JP2009060412A - Elastic wave filter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an elastic wave filter capable of coping with various bands, while having versatility. <P>SOLUTION: The elastic wave filter 1 includes inclination type IDTs 12, 13 on an input side and an output side on a piezoelectric substrate 11, where the pitches of electrode fingers 16a-16d, 19 are enlarged in a direction to be orthogonally crossed with the propagation direction of the elastic save. For example, the inclination type IDT 12 on the input side is divided into a plurality of inclination type IDT blocks 12a-12d in the direction to be orthogonally crossed with the propagation direction of the elastic wave, which are mutually connected. The block to be used is selected from among these inclination type IDT blocks 12a-12d. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention is provided with an inclined IDT in which the pitch of electrode fingers varies particularly in the direction orthogonal to the propagation direction of elastic waves, among IDTs (Interdigital Transducers) used for excitation of SAW (Surface Acoustic Wave) and the like. The present invention relates to an elastic wave filter.

  An elastic wave filter that is mounted on a mobile terminal such as a mobile phone and discriminates a high-frequency signal employs, for example, an elastic wave filter using SAW transmitted on the surface of the elastic body. A device having an electrode having a slope in which the pitch of electrode fingers spreads along a direction orthogonal to the propagation direction is known. FIG. 7 shows an example of a two-port SAW filter 100 that is one of such elastic wave filters. The SAW filter 100 includes, for example, a piezoelectric substrate 101 on which SAW propagates and a piezoelectric substrate 101 on the piezoelectric substrate 101. The input side IDT 102 and the output side IDT 103 are spaced from each other in the SAW propagation direction.

  Of these IDTs 102 and 103, for example, the input-side IDT 102 has a configuration in which a large number of electrode fingers 105 extend from each of a pair of bus bars 104 formed so as to be parallel to each other. The bus bar 104 is connected to a frequency signal input port 106, and the other bus bar 104 is grounded. When a frequency signal is input to the input port 106, an elastic wave having a frequency corresponding to the signal is excited between the electrode fingers 105, and this elastic wave propagates on the piezoelectric substrate 101 toward the output side IDT 103. Is configured to do. On the other hand, the output side IDT 103 has the same configuration as that of the input side IDT 102 except that one side of the bus bar 104 is connected to the output port 107, and the elastic wave propagated from the input side IDT 102 is mechanically / electrically converted. Are output from the output port 107.

  Further, the SAW filter 100 shown in FIG. 7 has a characteristic as a bandpass filter, and the width of each electrode finger 105 provided in the IDTs 102 and 103 is the propagation direction of the elastic wave (left and right X direction in FIG. 7). It is configured to gradually become wider (or narrower) along the direction perpendicular to (Y direction). Also, the interval between the adjacent electrode fingers 105 is gradually increased along the direction perpendicular to the propagation direction of the elastic wave, in the same manner as the width of the electrode fingers 105 described above. With such a configuration, the electrode fingers 105 provided in the IDTs 102 and 103 have different inclinations as shown in FIG. 7, and the inclined IDTs 102 and 103 are formed in a fan shape as a whole.

  The IDTs 102 and 103 each have the structure described above, so that the width of the electrode fingers 105 and the interval between the electrode fingers 105 (hereinafter collectively referred to as the electrode fingers 105 adjacent in the elastic wave propagation direction). At the position “a” where the distance between the centers of the signals is wide), electro-mechanical conversion between a signal having a low frequency corresponding to the pitch and SAW is performed, and at the position “a”, the position “a” The highest frequency signal is converted at the position of “c”. As a result, as shown in FIG. 8B, the SAW filter 100 has a frequency transfer characteristic that allows a frequency signal corresponding to each position of “a, i, c” to pass therethrough. Further, as described above, since the pitch of each electrode finger 105 continuously changes in the Y direction, the SAW filter 100 is shown in FIG. 8C when viewed from the position “A” to the position “U”. As shown in the figure, the band-pass filter allows the frequency signal to pass in a wide band from the lowest frequency corresponding to the position of “A” to the highest frequency corresponding to the position of “U”. 8B and 8C, the horizontal axis indicates the frequency [MHz] of the frequency signal input to the SAW filter 100, and the vertical axis indicates the amplitude level [of the frequency signal that has passed through the SAW filter 100]. dB].

  By the way, it is expected that a mobile terminal equipped with such a SAW filter 100 will be provided with various functions in the future, and the functions of the SAW filter 100 will be required to be diversified. It is done. For example, in a technique called seamless roaming, a mobile terminal that moves with a user searches for a network that can be used at that position, such as a mobile phone network or a wireless LAN, and switches to an appropriate network. If the frequency signal bands used in each network are greatly different when switching between such networks, for example, the SAW filter 100 corresponding to each frequency band must be prepared. This has the problem that various types of filters must be prepared, matching circuits corresponding to these SAW filters must be prepared and assembled as chips, and process management is complicated.

In Patent Document 1, in a 2-port SAW filter, the output side is composed of a tilted IDT, and a plurality of strip-like electrodes that are elongated in the horizontal direction between the IDTs on the input side and the output side are arranged at a pitch of the tilted IDT. An elastic wave filter is described which is arranged in a direction in which the voltage changes (Y direction in FIG. 7) and a bias voltage can be applied to each strip electrode. The elastic wave filter is configured to change the usable bandwidth by changing the bias voltage applied to each band electrode and changing the insertion loss between the IDTs at the position where each band electrode is provided. Yes. However, if a technique for changing the insertion loss by applying a bias voltage in this way is adopted, the power consumption of the filter increases, so that it is not practical to be mounted on a mobile terminal that requires low power consumption.
JP-A-61-94411: page 40, lower row, right 2nd row to page 41, upper row, left 5th row, page 41 upper row, right, 9th row to 14th row, FIG.

  The present invention has been made based on such circumstances, and an object of the present invention is to provide an elastic wave filter capable of dealing with various bands while having versatility.

An elastic wave filter according to the present invention is an elastic wave filter in which inclined IDTs in which the pitch of electrode fingers is increased along a direction orthogonal to the propagation direction of elastic waves are provided on the input side and the output side on a piezoelectric substrate. In
One of the input-side inclined IDT and the output-side inclined IDT is divided into a plurality of inclined IDT blocks along a direction orthogonal to the propagation direction of the elastic wave, and the plurality of inclined IDT blocks are parallel to each other. Connected and
It is characterized by being configured so that a combination of inclined IDT blocks to be used can be selected from the plurality of inclined IDT blocks.
The elastic wave filter is preferably provided corresponding to each of the plurality of inclined IDT blocks and includes a switch unit for enabling or disabling the corresponding inclined IDT block.

  In addition, the above-described elastic wave filter includes a plurality of matching circuits having matching impedances according to combinations of inclined IDT blocks, and a matching circuit corresponding to a combination of inclined IDT blocks selected from the plurality of matching circuits. And a matching circuit selection means for connecting to the selected inclined IDT block, and further, the amplitude level of the intersection of the frequency transfer characteristics of the adjacent inclined IDT blocks However, it is preferable to be 2.5 dB to 3.5 dB (3.0 dB plus or minus 0.5 dB) lower than the average value of the amplitude level of the pass band of these inclined IDT blocks. Here, the phases of the transfer characteristics at the intersections of the adjacent IDT blocks are in phase with each other.

  According to the present invention, a plurality of inclined IDTs having different passbands are connected in parallel to one side of the elastic wave propagation direction in the elastic wave filter, and predetermined from the plurality of inclined IDTs. Since the configuration is such that the combined inclined IDT can be used, one device can be used as a plurality of types of filters having different passbands and bandwidths. Therefore, the burden on the maker side required for process management or the like can be reduced as compared with the case where a plurality of acoustic wave filters meeting each specification are manufactured and mounted.

First, the configuration of the SAW filter 1 according to the present embodiment will be described with reference to the configuration diagram of FIG. As shown in FIG. 1, the SAW filter 1 includes a filter unit 10 constituting a filter body and a selection unit 2 for selecting a pass band of the SAW filter 1. The filter unit 10 includes, for example, a piezoelectric substrate 11 made of a piezoelectric material such as quartz, LiTaO _3, or LiNbO ₃ , and an input-side IDT 12 that is patterned on the surface of the piezoelectric substrate 11 by, for example, photolithography and is made of, for example, aluminum Side IDT13. In the following description, the upper side is described as the front side and the lower side as the rear side in the drawings.

  As shown in FIGS. 1 and 2A, the input side IDT 12 according to the present embodiment includes a plurality of conventional input side IDTs 102 (see FIG. 7) described in the background art from the front side to the rear side. The structure is divided into four parts, for example. The configuration of the input side IDT 12 will be described in detail. The input side IDT 12 is composed of four inclined IDT blocks 12a to 12d. These inclined IDT blocks 12a to 12d convert the conventional inclined IDT into an elastic wave. It has a trapezoidal inclined IDT electrode structure formed by dividing into a plurality of directions in a direction orthogonal to the propagation direction. Among the four inclined IDT blocks 12a to 12d, for example, the foremost inclined IDT block 12a has a plurality of electrode fingers 16a extending from each of a pair of bus bars 14a and 15a formed in parallel to each other in the shape of cross fingers. It has a known structure and has a well-known IDT structure. Of the pair of bus bars 14a and 15a, the front side is an input side bus bar 14a to which a frequency signal is input, and the rear side is a ground side bus bar 15a that is grounded.

  Similarly to the conventional input side IDT 102, the inclined IDT block 12a is also configured as an inclined IDT for a bandpass filter, and the distance between the centers of adjacent electrode fingers 16a (as viewed from the propagation direction of the elastic wave) ( The pitch of the electrode fingers 16a is gradually increased from the front side to the rear side, that is, along the direction perpendicular to the propagation direction of the elastic wave. As a result, the inclined IDT block 12a forms a band filter having a frequency transfer characteristic indicated by the reference numeral “3a” in FIG. 2B with the output side IDT 13 described later. .

  The inclined IDT blocks 12b to 12d arranged on the rear side also have an IDT structure substantially the same as the inclined IDT block 12a described above, but the inclined IDT blocks 12b to 12d are output IDTs 13 respectively. The pitch of the electrode fingers 16b to 16d is already set so as to constitute a bandpass filter having a frequency transfer characteristic indicated by the reference numerals “3b to 3d” in FIG. This is different from the inclined IDT block 12a described above.

  These four inclined IDT blocks 12a to 12d are such that the bus bars 14a to 14d and 15a to 15d are parallel to each other, and the inclined IDT block 12a having a higher pass band is the foremost, and the pass band is sequentially lower. Inclined IDT blocks 12b to 12d are arranged so as to be on the rear side. The ground-side bus bars 15a to 15d are connected by a bus bar connection line 151 and connected at a common ground point. As shown in FIG. 2A, the pitch of the electrode fingers 16a to 16d between the adjacent inclined IDT blocks 12a to 12d is also adjusted based on a predetermined rule in relation to the function of the selection unit 2. The details will be described later.

  While the input side IDT 12 has such a configuration, the output side IDT 13 has the same configuration as the conventional output side IDT 103 described with reference to FIG. 7, and 17 is a bus bar ( The output-side bus bars 17) and 18 are grounded bus bars (ground-side bus bar 18), and 19 are electrode fingers extending from these bus bars 17 and 18 in the shape of cross fingers. The output side IDT 13 is spaced from the input side IDT 12 in the elastic wave propagation direction, and the electrode fingers 19 are formed in areas where the elastic waves from the inclined IDT blocks 12a to 12d propagate. is there. Reference numeral 25 denotes an output port from which a frequency signal is output.

  Next, the selection unit 2 will be described. Each inclined IDT block 12a to 12d is connected in parallel between the signal line of the frequency signal and the ground, and includes four inclined IDT blocks 12a to 12d. Each channel is provided with a first switch SWa to SWd that constitutes a switch unit, and by turning on these first switches SWa to SWd, the corresponding inclined IDT blocks 12a to 12d are connected to the signal line. Also, when the first switches SWa to SWd are turned off, they are separated from the corresponding inclined IDT blocks 12a to 12d and become invalid. Accordingly, these first switches SWa to SWd serve to select combinations of the inclined IDT blocks 12a to 12d.

  As for the first switches SWa to SWd, the on / off states of the first switches SWa to SWd are installed on the manufacturer side according to the application to which the SAW filter 1 according to the present embodiment is applied. That is, the states of the first switches SWa to SWd are set so as to be a combination of the inclined IDT blocks 12a to 12d that can obtain the target filter characteristics (pass band and attenuation band).

  Further, a matching circuit 22 and second switches SW1 to SW10 forming a matching circuit selection unit are provided between the confluence on the input side of the four channels and the input port 24 where the frequency signal is input to the SAW filter 1. Are connected in series. Each matching circuit 22 has an impedance corresponding to the combination of the inclined IDT blocks 12a to 12d selected by the first switches SWa to SWd described above, and the second switches SW1 to SW10 in each series circuit are connected. By turning on, the matching circuit 22 included in the series circuit is connected to the signal line, and by turning off the second switches SW1 to SW10, the matching circuit 22 included in the series circuit is disconnected from the signal line. As shown in FIGS. 3 and 4 to be described later, when combining the tilted IDT electrodes 12a to 12d so as to obtain a filter characteristic having a continuous pass band, there are 10 combinations of four blocks. For example, ten matching circuits 22 are prepared. Then, the matching circuit 22 corresponding to the selected combination of the inclined IDT blocks 12a to 12d is selected by the second switches SW1 to SW10. The selection unit 22 includes the first switches SWa to SWd, the second switches SW1 to SW10, and the matching circuit 22 described above.

  Next, the operation of the SAW filter 1 according to the embodiment having the above configuration will be described. Now, it is assumed that the pass band of the SAW filter 1 has a full width of 36 MHz, a center frequency of 144 MHz, a specific band of 25% (= (36 MHz / 144 MHz) × 100%) (see FIG. 5D), and each inclined IDT block 12a. ˜12d has a pass band of approximately 9 MHz, which is obtained by dividing the above-described full width of 36 MHz into four. At this time, the slope type IDT block 12d provided at the rear of the filter unit 10 is made usable by using the first switches SWa to SWd, and the frequency signal is sent through the matching circuit 22 according to the selection result. When input from the input port 24, a band-pass filter is formed between the inclined IDT block 12d and the output side IDT 13, and the frequency transfer characteristic 3d shown in FIG. 3A is obtained. Similarly, when the inclined IDT block of “12c, 12b, 12a” and the matching circuit 22 corresponding thereto are selected and a frequency signal is input, the frequencies shown in FIGS. 3B to 3D, respectively. Transfer characteristics 3c to 3a are obtained, respectively, and a total of four types of band-pass filters having different pass bands can be switched and used.

  Next, for example, when the frequency signal is input by selecting the two inclined IDT blocks 12c and 12b and the matching circuit 22 corresponding to this combination, between the two inclined IDT blocks 12c and 12b and the output side IDT 13 A band-pass filter is formed, and a frequency transfer characteristic obtained by synthesizing the above-described frequency transfer characteristics 3c and 3b can be obtained as shown in FIG.

  Here, in the SAW filter 1 according to the present embodiment, as shown in FIG. 4A, a frequency transfer characteristic 3c (first frequency transfer) formed by the inclined IDT block 12c and having a pass band on the low frequency side. Characteristic) is formed by the first shoulder portion 31 that is a region where the amplitude level is abruptly attenuated (the amount of attenuation increases) on the high frequency side from the pass band, and the inclined IDT block 12c, and is formed on the high frequency side. Each frequency transfer characteristic 3c includes a second shoulder portion 32, which is a region where the amplitude level abruptly attenuates on a lower frequency side than the pass band of the frequency transfer characteristic 3c (second frequency transfer characteristic) having a pass band. It intersects at point A, which is an amplitude level that is approximately 3 dB smaller than the amplitude level of the passband of 3b (the average value if these values are different).

Here, when the amplitude level “a _i ” at the intersection point A between the first shoulder portion 31 and the second shoulder portion 32 is 3 dB lower than the amplitude level “a _t ” of the passband, the output signal at the intersection point The power is half that of the output signal in the passband. Therefore, when the output signals that have passed through the two IDTs of the inclined IDT blocks 12c and 12b are added at the frequency of the intersection, an amplitude level substantially equal to the output signal from the passband is obtained, as shown in FIG. A band-pass filter having a combined frequency transfer characteristic 30a and a bandwidth of about 18 MHz is formed.

Here, the position of the intersection A with the first shoulder portion 31 and the second shoulder portion 32 shown in FIG. 4A is (1) the difference in frequency at which the attenuation of the amplitude level starts, that is, FIG. The horizontal distance between the point B and the point C shown in (2), and (2) the inclination of the first shoulder portion 31 and the second shoulder portion 32 are determined. Among these elements, the frequency difference between points B-C is determined by the pitch “d ₃ ” of the electrode finger 16b at the rear end position of the inclined IDT block 12b shown in FIG. The inclination of the first shoulder portion 31 and the second shoulder portion 32 is determined by the difference from the pitch “d ₄ ” of the electrode fingers 16 c at the tip position, and the electrode fingers 16 b in the intersecting regions of the inclined IDT blocks 12 c and 12 b It is known that it is determined by the number of 16c.

Therefore, the inclined IDT blocks 12c and 12b in the present embodiment are configured so that the amplitude level “a _i ” at the intersection A shown in FIG. 4A is smaller than the amplitude level “a _t ” of the passband by about 3 dB. The value of the pitch “d ₃ , d ₄ ” between the electrode fingers 16 c and 16 b and the number of electrode fingers 16 b and 16 c are designed. Note that “approximately 3 dB” means that the difference between the amplitude level of the point A and the amplitude level of the passband depends on the ripple (maximum value of the difference between the maximum value of attenuation in the passband and the minimum loss). This means that there may be no problem in practical use of the SAW filter 1 even in a range as low as 2.5 dB to 3.5 dB (3.0 dB plus or minus 0.5 dB).

  Then, similarly to the relationship between the tilted IDT blocks 12b and 12c described above, the four tilted IDT blocks 12a to 12d according to the present embodiment have a frequency transfer characteristic 3a between the adjacent tilted IDT blocks 12a to 12d. In ~ 3c, the first shoulder portion 31 and the second shoulder portion 32 are designed to intersect at a position 3 dB smaller than the amplitude level of the passband. For this reason, as shown in FIG. 4C, the frequency transfer characteristics 3c and 3d are combined to form a band filter (bandwidth of about 18 MHz) having the combined frequency transfer characteristic 30b shown in FIG. FIG. 5A shows a combined frequency transfer characteristic 30c (bandwidth of about 27 MHz) obtained by combining the three frequency transfer characteristics 3a to 3c shown in FIG. 5B, and FIG. 5C shows four frequencies shown in FIG. 5D. One SAW filter 1 may be used as a filter having various bands and bandwidths, such as configuring a band filter having a combined frequency transfer characteristic 30d (bandwidth 36 MHz) by combining the transfer characteristics 3a to 3d. It becomes possible.

  The SAW filter 1 according to the embodiment described above has the following effects. A plurality of inclined IDT blocks 12a to 12d (inclined IDTs) having different pass bands are connected in parallel to one side of the SAW filter 1 in the propagation direction of elastic waves, and a predetermined combination is selected from these. Therefore, one device can be used as a plurality of types of filters having different pass bands and bandwidths. Therefore, the burden on the maker side required for process management or the like can be reduced as compared with the case where a plurality of SAW filters 1 corresponding to each specification are manufactured and mounted.

  Further, a matching circuit 22 having a matching impedance suitable for the combination of the gradient IDT blocks 12a to 12d selected by the first switches SWa to SWd is selected from the matching circuits having a plurality of types of matching impedances. Since the SAW filter 1 includes the second switches SW1 to SW10 that allow the frequency signal to be input to the inclined IDT blocks 12a to 12d via the matching circuit 22, the amplitude level gradient and the like can be obtained. Low frequency transfer characteristics with good flatness can be obtained.

In addition, the widths of the electrode fingers 16a to 16d and their intervals are set so that the inclined IDT blocks 12a to 12d adjacent to each other have frequency transfer characteristics 3a to 3d having pass bands adjacent to each other. Thus, it is possible to configure a band filter having a synthesized frequency transfer characteristic having a continuous pass band. In particular, the first shoulder portion 31 and the second shoulder portion 32 of the frequency transfer characteristics 3a to 3d between the adjacent inclined IDT blocks 12a to 12d are the amplitude levels of the passbands of the frequency transfer characteristics 3a to 3d. The pitches “d _{1 to} d ₆ ” of the electrode fingers 16 a to 16 d between the adjacent inclined IDT blocks 12 a to 12 d and the number of the electrode fingers 16 a to 16 d are set so as to intersect at a position that is approximately 3 dB smaller than ing. As a result, in the combined frequency transfer characteristic 30 formed by combining a plurality of frequency transfer characteristics 3a to 3d, it is possible to obtain a flat pass band in which the joints between the frequency transfer characteristics 3a to 3d are not conspicuous.

  In the embodiment shown in each of FIGS. 4 and 5, the case where the inclined IDT blocks 12a to 12d are selected so that the newly formed synthesized frequency transfer characteristic 30 has a continuous pass band is illustrated. For example, two inclined IDT blocks 12a and 12c that are not adjacent to each other are selected, and the frequency transfer characteristic 3d of FIG. 3A and the frequency transfer characteristic 3b of FIG. 3C are combined. A bandpass filter having a combined frequency transfer characteristic having a discontinuous passband may be configured. In such a case, since there are 15 combinations of the inclined IDT blocks 12a to 12d shown in FIG. 2A, a type of matching circuit 22 corresponding to these combinations is required.

  Here, the SAW filter 1 may not include the matching circuit 22 corresponding to all combinations of the plurality of inclined IDT blocks 12a to 12d. For example, when the frequency band actually used in the SAW filter 1 (a combination of IDT blocks 12a to 12d) is known in advance, a matching circuit 22 corresponding to these combinations may be provided. For example, when the three inclined IDT blocks 12a, 12b, and 12c have the same impedance, the same matching circuit 22 is used for the combination of the IDT blocks 12a and 12b and the combination of the IDT blocks 12b and 12c. Thus, the number of circuits may be reduced.

  Further, as shown in FIG. 1, in this embodiment, the input side IDT 12 is divided into four inclined IDT blocks 12a to 12d, but the output side IDT 13 may be divided instead of the input side IDT 12. However, both the input side IDT 12 and the output side IDT 13 may be divided. However, when both the input side IDT 12 and the output side IDT 13 are divided, the number of matching circuits 22 required is increased. Therefore, it is preferable that either one is divided. Further, the number of inclined IDT blocks to be divided is not limited to four, and one may be an inclined IDT in which one is divided, and the other may be an IDT that is not inclined.

  Further, as shown in FIG. 6, for example, the input side IDT 121 may be configured by dividing the stepped IDT. In addition, in the above-described embodiment, the case where the SAW filter 1 using SAW has been described. However, the types of elastic wave filters applicable to the present invention are not limited thereto. For example, the present invention can also be applied to an elastic wave filter using a boundary acoustic wave.

It is a top view which shows the structure of the SAW filter which concerns on this Embodiment. It is a top view which shows the structure of the input side IDT of the said SAW filter. It is a characteristic view which shows the frequency transfer characteristic of each inclination type IDT block contained in the said input side IDT. It is a characteristic view which shows the synthetic | combination frequency transfer characteristic obtained by combining several inclination type IDT blocks. It is a 2nd characteristic figure which shows the synthetic | combination frequency transfer characteristic which concerns on another combination. It is a top view which shows the structure of the input side IDT which concerns on other embodiment. It is a top view which shows the structure of the 2 port type filter provided with the conventional inclination type IDT. It is a top view which shows the structure of the said conventional inclination type IDT.

Explanation of symbols

SWa to SWd
1st switch SW1-SW10
Second switch 1 SAW filter 10 Filter unit 11 Piezoelectric substrates 12 and 121
Input side IDT
12a-12d
Inclined IDT block 13 Output IDT
14a-14d
Input side bus bars 15a to 15d
Ground side bus bar 151 Bus bar connection lines 16a to 16d
Electrode finger 17 Output side bus bar 18 Ground side bus bar 19 Electrode finger 2 Selection unit 22 Matching circuit 24 Input port 25 Output ports 3a to 3d
Frequency transfer characteristics 30, 30a-30c
Synthetic frequency transfer characteristic 31 First shoulder portion 32 Second shoulder portion 100 SAW filter 101 Piezoelectric substrate 102 Input side IDT
103 Output IDT
104 Bus bar 105 Electrode finger 106 Input port 107 Output port

Claims (4)

In the acoustic wave filter in which the inclined IDT in which the pitch of the electrode fingers is increased along the direction orthogonal to the propagation direction of the elastic wave on the piezoelectric substrate is provided on the input side and the output side,
One of the input-side inclined IDT and the output-side inclined IDT is divided into a plurality of inclined IDT blocks along a direction orthogonal to the propagation direction of the elastic wave, and the plurality of inclined IDT blocks are parallel to each other. Connected and
An elastic wave filter characterized by being configured such that a combination of inclined IDT blocks to be used can be selected from the plurality of inclined IDT blocks.   The elastic wave filter according to claim 1, further comprising a switch unit which is provided corresponding to each of the plurality of inclined IDT blocks and which enables or disables the corresponding inclined IDT block. A plurality of matching circuits having matching impedances according to combinations of inclined IDT blocks;
And a matching circuit selecting means for connecting a matching circuit corresponding to a combination of the inclined IDT blocks selected from the plurality of matching circuits to the selected inclined IDT block. The elastic wave filter according to claim 1 or 2.   The amplitude level of the intersection of the frequency transfer characteristics of adjacent inclined IDT blocks is 2.5 dB to 3.5 dB lower than the average value of the amplitude levels of the passbands of these inclined IDT blocks. The elastic wave filter as described in any one of thru | or 3.

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