic wave may be used. In this example, the first filter F1 and the second filter F2 constitute a reception filter and a transmission filter of one frequency band, and the third filter F3 and the fourth filter F4 constitute a reception filter and a transmission filter of another frequency band.

Filter 1 shown in fig. 1 is used as first filter F1. Specifically, the first terminal 11 of the filter 1 is electrically connected to the antenna terminal 120, and the second terminal 12 is electrically connected to the input/output terminal 130A.

The second filter F2 and the fourth filter F4 are transmission filters composed of ladder filters. The third filter F3 is a reception filter formed by combining a ladder filter and a vertical coupling filter (DMS). In this example, the third filter F3 has the same configuration as the first filter F1, but may be configured of only a ladder filter or may not include only a DMS filter or only a DMS filter and a resonator.

In such first to fourth filters F1 to F4, the first filter F1 is constituted by a substrate divided into two pieces, and these divided substrates are shared by any of the other filters F2 to F4. Specifically, as shown in fig. 4, the ladder filter cell 3 of the first filter F1 is integrally configured with the second filter F2 on the same substrate. That is, a resonator group constituting the ladder filter unit 3 and the second filter F2 is formed on the first piezoelectric substrate 35. The first piezoelectric substrate 35 is a LT substrate with a 46 DEG Y-X cut angle, and the thickness of the conductor layer between the ladder filter unit 3 and the resonator group constituting the second filter F2 is set to be

Similarly, the multimode filter unit 5 of the first filter F1 is integrally formed on the same substrate as the third filter F3. That is, a resonator group constituting the multimode filter unit 5 and the third filter F3 is formed on the second piezoelectric substrate 55. The second piezoelectric substrate 55 is a LT substrate with a 42 ° Y-X cut angle, and the thickness of the conductor layer between the resonator group constituting the multimode filter unit 5 and the third filter F3 is set to be 42 °

The fourth filter F4 is formed on the piezoelectric substrate 140 different from the first piezoelectric substrate 35 and the second piezoelectric substrate 55. The piezoelectric substrate 140 uses an LT substrate with a 46 ° Y-X cut angle, similarly to the second piezoelectric substrate 55. The thickness of the conductor layer constituting the resonator group of the fourth filter F4 is set to be

The first piezoelectric substrate 35, the second piezoelectric substrate 55, and the piezoelectric substrate 140 are mounted on the mounting substrate 150, and the filters are electrically connected to each other through a wiring formed on or inside the mounting substrate 150, whereby the multi-filter 100 can be provided. The first piezoelectric substrate 35, the second piezoelectric substrate 55, and the piezoelectric substrate 140 are formed so that the surface on which the filter electrode is formed faces the mounting substrate 150. In the figure, the regions surrounded by the broken lines indicate regions where electrodes corresponding to the filters are formed on the piezoelectric substrates.

With such a configuration, 4 filters can be realized in 3 chips (3 piezoelectric substrates), and thus the multi-filter 100 can be miniaturized. Further, if one filter is divided into two substrates, the size of each substrate becomes small, and the processing becomes difficult; however, as described above, the multi-filter 100 can be provided with a high throughput by sharing the substrate with another filter to ensure a single chip size.

Further, in this example, among the first to fourth filters F1 to F4, the ladder type filters are grouped on the same substrate, and the DMS type filters are grouped on the same substrate. Thereby, the optimum electrode layer thickness and piezoelectric substrate can be selected for each filter. This makes it possible to improve the electrical characteristics of the individual filters.

In addition, in this example, the resonator group of the second filter F2 is formed on the first piezoelectric substrate 35 of the ladder filter unit 3, but a resonator group of the fourth filter F4 may be formed. Further, a resonator group of the second filter F2 and a resonator group of the fourth filter F4 may be formed on the first piezoelectric substrate 35.

Further, in this example, the ladder filter is disposed together on the first piezoelectric substrate 35, and the DMS filter is disposed together on the second piezoelectric substrate 55. This allows the optimum electrode thickness and substrate to be selected for each filter type. In this example, since the third filter F3 is also a filter in which the ladder filter and the DMS filter are combined to form one passband, only the DMS filter cells of the third filter F3 may be provided on the second piezoelectric substrate 55, and the ladder filter cells may be provided on the first piezoelectric substrate 35 and the piezoelectric substrate 140.

[ modified examples ]

In the above example, although the description has been made of the case where a single substrate is used for both the first piezoelectric substrate 35 and the second piezoelectric substrate 55, it is also possible to reduce the thickness of the first piezoelectric substrate 35 and the second piezoelectric substrate 55 and attach another support substrate. Fig. 5 is an enlarged cross-sectional view of a main portion of the filter 1A.

In fig. 5, the first piezoelectric substrate 35 is thin, and a support substrate 37 is directly or indirectly disposed on a surface of the first piezoelectric substrate that faces the ladder filter unit 3. The support substrate 37 is not particularly limited as long as it has strength capable of supporting the first piezoelectric substrate 35; for example, when a material having a linear expansion coefficient smaller than that of the first piezoelectric substrate 35 is used, deformation of the first piezoelectric substrate 35 due to temperature change can be suppressed, and the temperature compensation effect can be improved. In this case, the thickness of the first piezoelectric substrate 35 may be 20 λ or less with λ as a reference.

Further, when the thickness of the first piezoelectric substrate 35 is less than 1 λ, leakage of the elastic wave in the substrate thickness direction can be suppressed, the elastic wave is confined in the first piezoelectric substrate 35, and as a result, a low-loss filter can be provided. In this case, between the first piezoelectric substrate 35 and the support substrate 37, an acoustic multilayer film formed by alternately laminating low sound velocity films and high sound velocity films may be interposed, and a bonding layer made of an insulating material such as silicon oxide may be interposed, for example. Further, in the ladder filter unit 3, in order to suppress the influence of bulk wave spurious, a material having a higher acoustic velocity than the first piezoelectric substrate 35 may be used as the support substrate 37. Examples of the material of such a support substrate 37 include AlN, silicon nitride, a sapphire substrate, and a Si substrate.

On the other hand, the second piezoelectric substrate 55 is a normal LT substrate, and a support substrate or the like is not inserted on the lower surface thereof.

Thus, the thickness of the first piezoelectric substrate 35 and the thickness of the second piezoelectric substrate 55 are different for the filter 1A. The first piezoelectric substrate 35 and the second piezoelectric substrate 55 are mounted on a mounting substrate 70 such that the side on which the IDT electrodes are formed faces downward. The ladder filter unit 3 and the multi-mode filter unit 5 are electrically connected by a wiring pattern 71 located inside the substrate 70. Thereby, the filter units 3 and 5 can be used as the filter 1A. Further, by ensuring that the path of wiring pattern 71 is longer than the line segment for linearly connecting ladder filter section 3 and multimode filter section 5 in substrate 70 in the perspective plan view, wiring pattern 71 can also function as an inductor. In this case, the pass band of the filter 1A can be extended. Further, the wiring pattern 71 may be located on the upper surface (mounting surface) of the substrate 70. Further, in this example, the first piezoelectric substrate 35 and the second piezoelectric substrate 55 are mounted on the mounting substrate 70 via the mounting bumps 72, but is not limited thereto.

According to the filter 1A, the electric characteristics with suppressed loss can be obtained in the filter unit (i.e., the ladder filter unit 3) on the side to which the antenna terminal 120 is connected. Here, as shown in fig. 3, when a plurality of filters are commonly connected to the antenna terminal 120, the characteristic of the resonator located at the position closest to the antenna terminal 120 is related to the insertion loss of the other filters. For this reason, by forming the ladder filter unit 3 including the resonators close to the antenna terminal 120 on the composite substrate including the first piezoelectric substrate 35 having a thin thickness and the support substrate 37 for supporting it, it is possible to provide a multi-filter having good temperature characteristics and reduced insertion loss.

As can be seen from the above, in the multi-filter 100 shown in fig. 3, the composite substrate including the first piezoelectric substrate 35 that is thinned can form a resonator group of a filter having a small interval between adjacent pass bands. In this case, the frequency fluctuation of the filter can be suppressed, and a highly reliable multi-filter can be obtained.

In addition, in the above example, only the case where the first piezoelectric substrate 35 is thinned is described as an example, but the second piezoelectric substrate 55 may also be thinned.

[ modified examples ]

The materials of the first piezoelectric substrate 35 and the second piezoelectric substrate 55 may be different. For example, one may be an LT substrate and the other may be a Lithium Niobate (LN) substrate.

Further, when the ladder filter unit 3 is located directly below the antenna terminal 120, the cut angle of the piezoelectric crystal constituting the first piezoelectric substrate 35 may be larger than that of the second piezoelectric substrate 55. In this case, the electrode thickness of the ladder filter unit 3 can be increased, so that the power resistance can be improved.

Further, in the above example, only the case where the first piezoelectric substrate 35 is thinned is described as an example, but the second piezoelectric substrate 55, the piezoelectric substrate 140 may be thinned.

Description of the symbols

1 … filter, 3 … ladder type filter unit, 5 … multimode type filter unit, 35 … first piezoelectric substrate, 55 … second piezoelectric substrate.