JP3772702B2 - Manufacturing method of surface acoustic wave device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is used for communication equipment and the like. Manufacturing method of surface acoustic wave device It is about.
[0002]
[Prior art]
In recent years, surface acoustic wave devices are also required to be downsized in order to reduce the size of communication equipment. In order to satisfy this demand, a structure is known in which a surface acoustic wave element is flip-chip mounted on a package with bumps or the like and sealed with a sealing member.
[0003]
Although this structure can ensure weather resistance by sealing with a package, the entire structure is considerably larger than the shape of the surface acoustic wave element, and is said to be unsuitable for miniaturization.
[0004]
On the other hand, as a means for solving this problem, a method described in JP-A-11-150440 is known. That is, as shown in FIG. 6, the element-side pad 65 a of the surface acoustic wave element 62 having the comb-shaped electrode 63 is connected to the substrate-side pad 65 b of the substrate 61 via the bumps 64, so that the functional surface of the surface acoustic wave element 62 is The functional surface of the surface acoustic wave element 62 and the outer periphery of the space formed by the substrate 61 are covered with a sealing resin 66 while the space is kept in the space, and the side surfaces and the back surface of the sealing resin 66 and the surface acoustic wave element 62 are waterproofed. A method of sealing by applying a resin 67 has been used.
[0005]
[Problems to be solved by the invention]
However, in the conventional structure in which the surface acoustic wave element 62 is resin-sealed, the height can be reduced to some extent in the height direction, but the substrate 61 is larger than the surface acoustic wave element 62 and the periphery of the surface acoustic wave element 62 is resin-filled. In order to seal, the whole structure necessarily becomes larger than the shape of the surface acoustic wave element 62, and it was difficult to further reduce the size.
[0006]
The present invention solves the above-mentioned conventional problems, and is a small CSP (Chip Size Package) type close to the shape of a surface acoustic wave element. Manufacturing method of surface acoustic wave device Is intended to provide.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the present invention has the following configuration.
[0008]
According to a first aspect of the present invention, there is provided a surface acoustic wave device having a functional surface including a comb electrode, a reflector electrode, and a pad electrode on a surface of a piezoelectric substrate, and a wiring substrate having a pad electrode and a conductive pattern formed thereon. In the surface acoustic wave device manufacturing method, the surface acoustic wave element is coated on the functional surface of the surface acoustic wave element with a step of applying a resin that does not contain components that corrode the comb electrode, the reflector electrode, and the pad electrode. Including a step of providing an opening in the resin, a step of providing a first through hole in the resin applied on the pad electrode of the surface acoustic wave element, and a component that corrodes the comb electrode, the reflector electrode, and the pad electrode on the wiring board. A step of applying a non-resin, a step of providing a second through hole in the resin applied on the pad electrode of the wiring board, and electrically connecting the surface acoustic wave element and the wiring board to the first and second through holes. Connected part And a step of bonding the pad electrode of the surface acoustic wave element and the pad electrode of the wiring board so as to face each other and aligning them, thereby providing a surface acoustic wave device. The effect that a downsized CSP can be obtained is obtained.
[0009]
According to a second aspect of the present invention, there is provided a method in which the step of providing an opening in the resin coated on the functional surface of the surface acoustic wave device is performed by a photolithography method, whereby the surface acoustic wave device is provided. Since the vibration space can be easily formed without affecting the functional surface, a surface acoustic wave device with a small loss can be easily manufactured.
[0010]
The invention according to claim 3 of the present invention has a method in which the first through-hole is formed by a photolithography method, whereby the through-hole can be easily formed without affecting the surface acoustic wave element. Therefore, the effect of obtaining a surface acoustic wave device that secures conduction and is excellent in weather resistance can be obtained.
[0011]
The invention according to claim 4 of the present invention has a method in which the second through hole is formed by a photolithography method or a laser processing method, and this makes it easy without affecting the surface acoustic wave element. Since the through hole can be formed, it is possible to obtain an effect that a surface acoustic wave device that ensures electrical conduction and has excellent weather resistance can be obtained.
[0012]
The invention according to claim 5 of the present invention has a method in which the step of permanently bonding the resin is performed by heating while applying pressure, whereby the surface acoustic wave element and the wiring board are firmly bonded. Therefore, the effect that a surface acoustic wave device excellent in durability and weather resistance can be obtained can be obtained.
[0013]
The invention according to claim 6 of the present invention has a method in which the step of permanently bonding the resin is performed by irradiating light while applying pressure, whereby the surface acoustic wave element and the wiring board are firmly bonded. Therefore, the effect that a surface acoustic wave device excellent in durability and weather resistance can be obtained can be obtained.
[0014]
The invention according to claim 7 of the present invention has a method in which the step of permanently adhering the resin is performed by irradiating light while heating and heating, thereby strengthening the surface acoustic wave element and the wiring board. Therefore, it is possible to obtain a surface acoustic wave device excellent in durability and weather resistance.
[0015]
Claims of the invention 8 The invention described in (2) includes a plurality of surface acoustic wave element assemblies having a functional surface comprising a plurality of comb-shaped electrodes, a plurality of reflector electrodes, and a plurality of pad electrodes on the surface of a wafer-like piezoelectric substrate, a plurality of pad electrodes, In a method for manufacturing a plurality of surface acoustic wave devices composed of an assembly of wiring boards on which a plurality of conductive patterns are formed, a resin that does not contain components that corrode comb-shaped electrodes, reflector electrodes, and pad electrodes is applied to a wafer-like piezoelectric substrate. A step of providing a plurality of openings in the resin applied on the functional surfaces of the plurality of surface acoustic wave element assemblies, and a resin applied on the plurality of pad electrodes of the plurality of surface acoustic wave element assemblies. A step of providing a plurality of first through holes, a step of applying a resin that does not corrode the comb-shaped electrode, the reflector electrode, and the pad electrode to the wiring board assembly, and a coating on the pad electrode of the wiring board assembly. Providing a plurality of second through holes in the formed resin, and arranging a plurality of members for electrically connecting the surface acoustic wave element assembly and the wiring board assembly to the plurality of first and second through holes. A step of providing a plurality of surface acoustic wave element assemblies formed on a wafer-like piezoelectric substrate and a plurality of pad electrodes of a wiring substrate assembly are opposed to each other and then bonded together. The method includes the step of cutting the bonded wafer-like piezoelectric substrate and the wiring substrate assembly into pieces, thereby reducing the size of the surface acoustic wave device and reducing the height of the CSP. The effect that a large amount can be obtained at a time in the wafer state is obtained.
[0016]
Claims of the invention 9 In the invention described in (1), the step of providing an opening in the resin coated on the functional surface of the surface acoustic wave element is performed by a photolithography method, thereby affecting the functional surface of the surface acoustic wave element. Since the vibration space can be easily formed without giving, an effect that a surface acoustic wave device with a small loss can be easily manufactured can be obtained.
[0017]
Claims of the invention 10 The invention described in (1) has a method in which the first through hole is formed by a photolithography method, and thus the through hole can be easily formed without affecting the surface acoustic wave element. The effect of obtaining a surface acoustic wave device that ensures conduction and is excellent in weather resistance can be obtained.
[0018]
Claims of the invention 11 The invention described in 1 has a method in which the second through hole is formed by a photolithography method or a laser processing method, whereby the through hole can be easily formed without affecting the surface acoustic wave element. Therefore, the effect of obtaining a surface acoustic wave device that secures conduction and is excellent in weather resistance can be obtained.
[0019]
Claims of the invention 12 The invention described in the above has a method in which the step of performing the main bonding of the resin is performed by heating while applying pressure, whereby the surface acoustic wave element and the wiring board can be firmly bonded. The effect of obtaining a surface acoustic wave device having excellent weather resistance can be obtained.
[0020]
Claims of the invention 13 The invention described in the above has a method in which the step of permanently adhering the resin is performed by irradiating light while applying pressure. This allows the surface acoustic wave element and the wiring board to be firmly bonded, so that the durability is ensured. The effect that the surface acoustic wave apparatus excellent in the property and the weather resistance can be obtained is obtained.
[0021]
Claims of the invention 14 According to the invention described in (2), there is a method in which the step of performing the main bonding of the resin is performed by irradiating light while heating and heating, whereby the surface acoustic wave element and the wiring board can be firmly bonded. Therefore, the effect that a surface acoustic wave device excellent in durability and weather resistance can be obtained can be obtained.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
(Embodiment 1)
The present invention will be described below using Embodiment 1 of the present invention.
[0023]
FIG. 1 is a cross-sectional view of a surface acoustic wave device according to Embodiment 1 of the present invention.
[0024]
In FIG. 1, 1 is a piezoelectric substrate, 2 is a comb electrode, 3 is a reflector electrode, 4 is a first pad electrode provided on the surface acoustic wave element, 5 is a surface acoustic wave element, and 6a and 6b are thermosetting and Resin that does not contain components that corrode the comb electrode 2, reflector electrode 3, and pad electrode 4, 7 is a resin substrate, 8 is a through hole provided in the resin substrate 7, and 9 a and 9 b are resin substrates 7 The second and third pad electrodes provided in 10 are a metal layer provided on the surface of the through hole 8, 11 is a dense layer provided on the resin substrate 7, 12 is a conductive resin, 13 is a first resin, Reference numeral 14 denotes a second resin, 15 denotes a first through hole, and 16 denotes a second through hole.
[0025]
FIG. 1 schematically shows the configuration, and does not show the relative relationship between the thicknesses and dimensions.
[0026]
The present invention forms a vibration space with the resins 6a and 6b that have thermosetting and photo-curing properties and do not include components that corrode the comb electrode 2, the reflector electrode 3, and the pad electrode 4, and a surface acoustic wave element. The present invention focuses on the fact that a small CSP type surface acoustic wave device can be configured by bonding and sealing a wiring board.
[0027]
A specific manufacturing process will be described below.
[0028]
LiTaO _Three A metal film made of Al or the like is formed on a wafer-like piezoelectric substrate 1 made of, for example, a sputtering method or the like, a resist is coated on the metal film, exposed by a photolithography method, and developed. The desired comb-shaped electrode 2, reflector electrode 3, and first pad electrode 4 are formed by etching the metal film to obtain a surface acoustic wave element assembly.
[0029]
On the other hand, a through hole 8 is formed at a predetermined position of the resin substrate 7 made of glass epoxy resin or the like by, for example, laser processing.
[0030]
Next, a metal layer is formed on the entire surface of the resin substrate 7 by Cu plating or the like, and a resist is applied on the metal layer. Then, exposure, development, and etching are performed by a photolithography method so that the inner surface of the through hole 8 is plated with Cu. A resin substrate 7 having a desired electrode pattern, such as a metal layer 10 made of, etc. and a dense layer 11 made of Cu plating or the like, is formed.
[0031]
Further, a first resin 13 such as an epoxy resin is disposed in the through hole 8 and is embedded in the hole of the through hole 8. Second and third layers made of Cu or the like are formed on the metal layer 10 and the first resin 13. Pad electrodes 9a and 9b are formed.
[0032]
Thereafter, a second resin 14 made of a resist or the like is applied and cured on the entire surface of the resin substrate 7 on which the second pad electrode 9a is provided by spin coating or the like, and then the second pad electrode 9a and the dense layer 11 are applied. The second resin 14 is removed by a method such as polishing until appears on the surface to obtain a wiring board assembly.
[0033]
Here, the second resin 14 is provided because when the metal layer 10, the second pad electrode 9 a, and the dense layer 11 are provided in the through hole 8 of the resin substrate 7, a step having a constant thickness is formed from the resin substrate 7. The
[0034]
If this level difference is relatively small, it can be absorbed by the thermosetting and photo-curing resin 6b. However, if the level difference becomes large to some extent, it cannot be absorbed, and in some cases, a cavity may be formed to improve sealing performance. It may cause trouble.
[0035]
Therefore, by providing the second resin 14 in advance, this step can be eliminated and the surface can be flattened to improve the sealing performance and increase the adhesive strength. If necessary, a metal layer having oxidation resistance made of Au or the like may be provided on the second and third pad electrodes 9a and 9b made of Cu or the like.
[0036]
The surface acoustic wave element assembly thus obtained is coated on the entire surface with a thermosetting and photocurable resin by spin coating, for example, and dried, and then the comb-shaped electrode 2 and the reflection of the surface acoustic wave element 5 are reflected. The functional surface portion such as the electrode 3 is exposed and developed by a photolithography method, the resin having thermosetting and photocuring properties in the functional surface portion is removed and washed, and a vibration space is formed in the functional surface portion. Then, the first through hole 15 is formed in the thermosetting and photocurable resin 6 a on the first pad electrode 4.
[0037]
On the other hand, after applying and drying a resin having a thermosetting property and a photocurable property on the surface of the wiring board assembly provided with the second pad electrode 9a and the dense layer 11 by a method such as spin coating, Exposure and development are performed by photolithography, and the resin having thermosetting and photocuring properties in the functional surface portion of the surface acoustic wave element 5 is removed and washed to form a vibration space in the functional surface portion. A second through hole 16 is formed in the thermosetting and photocurable resin 6b on the pad electrode 9a.
[0038]
Next, an electrical connection member made of a conductive resin 12 such as Ag is applied to the first and second through holes 15 and 16 by printing, for example, and the surface acoustic wave element assembly and the wiring board assembly are made to face each other. The positions of the first through holes 15 provided in the surface wave element assembly and the second through holes 16 provided in the wiring board assembly are adjusted and overlapped, and pressed with a pressure of about 1 MPa to obtain the surface acoustic wave element assembly. The substrate and the wiring board assembly are heat-treated at 160 ° C. for 30 minutes and then heat-cured at 200 ° C. for 30 minutes, and the surface acoustic wave element assembly and the wiring board assembly are permanently bonded.
[0039]
Thus, the surface acoustic wave device assembly can be formed in a wafer state. Then, it cut | disconnects into the surface acoustic wave apparatus of a piece by cut | disconnecting to a predetermined dimension using a dicing apparatus etc., for example.
[0040]
Thus, the surface acoustic wave element assembly and the wiring board assembly are electrically connected by the conductive resin 12, and the surface acoustic wave element assembly and the wiring board assembly are formed by the thermosetting and photocurable resins 6a and 6b. A compact CSP type surface acoustic wave device is obtained in which the body is bonded and the surface acoustic wave element 5 and the wiring board have substantially the same shape.
[0041]
Here, as the resin, resins 6a and 6b having both thermosetting and photo-curing functions were used. By using the photo-curing property of the resin, a vibration space and a through hole are formed, so that the surface acoustic wave is formed. This is because processing can be performed without affecting the comb-shaped electrode 2, the reflector electrode 3, and the first pad electrode 4 of the element 5, and thereby easily without affecting the characteristics of the surface acoustic wave element 5. A highly accurate small surface acoustic wave device can be formed.
[0042]
Further, the total thickness of the thermosetting and photocurable resins 6a and 6b needs to be at least a thickness that can secure the vibration space of the surface acoustic wave element 5, and at least 5 μm or more. The connection interval between the surface acoustic wave element 5 and the resin substrate 7 is determined by the total thickness of the thermosetting and photocurable resins 6a and 6b.
[0043]
The thermosetting and photocurable resins 6a and 6b are formed on both the surface acoustic wave element 5 side and the resin substrate 7 side, but they may be formed only on one side. In that case, in order to form the vibration space with high accuracy, it is desirable to dispose a thermosetting resin and a photocurable resin on the surface acoustic wave element 5 side.
[0044]
Moreover, although the component which corrodes the comb-shaped electrode 2, the reflector electrode 3, and the 1st pad electrode 4 was not included as a component of resin 6a, 6b which has thermosetting and photocurable property, this is thermosetting. In addition, if the photo-curing resins 6a and 6b contain components that corrode the materials of the comb electrode 2, the reflector electrode 3, and the first pad electrode 4, the electrodes are damaged, and the surface acoustic wave element 5 This is because the initial characteristics of the material deteriorate or the weather resistance deteriorates. In the present invention, as a component that corrodes the comb electrode 2, the reflector electrode 3, and the first pad electrode 4 in the thermosetting and photocurable resins 6a and 6b, CaCO _Three , Ca compound, MgCO _Three , Mg compound, Na ₂ CO _Three , Na compound, K ₂ CO _Three , K compounds, halogenated compounds and the like have been found to have an adverse effect.
[0045]
These substances exhibit alkalinity when dissolved in water or the like, and corrode metals such as Al, Al alloy, Ti used for the surface acoustic wave element 5, so that the same space as well as the case where the resin and metal are in direct contact with each other. Even if it coexists, the initial characteristics and weatherability are deteriorated.
[0046]
Accordingly, the thermosetting and photocurable resins 6a and 6b used for joining and sealing the surface acoustic wave element 5 are not free of CaCO. _Three , Ca compound, MgCO _Three , Mg compound, Na ₂ CO _Three , Na compound, K ₂ CO _Three It is important that no K compound or halogen compound is contained. CaCO _Three , Ca compound, MgCO _Three , Mg compound, Na ₂ CO _Three , Na compound, K ₂ CO _Three It is necessary for the metal used for the surface acoustic wave element 5 to contain no components that corrode metals other than K compounds and halogen compounds.
[0047]
The heat treatment conditions for the main bonding of the thermosetting and photocurable resins 6a and 6b are as follows. After the first stage is bonded and cured at a temperature of about 160 ° C., the second stage has a higher temperature. It is desirable to stabilize the resin by heat treatment at a temperature such as 200 ° C., and a two-stage heat treatment is effective.
[0048]
The photolithography method is used as a method of making a through hole in the thermosetting and photocurable resin 6a on the first pad electrode 4, but this is because the surface acoustic wave element 5 is not damaged. Otherwise, it is not preferable to make a through-hole using a laser or the like, since electric charges are generated from the piezoelectric substrate 1 due to heat generated during processing, and electrostatic discharge or the like is caused to cause defects.
[0049]
The resin substrate 7 is used as the material of the wiring substrate. However, when the resin substrate 7 is used for a long period of time, moisture and gas are transmitted through pores and the like existing in the resin substrate 7, thereby adversely affecting the characteristics of the surface acoustic wave element 5. Sometimes. Therefore, in order to avoid this, by providing the dense layer 11 made of, for example, metal on the surface of the resin substrate 7 facing the vibration space, it is possible to block moisture and gas from permeating through pores existing in the resin substrate 7. Therefore, it becomes difficult to be influenced by the surroundings, and weather resistance can be improved over a long period of time.
[0050]
Further, in order to efficiently suppress the permeation of moisture and gas from the resin substrate 7 by the dense layer 11, the dense layer 11 and the resin 6b having thermosetting and photocuring properties are in contact with each other or dense. It is desirable that a part of the layer 11 is covered with a resin 6b having thermosetting and photosetting properties.
[0051]
In addition to the resin substrate, a ceramic substrate, a glass substrate, or the like may be used as the material for the wiring substrate. Further, when a ceramic substrate, a glass substrate, or the like is used, the substrate itself is dense, and thus it is not necessary to provide a dense layer.
[0052]
Also, the second and third pad electrodes 9a and 9b are provided on the through hole 8 of the resin substrate 7 so as to close the hole of the through hole 8. In addition, the second and third pad electrodes 9a and 9b can be provided on the through-hole 8 to form a flat metal layer on the through-hole 8. Since the bonding property and sealing property with the member can be improved, it is difficult to be influenced by the surroundings, the weather resistance can be improved over a long period of time, and the surface acoustic wave element 5 and the resin substrate 7 can be improved. Connection reliability can be improved.
[0053]
The metal layer provided in the through hole 8 and the dense layer 11 may be a metal other than Cu as long as it is electrically conductive and a dense layer can be formed.
[0054]
Further, the metal layer provided in the through hole 8 and the dense layer 11 may be the same metal or a different metal. However, the same metal can be formed at the same time and the process can be simplified.
[0055]
In addition, although the conductive resin 12 was used as the electrical connection member, a bump made of Au or the like is provided on the first pad electrode 4 of the surface acoustic wave element 5 in addition to this, and the second of the resin substrate 7 is provided. The pad electrode 9a may be electrically connected by disposing a conductive resin or the like and bonding the bump and the conductive resin. In this case, the bump may or may not be in direct contact with the second pad electrode 9a of the resin substrate 7.
[0056]
As described above, in the first embodiment, the surface acoustic wave element 5 and the resin substrate 7 are bonded using the resins 6a and 6b having both thermosetting and photocurable functions as the resin. By sealing and electrically connecting with the conductive resin 12 and cutting the surface acoustic wave device assembly in the wafer state, the surface acoustic wave element 5 and the wiring board are substantially the same in shape, and a small CSP type elasticity. The effect that a surface wave device can be obtained easily is obtained.
[0057]
(Embodiment 2)
The present invention will be described below using Embodiment 2 of the present invention.
[0058]
FIG. 2 is a sectional view of the surface acoustic wave device according to the second embodiment.
[0059]
2, the same components as those described in FIG. 1 of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0060]
FIG. 2 schematically shows the configuration, and does not show the relative relationship between the thicknesses and dimensions.
[0061]
The differences between the second embodiment and the first embodiment are the configuration and type of the electrical connection member that connects the surface acoustic wave element assembly and the wiring board assembly, the material of the wiring board, and the thermosetting property. The structure of the resin having both photo-curing functions and the method of the main bonding are the same, and the other operations are the same as in the first embodiment.
[0062]
That is, in the first embodiment, the surface acoustic wave element assembly and the wiring board assembly are connected by an electrical connection member made of a conductive resin 12 such as Ag, but in the second embodiment, A bump 21 made of a metal such as Au is provided on the first pad electrode 4 provided in the surface acoustic wave element assembly, and the surface acoustic wave element assembly and the wiring are connected by an electrical connection member made of the bump 21 and the conductive resin 22. The substrate assembly is electrically connected, and the surface acoustic wave element assembly and the wiring substrate assembly are bonded by a resin 25 having thermosetting and photo-curing properties.
[0063]
Specifically, a glass substrate 23 is used as a wiring substrate, and a through hole 24 is provided in the glass substrate 23 in advance by sandblasting or the like.
[0064]
A resin 25 having a thermosetting property and a photo-curing property is applied only on the surface acoustic wave element 5, and the vibration space and the third through hole 26 are formed by exposing and developing by a photolithography method or the like.
[0065]
Next, the surface acoustic wave element assembly and the wiring board assembly are made to face each other, the positions of the bumps 21 of the surface acoustic wave element assembly and the through holes 24 of the wiring board assembly are adjusted and overlapped, and the glass substrate 23 is provided. The conductive resin 22 made of Ag or the like is printed and applied through the through-hole 24, and is contacted with the bump 21 and cured.
[0066]
Thereafter, the resin 25 having thermosetting property and photo-curing property is cured by irradiating light such as ultraviolet rays while pressing and setting the interval between the surface acoustic wave element assembly and the wiring board assembly to a predetermined interval, and elastic A surface wave element assembly and a wiring board assembly are bonded together.
[0067]
Implemented except changing the construction and type of the electrical connection member that connects the surface acoustic wave element assembly and the wiring board assembly, the material of the wiring board, and the method of permanently bonding the resin having thermosetting and photocuring properties. A surface acoustic wave device was fabricated in the same manner as in Embodiment 1.
[0068]
The bump 21 and the conductive resin 22 are used as the electrical connection members because the bump 21 is provided on the first pad electrode 4 of the surface acoustic wave element 5 to electrically connect the first pad electrode 4 and the bump 21. In addition, the bump 21 can have a larger connection area than the first pad electrode 4, so that the contact resistance is reduced and the surface acoustic wave element assembly and the wiring board assembly are electrically connected. This is because the reliability of the can be improved. The reason why the glass substrate 23 is used as the wiring substrate is that the glass substrate 23 is dense and can almost eliminate intrusion of moisture and gas from the surroundings. When the glass substrate 23 is used, the surface acoustic wave is used. A dense layer may not be provided in a portion facing the functional surface of the element 5.
[0069]
Further, by applying the conductive resin 22 through the through hole 24 provided in the glass substrate 23, electrical connection between the surface acoustic wave element assembly and the wiring board assembly is ensured, and the through hole provided in the glass substrate 23. 24 can be sealed at the same time, and the weather resistance can be improved.
[0070]
In order to make the surface acoustic wave element assembly and the wiring board assembly face each other, and adjust the positions of the bumps 21 of the surface acoustic wave element assembly and the through holes 24 of the wiring board assembly, the glass substrate 23 If the material has translucency as described above, the position of the bump 21 can be easily confirmed through the glass substrate 23, so that there is an advantage that the alignment can be performed more easily.
[0071]
As a method for curing the resin 25 having thermosetting property and photo-curing property, the surface acoustic wave element assembly is focused by being irradiated with light while pressing the surface acoustic wave element assembly and the wiring board assembly. Due to its electrical properties, when heat is applied, electric charges are generated, which may cause electrostatic discharge and the like, and the characteristics of the surface acoustic wave element 5 may be deteriorated. However, when the resin is cured by light irradiation, the generation of electric charges is hardly generated. This is because the occurrence of defects due to electrostatic discharge can be eliminated, and curing and sealing can be performed efficiently in a short time.
[0072]
Further, the reason why the resin 25 having thermosetting and photo-curing properties is provided only on the surface acoustic wave element 5 side is that the resin can be applied, the formation of the vibration space, and the formation of the through hole can be reduced, and the process can be simplified. is there.
[0073]
In addition, when a wiring substrate having translucency such as the glass substrate 23 is used, light can be effectively irradiated to the inside of the surface acoustic wave device by irradiating light through the glass substrate 23. There exists an advantage that hardening of resin 25 which has curability and photocurability can be accelerated | stimulated. Such an effect can be obtained with a light-transmitting substrate such as a light-transmitting alumina substrate in addition to the glass substrate.
[0074]
As described above, in the second embodiment, the electrical connection is ensured by using the bumps 21 and the conductive resin 22, and the glass substrate 23 is used as the wiring board, and light irradiation is performed while pressing. In addition, since the sealing can be performed at the same time, the operation and effect can be obtained that the process can be simplified and the electrical connection reliability and the weather resistance can be further improved as compared with the first embodiment.
[0075]
(Embodiment 3)
Hereinafter, the present invention will be described using Embodiment 3 of the present invention.
[0076]
FIG. 3 is a sectional view of the surface acoustic wave device according to the third embodiment.
[0077]
3, the same components as those described in FIG. 1 of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0078]
FIG. 3 schematically shows the configuration, and does not show the relative relationship between the thicknesses and dimensions.
[0079]
The difference between the third embodiment and the first and second embodiments is that a protective film is provided on a part or the entire surface of the electrode of the surface acoustic wave element, and the surface acoustic wave element and the wiring board are provided. The construction and type of the electrical connection member to be connected, the material of the wiring board, and the method of permanently bonding the resin, and the other operations were the same as in the first embodiment.
[0080]
That is, in the first embodiment, the surface acoustic wave element assembly and the wiring board assembly are connected by an electrical connection member made of a conductive resin 12 such as Ag, but in the third embodiment, The first pad electrode provided on the surface acoustic wave element assembly by forming a protective film 31 on a part or the entire surface of the comb-shaped electrode 2, the reflector electrode 3, and the first pad electrode 4 of the surface acoustic wave element 5. 4 at a predetermined position of a low-temperature cofired substrate 33 (hereinafter referred to as LTCC substrate: Low Temperature Cofired Ceramic) opposite to the fourth conductive electrodes made of fourth and fifth pad electrodes 36a, 36b made of Ag, through holes 34, Ag, etc. The surface acoustic wave element 5 and the LTCC substrate 33 are adhered and sealed with the thermosetting and photocurable resins 6a and 6b, and the surface acoustic wave element 5 and the LTCC substrate 33 are connected to the conductive resin 32. It is set as the structure electrically connected by.
[0081]
Specifically, the comb electrode 2, the reflector electrode 3, and the first pad electrode 4 are formed on the piezoelectric substrate 1 with a metal such as Al—Cu, and then the comb electrode 2 and the reflector electrode 3 are formed by an anodic oxidation method or the like. A protective film 31 made of a metal oxide such as Al—Cu is formed on a part or the whole of the electrode surface of the first pad electrode 4.
[0082]
Note that a portion where the protective film 31 is not formed is previously coated with a resist, and then the protective film 31 is formed, and then the resist is peeled off.
[0083]
On the other hand, a through hole 34 is formed at a predetermined position of the LTCC substrate green sheet by a method such as punching, and a conductive resin 35 made of Ag or the like is applied and embedded in the through hole 34, and Ag and the like are formed on both upper and lower surfaces of the through hole 34 The LTCC substrate 33 is obtained by forming the fourth and fifth pad electrodes 36a and 36b to be fired simultaneously.
[0084]
Next, the surface acoustic wave element assembly and the LTCC substrate assembly are made to face each other, and the positions of the first pad electrode 4 of the surface acoustic wave element assembly and the fourth pad electrode 36a of the LTCC substrate assembly are adjusted and overlapped. Resin having thermosetting and photo-curing properties by irradiating with light such as ultraviolet rays and heating to 160 ° C. while keeping the distance between the surface acoustic wave element assembly and the LTCC substrate assembly at a predetermined interval by combining and pressing 6a and 6b were cured, and the surface acoustic wave element assembly and the wiring board assembly were permanently bonded.
[0085]
The elastic surface is the same as in the first embodiment except that the protective film 31 is formed on a part of or the entire surface of the electrode of the surface acoustic wave element 5, the material of the wiring board, and the method of permanently bonding the resin are changed. A wave device was produced.
[0086]
The protective film 31 is formed on part or all of the electrode surfaces of the comb-shaped electrode 2, the reflector electrode 3, and the first pad electrode 4 of the surface acoustic wave element 5. The protective film 31 having a high resistance is formed on the electrode. This is to prevent the surface acoustic wave element 5 from being short-circuited or deteriorated in characteristics even when conductive foreign matter adheres to the surface of the surface acoustic wave element 5.
[0087]
As a method of forming the protective film 31, a method of forming a metal oxide by an anodic oxidation method and SiO ₂ There is a method of forming a film of silicon or silicon nitride on the electrode, and either method may be used. In the anodic oxidation method, a protective film is formed only on the electrode surface. ₂ In the method of forming a film such as silicon nitride, a protective film is also formed on the electrode surface and the piezoelectric substrate, so that characteristics such as loss of the surface acoustic wave element are deteriorated. Is desirable.
[0088]
The use of the LTCC substrate 33 as the wiring substrate allows various wirings to be easily formed, allows an external additional circuit to be built in the LTCC substrate 33, and can produce a composite module. This is because the structure can be realized.
[0089]
As a method for bonding and curing the thermosetting and photocurable resins 6a and 6b, a method of irradiating and heating light while pressing was used, but this method is most surely bonded considering the properties of the resin. This is because it is cured.
[0090]
As described above, in the third embodiment, the protective film 31 is formed on a part or the entire surface of the comb-shaped electrode 2, the reflector electrode 3, and the pad electrode 4 of the surface acoustic wave element 5, and the LTCC substrate 33 and the surface acoustic wave element 5 are formed. The resin 6a, 6b having thermosetting property and photo-curing property is cured by irradiating with light such as ultraviolet rays while being pressed, and the LTCC substrate 33 and the surface acoustic wave element 5 are bonded and sealed to conduct electricity. In this configuration, the LTCC substrate 33 and the surface acoustic wave element 5 are electrically connected to each other by a conductive resin. Compared with the first embodiment, the short circuit and characteristic deterioration of the surface acoustic wave element 5 can be reduced. It is done.
[0091]
(Embodiment 4)
Hereinafter, the present invention will be described using Embodiment 4 of the present invention.
[0092]
FIG. 4 is a cross-sectional view of the surface acoustic wave device according to the fourth embodiment.
[0093]
4, the same components as those described in FIG. 1 of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0094]
Note that FIG. 4 schematically shows the configuration, and does not show the relative relationship between the thicknesses and dimensions.
[0095]
The difference between the fourth embodiment, the first embodiment, the second embodiment, and the third embodiment is that an external electrode is provided on the end face of the surface acoustic wave device, and the others are the first embodiment. The same operation was performed.
[0096]
That is, in the first embodiment, the surface acoustic wave element assembly and the wiring board assembly are connected by an electrical connection member made of a conductive resin 12 such as Ag, but in the fourth embodiment, The part or the entire surface of the sixth pad electrode 41 provided on the surface acoustic wave element 5 is extended to the terminal portion of the surface acoustic wave element 5 and connected to the external electrode 42 made of a metal film or the like formed on the end face. Is.
[0097]
Since the external electrode area can be increased by adopting such a configuration, the adhesion force when the surface acoustic wave device is mounted on the circuit board can be increased. For example, the surface acoustic wave device in a drop test or the like There is an advantage that the peel strength of the film can be increased.
[0098]
Note that the external electrode 42 provided in FIG. 4 was not formed on the external surface of the surface acoustic wave element 5, but this is caused by distortion when the electrode is formed on the surface acoustic wave element 5, or heat treatment is performed at the time of electrode formation. This is because electric charges are generated, and the comb-shaped electrode 2 is easily damaged due to electrostatic discharge or the like, and may be defective. However, it may be provided if necessary.
[0099]
The external electrode 42 is formed by forming a metal film such as Ni—Cr as a lower layer electrode by a method such as sputtering and forming a metal film such as Ni or Sn thereon by a method such as plating. Other methods may be used as long as they are methods.
[0100]
As described above, in the fourth embodiment, a part or the entire surface of the sixth pad electrode 41 provided on the surface acoustic wave element 5 is extended to the terminal portion of the surface acoustic wave element 5 and is formed of an external film made of a metal film formed on the end face. Compared to the first embodiment, the configuration is connected to the electrode 42, and various external terminal configurations are possible, and the effect of increasing the peel strength in a drop test or the like can be obtained.
[0101]
(Embodiment 5)
Hereinafter, the present invention will be described using Embodiment 5 of the present invention.
[0102]
FIG. 5 is a configuration diagram of a composite module using the surface acoustic wave device according to the fifth embodiment.
[0103]
In FIG. 5, 51 is a first CSP type surface acoustic wave device, 52 is a first switching circuit for switching between transmission and reception, 53 is a harmonic elimination circuit made of a first low-pass film, and 54 is a second CSP. Type surface acoustic wave device, 55 is a second switching circuit for switching between transmission and reception, 56 is a harmonic elimination circuit comprising a second low-pass filter, 57 is a demultiplexing circuit, 58 is an antenna, and 59 is a composite module .
[0104]
In the fifth embodiment, the CSP type surface acoustic wave device manufactured in the first embodiment is used for the first CSP type surface acoustic wave device 51 and the second CSP type surface acoustic wave device 54, and two frequencies are used. This is a dual type composite module that can be used, and consists of a module in which a portion excluding an antenna is combined into one package.
[0105]
The first CSP type surface acoustic wave device 51 and the second CSP type surface acoustic wave device 54 are CSP type surface acoustic wave devices having different frequency pass bands.
[0106]
In the case of reception, the signal input from the antenna 58 is divided into one of two target frequencies by the branching circuit 57, and the receiving circuit is further switched by the first switching circuit 52 or the second switching circuit 55. The first CSP type surface acoustic wave device 51 or the second CSP type surface acoustic wave device 54 is used to extract only the target frequency.
[0107]
On the other hand, in the case of transmission, an unnecessary high-frequency component is removed from the target signal by a harmonic removal circuit composed of the first low-pass filter 53 or the second low-pass filter 56, and the first switching circuit 52 or the second switching is performed. The circuit 55 is switched to the transmission side, and the signal is transmitted from the antenna 58 through the branching circuit 57.
[0108]
Here, the harmonic switching circuit including the first switching circuit 52 and the first low-pass filter 53, the harmonic removing circuit including the second switching circuit 55 and the second low-pass filter 56, and the branching circuit 57 include A single CSP type surface acoustic wave device 51 and a second CSP type surface acoustic wave device 54 are mounted on an LTCC substrate and are packaged in one package. It is possible to obtain a small composite module 59 by sealing it in the form.
[0109]
The first and second switching circuits 52 and 55 can be a switch circuit or a phase circuit made of a diode or the like depending on the purpose.
[0110]
By combining a plurality of circuits into one package in this way, the circuit can be reduced in size and the loss due to connection can be reduced compared to the case where a single component is connected. Can be realized.
[0111]
The first CSP type surface acoustic wave device 51 and the second CSP type surface acoustic wave device 54 each have a small CSP structure, and are already packaged and ensured performance. Stable performance can be obtained.
[0112]
As a circuit integrated with the composite module, when only the switching circuit and the surface acoustic wave device are integrated, when the switching circuit, the surface acoustic wave device, and the harmonic elimination circuit are integrated, the switching circuit and the surface acoustic wave device are integrated. It is possible to integrate the device, the harmonic elimination circuit, and the demultiplexing circuit, etc., and the range of integration may be changed as necessary, and a matching circuit with another circuit, for example, an impedance matching strip It may be integrated by adding tracks.
[0113]
As described above, in the fifth embodiment, the entire circuit can be reduced in size by connecting a plurality of circuits together with a CSP type surface acoustic wave device that ensures performance, and a single component can be connected. Since the loss due to the connection can be reduced as compared with the case where it is made, it is possible to realize a composite module that is small, has a low loss, and is highly attenuated as compared with a case where a single component is combined.
[0114]
【The invention's effect】
As described above, according to the present invention, the surface acoustic wave element and the wiring board are bonded using a resin having both thermosetting and photocurable functions, and simultaneously cut. As a result, there can be obtained an effect that a small CSP type surface acoustic wave device in which the surface acoustic wave element and the wiring board have substantially the same shape can be easily obtained.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a surface acoustic wave device according to Embodiment 1 of the present invention.
FIG. 2 is a cross-sectional view of a surface acoustic wave device according to Embodiment 2 of the present invention.
FIG. 3 is a sectional view of a surface acoustic wave device according to a third embodiment of the present invention.
FIG. 4 is a sectional view of a surface acoustic wave device according to a fourth embodiment of the present invention.
FIG. 5 is a configuration diagram of a composite module according to Embodiment 5 of the present invention.
FIG. 6 is a sectional view of a conventional surface acoustic wave device.
[Explanation of symbols]
1 Piezoelectric substrate
2 Comb electrode
3 Reflector electrodes
4 First pad electrode
5 Surface acoustic wave device
6a Resin having thermosetting and photocuring properties
6b Resin having thermosetting and photocuring properties
7 Resin substrate
8 Through hole
9a Second pad electrode
9b Third pad electrode
10 Metal layer
11 Dense layer
12 Conductive resin
13 First resin
14 Second resin
15 First through hole
16 Second through hole
21 Bump
22 Conductive resin
23 Glass substrate
24 through hole
25 Thermosetting and photocuring resins
26 Third through hole
31 Protective film
32 conductive resin
33 LTCC substrate
34 Through hole
35 Conductive resin
36a Fourth pad electrode
36b Fifth pad electrode
41 Sixth pad electrode
42 External electrode
43 resin having thermosetting and photocuring properties
51 First surface acoustic wave device
52 First switching circuit
53 First harmonic elimination filter
54 Second surface acoustic wave device
55 Second switching circuit
56 Second harmonic elimination filter
57 branching circuit
58 Antenna
59 Compound module

Claims (14)

  In the method of manufacturing a surface acoustic wave device including a surface acoustic wave element having a functional surface composed of a comb-shaped electrode, a reflector electrode, and a pad electrode on a surface of a piezoelectric substrate, and a wiring substrate on which a pad electrode and a conductive pattern are formed. Applying a resin that does not include a component that corrodes the comb electrode, the reflector electrode, and the pad electrode to the surface acoustic wave element; and providing an opening in the resin applied on the functional surface of the surface acoustic wave element A step of providing a first through hole in the resin coated on the pad electrode of the surface acoustic wave element, and a component that corrodes the comb electrode, the reflector electrode, and the pad electrode on the wiring board. A step of applying a non-resin, a step of providing a second through hole in the resin applied on the pad electrode of the wiring board, and the elastic surface in the first and second through holes. A surface acoustic wave including a step of disposing a member for electrically connecting the element and the wiring board, and a step of aligning the pad electrode of the surface acoustic wave element and the pad electrode of the wiring board so as to face each other and then performing a final bonding Device manufacturing method.   2. The method of manufacturing a surface acoustic wave device according to claim 1, wherein the step of providing an opening in the resin applied on the functional surface of the surface acoustic wave element is performed by a photolithography method.   The surface acoustic wave device manufacturing method according to claim 1, wherein the first through hole is formed by a photolithography method.   The surface acoustic wave device manufacturing method according to claim 1, wherein the second through hole is formed by a photolithography method or a laser processing method.   The method for manufacturing a surface acoustic wave device according to claim 1, wherein the step of permanently bonding the resin is performed by heating while applying pressure.   The method for producing a surface acoustic wave device according to claim 1, wherein the step of permanently bonding the resin is performed by irradiating light while applying pressure.   The method for producing a surface acoustic wave device according to claim 1, wherein the step of permanently adhering the resin is performed by applying light while heating and heating.   A surface of a wafer-like piezoelectric substrate has a plurality of comb electrodes and a plurality of reflector electrodes, a plurality of surface acoustic wave element assemblies having a functional surface composed of a plurality of pad electrodes, a plurality of pad electrodes and a plurality of conductive patterns. In the method for manufacturing a plurality of surface acoustic wave devices including the formed wiring board assembly, a step of applying a resin that does not include a component that corrodes the comb electrode, the reflector electrode, and the pad electrode to the wafer-like piezoelectric substrate; A step of providing a plurality of openings in the resin applied on the functional surfaces of the plurality of surface acoustic wave element assemblies, and a step of applying a resin to the resin applied on the plurality of pad electrodes of the plurality of surface acoustic wave element assemblies. A step of providing a plurality of through-holes, a step of applying a resin that does not corrode the comb-shaped electrode, the reflector electrode, and the pad electrode to the wiring board assembly, and a package of the wiring board assembly. A step of providing a plurality of second through holes in the resin applied on the electrodes, and electrically connecting the surface acoustic wave element assembly and the wiring board assembly to the plurality of first and second through holes. The step of disposing a plurality of members and the plurality of pad electrodes of the plurality of surface acoustic wave element assemblies formed on the wafer-like piezoelectric substrate and the plurality of pad electrodes of the wiring board assembly are opposed to each other. A method of manufacturing a surface acoustic wave device, comprising: a step of aligning and aligning the wafer-shaped piezoelectric substrate; and a step of cutting the wafer-bonded piezoelectric substrate and wiring substrate assembly into pieces. 9. The method for manufacturing a surface acoustic wave device according to claim 8 , wherein the step of providing an opening in the resin coated on the functional surface of the surface acoustic wave element is performed by a photolithography method. The method for manufacturing a surface acoustic wave device according to claim 8 , wherein the first through hole is formed by a photolithography method. The method of manufacturing a surface acoustic wave device according to claim 8 , wherein the second through hole is formed by a photolithography method or a laser processing method. The method for manufacturing a surface acoustic wave device according to claim 8 , wherein the step of permanently bonding the resin is performed by heating while applying pressure. The method for manufacturing a surface acoustic wave device according to claim 8 , wherein the step of permanently bonding the resin is performed by irradiating light while applying pressure. The method for manufacturing a surface acoustic wave device according to claim 8 , wherein the step of permanently bonding the resin is performed by applying light and heating while applying pressure.

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