This application claims priority under 35 U.S.C. §119 to Japanese Patent Application No. 2010-003352 filed on Jan. 8, 2010, the entire content of which is hereby incorporated by reference.
1. Field of the Invention
The present invention relates to a piezoelectric vibrator manufacturing method, a piezoelectric vibrator, an oscillator, an electronic device, and an atomic timepiece.
2. Related Art
In recent years, a piezoelectric vibrator utilizing a piezoelectric vibrating piece formed from a piezoelectric material such as quartz has been used in portable telephones and portable information terminal instruments as a time source, a control signal timing source, a reference signal source, and the like. A tuning fork-shaped piezoelectric vibrating piece including a pair of vibrating arms is employed as the piezoelectric vibrating piece.
As this kind of piezoelectric vibrator, a surface mount type (SMD) piezoelectric vibrator is known.
As the surface mount type piezoelectric vibrator, one is proposed wherein a package is formed of a base substrate and a lid substrate, and a piezoelectric vibrating piece is housed in a cavity formed inside the package. The base substrate and lid substrate, a bonding film being disposed between the two, are bonded by means of an anodic bonding. The bonding film is formed from a metal such as aluminum (Al) or chromium (Cr), a semiconductor such as silicon (Si), or the like, and is provided on the surface of the base substrate that bonds to the lid substrate, or on the surface of the lid substrate that bonds to the base substrate. Herein, as the lid substrate has no electrode, when forming the bonding film on the lid substrate, there is no need for a step of masking the electrode. For this reason, because of a demand for a simplification of the manufacturing process and a reduction in the manufacturing cost, it is often the case recently that the bonding film is formed over the whole of the surface of the lid substrate that bonds to the base substrate.
However, it is desirable that an equivalent resistance value (an effective resistance value, Re) of the piezoelectric vibrator is kept low. As a piezoelectric vibrator with a low equivalent resistance value can cause the piezoelectric vibrating piece to vibrate with low power, it is an energy-efficient piezoelectric vibrator. As one common method of suppressing the equivalent resistance value, a method is known whereby the inside of the cavity in which the piezoelectric vibrating piece is sealed is brought close to a vacuum, thus reducing a serial resonance resistance value (R1), which is in a proportional relationship to the equivalent resistance value.
As a method of bringing the inside of the cavity close to a vacuum, there is known a method including a gettering step whereby a getter material formed from Al, Cr, or the like, is sealed on the base substrate inside the cavity and irradiated from the exterior with a laser, thus activating the getter material (refer to JP-A-2003-142976). According to this method, as it is possible to absorb oxygen emitted at the time of the anodic bonding with the getter material which is in an activated condition, it is possible to bring the inside of the cavity close to a vacuum.
Also, after the gettering step, a fine adjustment of the frequency of the piezoelectric vibrating piece (a frequency adjustment step) is carried out by a weight metal film formed on the leading end portions of the vibrating arms being irradiated with a laser, trimming the weight metal film. By carrying out the frequency adjustment step, it is possible to keep the frequency of the piezoelectric vibrating piece within a nominal frequency range.
As the getter material and weight metal film are formed near to each other, it is common to use the same laser emitting device in the gettering step as in the frequency adjustment step, and irradiate the getter material with the laser at the same laser intensity as that in the frequency adjustment step. By sharing the laser emitting device between the gettering step and frequency adjustment step, a rise in cost of manufacturing equipment is curbed.
However, in the gettering step, when irradiating the getter material formed on the inner side of the base substrate from the outer side of the base substrate, it may happen that the laser passes through the getter material, and reaches the lid substrate. Then, when the bonding film is formed on the inner side of the lid substrate, as heretofore described, the bonding film is irradiated with the laser, and the bonding film is dispersed.
Herein, when the bonding film is formed from a metal having a gettering effect, such as Al, the bonding film of Al or the like dispersed by the laser irradiation is activated, and adsorbs peripheral gas. Then, as it is possible to bring the inside of the cavity still nearer to a vacuum, it is possible to improve the equivalent resistance value of the piezoelectric vibrator. On the other hand, however, there is a danger of one portion of the dispersed bonding film adhering to the vibrating arms of the piezoelectric vibrating piece. Then, when the bonding film adheres to the vibrating arms of the piezoelectric vibrating piece, the equivalent resistance value of the piezoelectric vibrator rises. At this time, when the deterioration of the equivalent resistance value due to the adhering of the bonding film is greater than the improvement of the equivalent resistance value due to the gettering effect, there is an overall rise in the equivalent resistance value of the piezoelectric vibrator, meaning that as a result the efficiency of the piezoelectric vibrator deteriorates.
As the bonding film is exposed to the exterior at a bonding portion of the two substrates, there is a problem in that the bonding film formed from a metal such as Al corrodes, and it becomes difficult to maintain the air-tightness of the package. Therefore, in order to prevent the corrosion of the bonding film, and further improve the sealing function of the bonding film, Si may be used for the bonding film instead of a metal such as Al. Herein, when the bonding film is irradiated with the laser that has passed through the getter material, as previously described, the Si is dispersed. However, unlike a metal such as Al, Si has no gettering effect. Then, when one portion of the dispersed Si adheres to the vibrating arms of the piezoelectric vibrating piece, the equivalent resistance value of the piezoelectric vibrator rises, and the efficiency of the piezoelectric vibrator deteriorates.
Therefore, the invention has an object of providing a piezoelectric vibrator manufacturing method that curbs a dispersion of a bonding film at a time of a gettering step and with which good electrical characteristics can be obtained, and an oscillator, electronic device, and atomic timepiece, in which is mounted a piezoelectric vibrator with which good electrical characteristics can be obtained.
In order to achieve the object, a piezoelectric vibrator manufacturing method of one aspect of the invention is a manufacturing method of a piezoelectric vibrator including a base substrate and a lid substrate bonded to each other, a bonding film formed over the whole of the surface of the lid substrate that bonds to the base substrate, a cavity formed between the base substrate and the lid substrate, a piezoelectric vibrating piece sealed inside the cavity and mounted on the base substrate, and a getter material sealed inside the cavity and formed on the base substrate, the manufacturing method including a gettering step of the getter material being irradiated with a first laser penetrating the base substrate from the outer side of the base substrate, activating the getter material so that it adsorbs gas existing inside the cavity, and a frequency adjustment step of a weight metal film formed at leading ends of vibrating arms of the piezoelectric vibrating piece being irradiated with a second laser penetrating the base substrate from the outer side of the base substrate, thus adjusting the frequency of the piezoelectric vibrating piece, wherein the intensity of the first laser in the gettering step is weaker than the intensity of the second laser in the frequency adjustment step.
According to the aspect of the invention, in the gettering step, as the intensity of the first laser is weaker than the intensity of the second laser, even in the event that the first laser penetrates the getter material and reaches the bonding film formed on the lid substrate, the amount of the bonding film dispersing is small. Because of this, as it is possible to reduce the amount of the bonding film adhering to the vibrating arms of the piezoelectric vibrating piece, it is possible to curb the rise of the equivalent resistance value of the piezoelectric vibrator. Consequently, it is possible to curb the deterioration of the efficiency of the piezoelectric vibrator, and it is possible to manufacture a piezoelectric vibrator with which good electrical characteristics can be obtained.
Also, it is preferable that the first laser does not penetrate the getter material.
According to the aspect of the invention, as the first laser does not penetrate the getter material in the gettering step, the first laser does not reach the bonding film formed on the lid substrate, nor is the bonding film dispersed. Because of this, as the bonding film does not adhere to the vibrating arms of the piezoelectric vibrating piece, it is possible to reliably curb the rise of the equivalent resistance value of the piezoelectric vibrator. Consequently, it is possible to reliably curb the deterioration of the efficiency of the piezoelectric vibrator, and it is possible to manufacture a piezoelectric vibrator with which good electrical characteristics can be obtained.
Also, it is preferable to emit the first laser and second laser by using the same laser emitting device in the gettering step and the frequency adjustment step, and adjusting the laser intensity.
According to the aspect of the invention, the first laser in the gettering step and the second laser in the frequency adjustment step are emitted by using the same laser emitting device, and adjusting the laser intensity. Because of this, as it is possible to share the laser emitting device between the gettering step and the frequency adjustment step, it is possible to curb a rise in the manufacturing cost of the piezoelectric vibrator.
Also, it is preferable that the bonding film is formed from Si.
According to the aspect of the invention, as the bonding film is formed from Si, it has superior corrosion resistance compared with a case in which the bonding film is formed from a metal such as Al. Consequently, it is possible to further improve the sealing function of the bonding film. However, as Si has no gettering effect, as previously described, when the Si is dispersed by the first laser and adheres to the piezoelectric vibrating piece, the equivalent resistance value of the piezoelectric vibrator rises. In response to this, according to the aspect of the invention, either the first laser does not reach the bonding film, or the laser intensity is weak even in the event that the first laser reaches the bonding film, meaning that it is possible to curb the dispersion of the Si bonding film. Because of this, as it is possible to reduce the amount of the Si bonding film adhering to the vibrating arms of the piezoelectric vibrating piece, it is possible to curb the rise of the equivalent resistance value of the piezoelectric vibrator.
With an oscillator of another aspect of the invention, the piezoelectric vibrator manufactured using the manufacturing method is electrically connected to an integrated circuit as a resonator.
With an electronic device of another aspect of the invention, the piezoelectric vibrator manufactured using the manufacturing method is electrically connected to a timing unit.
With an atomic timepiece of another aspect of the invention, the piezoelectric vibrator manufactured using the manufacturing method is electrically connected to a filter unit.
According to the oscillator, electronic device, and atomic timepiece according to the aspects of the invention, as they include a piezoelectric vibrator manufactured using a manufacturing method with which good electrical characteristics can be obtained, it is possible to provide an oscillator, electronic device, and atomic timepiece with good performance.
According to the aspects of the invention, as the intensity of the first laser is weaker than that of the second laser in the gettering step, even in the event that the first laser penetrates the getter material and reaches the bonding film formed on the lid substrate, the amount of the bonding film dispersing is small. Because of this, as it is possible to reduce the amount of the bonding film adhering to the vibrating arms of the piezoelectric vibrating piece, it is possible to curb the rise of the equivalent resistance value of the piezoelectric vibrator. Consequently, it is possible to curb the deterioration of the efficiency of the piezoelectric vibrator, and it is possible to manufacture a piezoelectric vibrator with which good electrical characteristics can be obtained.
Hereafter, a description will be given, referring to the drawings, of a piezoelectric vibrator according to an embodiment of the invention.
Hereafter, the description will be given taking a surface of a base substrate bonded to a lid substrate as a first surface U, and the opposite surface as a second surface L.
In
As shown in
As shown in
The piezoelectric vibrating piece 4 includes the exciting electrode 15 configured of a first exciting electrode 13 and second exciting electrode 14, formed on external surfaces of the pair of vibrating arms 10 and 11, that causes the pair of vibrating arms 10 and 11 to vibrate, and the mount electrodes 16 and 17 electrically connected to the first exciting electrode 13 and second exciting electrode 14. The exciting electrode 15, mount electrodes 16 and 17, and drawing electrodes 19 and 20 are formed of a film of an electrically-conductive material such as chromium (Cr), nickel (Ni), aluminum (Al), or titanium (Ti).
The exciting electrode 15 is an electrode that causes the pair of vibrating arms 10 and 11 to vibrate at a predetermined resonance frequency in a direction approaching or moving away from each other. The first exciting electrode 13 and second exciting electrode 14 configuring the exciting electrode 15 are formed by patterning on the external surfaces of the pair of vibrating arms 10 and 11 respectively, in an electrically isolated condition. Specifically, the first exciting electrode 13 is mainly formed in the groove 18 of the one vibrating arm 10 and on both side surfaces of the other vibrating arm 11, and the second exciting electrode 14 is mainly formed on both side surfaces of the one vibrating arm 10 and in the groove 18 of the other vibrating arm 11. Also, the first exciting electrode 13 and second exciting electrode 14 are electrically connected to the mount electrodes 16 and 17, via the drawing electrodes 19 and 20 respectively, on both main surfaces of the base portion 12.
Also, the weight metal film 21 for carrying out an adjustment (frequency adjustment) of vibration condition of the pair of vibrating arms 10 and 11 in such a way as to vibrate within a predetermined frequency range is formed at the leading ends thereof. The weight metal film 21 is divided into rough adjustment films 21a, used when roughly adjusting the frequency, and fine adjustment films 21b, used when finely adjusting. By carrying out an adjustment of the frequency utilizing the rough adjustment films 21a and fine adjustment films 21b, it is possible to keep the frequency of the pair of vibrating arms 10 and 11 within the nominal frequency range of a device.
As shown in
A bonding film 35 for an anodic bonding is formed over the whole of the surface of the lid substrate 3 that bonds to the base substrate 2. That is, the bonding film 35 is formed on the peripheral frame region of the recessed portion 3a in addition to the whole of the internal surface of the recessed portion 3a. The bonding film 35 of the embodiment is formed of Si. When the bonding film 35 is formed of Si, it has superior corrosion resistance compared with a case, to be described hereafter, in which the bonding film 35 is formed from a metal such as Al. Consequently, it is possible to further improve the sealing function of the bonding film 35. Then, by the bonding film 35 and base substrate 2 being anodically bonded, as described hereafter, the cavity C is vacuum sealed.
It is also possible that the bonding film 35 is formed from a material (for example, Al) that is anodically bondable, and that may also be activated by a laser irradiation and adsorb peripheral gas (for example, oxygen). In this case, the bonding film 35 also functions as a getter material. However, the Si bonding film 35 of the embodiment is superior from the point of view of corrosion resistance.
The base substrate 2 is a substrate formed from a glass material, for example, soda-lime glass, and is formed in an approximate plate shape with the same external shape as that of the lid substrate 3, as shown in
Then, as shown in
The getter material 34, being activated by a laser irradiation and adsorbing peripheral gas, can be formed from a metal such as Al, Cr, Ti, or zirconium (Zr), or an alloy thereof, or the like. In the embodiment, the getter material 34 is formed from a metal material having Cr as a main component.
The getter material 34 is disposed in a position in which a laser irradiation from outside the piezoelectric vibrator 1 is possible. Herein, the bottom surface of the recessed portion 3a in the lid substrate 3 is an unpolished surface (frosted glass form). For this reason, even when irradiating with a laser from the exterior side of the lid substrate 3 via the recessed portion 3a, the laser diffuses, and it is not possible to adjust the focal point of the laser onto the getter material 34. Meanwhile, both surfaces of the base substrate 2 are polished in a through electrode formation step, to be described hereafter, in the condition of a base substrate wafer. For this reason, the laser irradiation is carried out from the exterior side of the base substrate 2 having polished surfaces. Because of this, the laser does not diffuse, and it is possible to adjust the focal point of the laser onto the getter material 34. Then, the getter material 34 is disposed in a position in which it does not overlap external electrodes 38 and 39, to be described hereafter, in a planar view of the base substrate 2.
Furthermore, the getter material 34 is disposed in a position in which it does not overlap the piezoelectric vibrating piece 4, in the planar view of the base substrate 2, when the piezoelectric vibrating piece 4 is mounted on the base substrate 2. In the example shown in the drawings, one pair of the getter material 34 are disposed one each on the outer sides of the pair of vibrating arms 10 and 11 in the width direction of the piezoelectric vibrating piece 4, in the planar view of the base substrate 2.
Also, a pair of through holes 30 and 31 piercing the base substrate 2 in the thickness direction, and through electrodes 32 and 33, are formed in the base substrate 2.
As shown in
The through electrode 32 is formed of a glass cylindrical body 6 and a conductive member 7 disposed inside the through hole 30, as shown in
In the embodiment, the cylindrical body 6 is one wherein a paste form glass frit is sintered. Both ends of the cylindrical body 6 are flat, and it is formed to substantially the same thickness as that of the base substrate 2. Then, the conductive material 7 is disposed in the center of the cylindrical body 6 in such a way as to pierce the cylindrical body 6. Then, the cylindrical body 6 is fixed securely to the conductive material 7 and through hole 30.
The cylindrical body 6 and conductive material 7, as well as maintaining the air tightness of the interior of the cavity C by completely blocking the through hole 30, perform a role of making a drawing electrode 36 and an external electrode 38 conductive with each other, to be described hereafter. The through electrode 33 is formed in the same way as the through electrode 32. Also, the relationship of the through electrode 33, a drawing electrode 37, and an external electrode 39 too is the same kind of relationship as that of the through electrode 32, drawing electrode 36, and external electrode 38.
As shown in
Then, a bump B is formed on each of the pair of drawing electrodes 36 and 37, and the pair of mount electrodes of the piezoelectric vibrating piece 4 are mounted utilizing the bumps B. Because of this, the one mount electrode 16 of the piezoelectric vibrating piece 4 is made conductive with the one through electrode 32 via the one drawing electrode 36, and the other mount electrode 17 is made conductive with the other through electrode 33 via the other drawing electrode 37.
Also, the pair of external electrodes 38 and 39 are formed on the second surface L of the base substrate 2, as shown in
When the piezoelectric vibrator 1 configured in this way is operated, a predetermined drive voltage is applied to the external electrodes 38 and 39 formed on the base substrate 2. Because of this, as it is possible to apply a voltage to the exciting electrode 15 formed of the first exciting electrode 13 and second electrode 14 of the piezoelectric vibrating piece 4, it is possible to cause the pair of vibrating arms 10 and 11 to vibrate at a predetermined frequency in a direction approaching or moving away from each other. Then, utilizing the vibration of the pair of vibrating arms 10 and 11, it is possible to utilize the piezoelectric vibrator 1 as a time source, a control signal timing source, a reference signal source, or the like.
Next, a description will be given, while referring to a flowchart, of the manufacturing method of the piezoelectric vibrator.
The manufacturing method of the piezoelectric vibrator according to the embodiment mainly includes a piezoelectric vibrating piece fabrication step S10, a lid substrate wafer fabrication step S20, a base substrate wafer fabrication step S30, and an assembly step (from S40 on). Of these, the piezoelectric vibrating piece fabrication step S10, lid substrate wafer fabrication step S20, and base substrate wafer fabrication step S30 can be carried out at the same time.
In the piezoelectric vibrating piece fabrication step S10, the piezoelectric vibrating piece 4 shown in
In the lid substrate wafer fabrication step S20, a lid substrate wafer 50, which is subsequently to be the lid substrate, is fabricated, as shown in
Next, in a bonding film formation step S24, the bonding film 35 shown in
In the base substrate wafer fabrication step S30, the base substrate wafer 40, which is subsequently to be the base substrate, is fabricated, as shown in
Next, a through electrode formation step S32, wherein the pair of through electrodes 32 and 33 are formed in the base substrate wafer 40, is carried out. Hereafter, the formation process of the through electrode 32 will be described, but the formation process of the through electrode 33 is the same.
Firstly, the through hole 30 is shaped from the second surface L to the first surface U of the base substrate wafer 40 by means of a pressing process, or the like. Next, the conductive member 7 is inserted into the through hole 30, and the through hole 30 is filled with a paste material formed from glass frit. Continuing, the paste material is sintered, thus integrating the glass cylindrical body 6, through hole 30, and conductive member 7. Lastly, by polishing the first surface U and second surface L of the base substrate wafer 40, giving the conductive member 7 flat surfaces while exposing it through the first surface U and second surface L, the through electrode 32 is formed inside the through hole 30. By means of the through electrode 32, at the same time as the conductivity of the first surface U side and second surface L side of the base substrate wafer 40 being ensured, it is possible to ensure air tightness inside the cavity C.
Next, a getter material formation step S34, wherein the getter material 34 is formed by patterning an electrically-conductive material on the first surface U side of the base substrate wafer 40, as shown in
In the embodiment, as previously described, the getter material 34 is formed from a metal material having Cr as the main component, and is formed by patterning a Cr layer on the first surface U of the base substrate wafer 40. When the sub-layers of the drawing electrodes 36 and 37 are formed of a Cr layer, it is possible to form the getter material 34 and the sub-layers of the drawing electrodes 36 and 37 at the same time. As shown in
Next, returning to
Next, a mounting step S40, wherein the piezoelectric vibrating piece 4 is bonded via the bumps B to the drawing electrodes 36 and 37 of the base substrate wafer 40, is carried out. Specifically, the base portion 12 of the piezoelectric vibrating piece 4 is placed on the bumps B, and the piezoelectric vibrating piece 4 is pressed against the bumps B while the bumps B are heated to a predetermined temperature. By this means, the base portion 12 is mechanically fixed to the bumps B in a condition in which the vibrating arms 10 and 11 of the piezoelectric vibrating piece 4 are raised above the first surface U of the base substrate wafer 40, as shown in
After the mounting of the piezoelectric vibrating piece 4 is finished, a superimposition step S50, wherein the lid substrate wafer 50 is superimposed on the base substrate wafer 40 as shown in
After the superimposition step S50, a bonding step S60, wherein the two wafers 40 and 50 laid one on top of the other are put into an unshown anodic bonding device and anodically bonded by applying a predetermined voltage in a predetermined temperature environment, is carried out. Specifically, the predetermined voltage is applied between the bonding film 35 and base substrate wafer 40. Then, an electrochemical reaction takes place at the interface of the bonding film 35 and base substrate wafer 40, the two adhere strongly to each other, and are anodically bonded. Because of this, it is possible to seal the piezoelectric vibrating piece 4 inside the cavity C, and it is possible to obtain a wafer body 60 shown in
Next, an external electrode formation step S70, wherein a plurality of the pairs of external electrodes 38 and 39 (refer to
Next, a gettering step S80 wherein, as shown in
As a method of determining an appropriate number of getterings, a method may be employed whereby, for example, a threshold value of a serial vibration resistance value is set in advance for each kind of piezoelectric vibrator, and the number is determined to be appropriate when the resistance value goes below the threshold value. Also, a determination may also be carried out by carrying out a gettering after storing the serial vibration resistance value immediately before the gettering, calculating the rate of change with the serial vibration resistance value immediately after the gettering, and comparing the rate of change with a pre-set value.
Next, a frequency adjustment step S90 wherein, as shown in
As a specific procedure of the frequency adjustment step S90, firstly, a predetermined voltage is continuously applied from the external electrodes 38 and 39, and the frequency is measured while causing the piezoelectric vibrating piece 4 to vibrate. Next, in this condition, an irradiation with the second laser is carried out from the exterior of the base substrate wafer 40, as shown in
The intensity of the first laser L1 in the gettering step S80 is set to be weaker than the intensity of the second laser L2 in the frequency adjustment step S90. For example, the intensity of the first laser L1 is set at around 90 percent of the intensity of the second laser L2. The reason is as follows.
The intensity of the second laser L2 in the frequency adjustment step S90 is set so that it is possible to carry out an irradiation that passes through the weight metal film 21 of the piezoelectric vibrating piece 4, as shown in
Meanwhile, in the gettering step S80, when the first laser L1 is set to an intensity equivalent to that of the second laser L2, there is a danger of the first laser L1 penetrating the getter material 34 and piezoelectric vibrating piece 4 and reaching the bonding film 35 formed on the lid substrate wafer 50, and of the bonding film 35 being dispersed. Herein, as the trimming amount of the gettering step S80 is large at approximately five times that of the trimming amount of the frequency adjustment step S90, when the first laser L1 reaches the bonding film 35, a large amount of the bonding film 35 is trimmed. Then, in the event that the dispersed bonding film 35 adheres to the vibrating arms 10 and 11 of the piezoelectric vibrating piece 4, the serial vibration resistance value of the piezoelectric vibrator 1 deteriorates due to the weight of the dispersed bonding film 35.
When the bonding film 35 is formed from Al or the like, the degree of vacuum inside the cavity C increases due to the gettering effect of the bonding film 35. As a result of this, there is a possibility of the serial vibration resistance value of the piezoelectric vibrator 1 improving. However, when the bonding film 35 is formed from Si, as in the embodiment, the bonding film 35 has no gettering effect, meaning that it does not happen either that the serial vibration resistance value of the piezoelectric vibrator 1 improves. Because of this, when the bonding film 35 is formed from Si, there is a considerable need to curb the dispersion of the bonding film.
For the above reason, in the gettering step S80, the intensity of the first laser L1 is set to be lower than the intensity of the second laser L2 so that, even supposing that the first laser L1 reaches the bonding film 35, the amount of the bonding film 35 dispersing is small. Because of this, as it is possible to reduce the amount of the bonding film 35 adhering to the vibrating arms 10 and 11 of the piezoelectric vibrating piece 4, it is possible to prevent the equivalent resistance value of the piezoelectric vibrator 1 from rising.
Furthermore, in the embodiment, the intensity of the first laser L1 is set to be lower than the intensity of the second laser L2, and so that the first laser L1 does not penetrate the getter material 34. Because of this, it does not happen that the first laser L1 reaches the bonding film 35, and it does not happen either that the bonding film 35 disperses. Consequently, as it does not happen either that the bonding film 35 adheres to the vibrating arms 10 and 11 of the piezoelectric vibrating piece 4, it is possible to reliably prevent the equivalent resistance value of the piezoelectric vibrator 1 from rising.
In the embodiment, the laser intensity is adjusted using the same laser emitting device (not shown) in the gettering step S80 and frequency adjustment step S90. Because of this, as it is possible to use the laser emitting device for both the gettering step S80 and frequency adjustment step S90, it is possible to prevent a rise in the manufacturing cost.
After the fine adjustment of the frequency is finished, a cutting step S100, wherein the bonded wafer body 60 is cut along the cutting lines M shown in
A step order wherein the frequency adjustment step S90 is carried out after dividing into individual piezoelectric vibrators by carrying out the cutting step S100 is also acceptable. However, as heretofore described, by carrying out the frequency adjustment step S90 first, it is possible to carry out the fine adjustment in the condition of the wafer body 60, meaning that it is possible to more efficiently finely adjust the plurality of piezoelectric vibrators. Therefore, this is preferable as it is possible to achieve an increase in throughput.
Subsequently, an internal electrical characteristic inspection S110 is carried out. That is, the resonance frequency, resonance resistance value, drive level characteristics (the excitation power dependence of the resonance frequency and resonance resistance value), and the like, of the piezoelectric vibrating piece 4 are measured and checked. Also, the insulation resistance characteristics, and the like, are checked at the same time. Then, lastly, an external appearance inspection of the piezoelectric vibrator is carried out, and the dimensions, quality, and the like, are checked for the last time. When this is done, the manufacture of the piezoelectric vibrator is finished.
According to the embodiment, in the gettering step S80, as the intensity of the first laser L1 is lower than the intensity of the second laser L2, as shown in
Next, a description will be given, while referring to
An oscillator 110 of the embodiment is configured as a resonator wherein the piezoelectric vibrator 1 is electrically connected to an integrated circuit 111, as shown in
In the oscillator 110 configured in this way, when a voltage is applied to the piezoelectric vibrator 1, the piezoelectric vibrating piece in the piezoelectric vibrator 1 vibrates. This vibration is converted into an electrical signal by the piezoelectric characteristics held by the piezoelectric vibrating piece, and input as the electrical signal into the integrated circuit 111. Various kinds of process are performed on the input electrical signal by the integrated circuit 111, and it is output as a frequency signal. By this means, the piezoelectric vibrator 1 functions as the resonator.
Also, for example, by selectively setting a real time clock (RTC) module, or the like, as the configuration of the integrated circuit 111 in accordance with demand, as well as a timepiece single-function oscillator, or the like, it is possible to add functions that control an operating day and time of the instrument or an external instrument, or provide a time, calendar, or the like.
According to the oscillator 110 of the embodiment, as it includes the piezoelectric vibrator 1 manufactured using a manufacturing method with which good electrical characteristics can be obtained, it is possible to provide an oscillator 110 with good performance.
Next, a description will be given, referring to
Next, a description will be given of the configuration of the portable information instrument 120 of the embodiment. The portable information instrument 120, as shown in
The controller 122, controlling each functional unit, carries out operational controls of the whole system, such as a transmission and reception of voice data, a measurement of the current time, and a display. Also, the controller 122 includes an ROM into which a program is written in advance, a CPU that reads and executes the program written into the ROM, an RAM used as a work area of the CPU, and the like.
The timing unit 123 includes an integrated circuit incorporating an oscillator circuit, a register circuit, a counter circuit, an interface circuit, and the like, and the piezoelectric vibrator 1. When a voltage is applied to the piezoelectric vibrator 1, the piezoelectric vibrating piece vibrates, and the vibration is converted into an electrical signal by the piezoelectric characteristics held by the quartz, and input as the electrical signal into the oscillator circuit. The output of the oscillator circuit is binarized, and counted by the register circuit and counter circuit. Then, a transmission and reception of a signal is carried out with the controller 122 via the interface circuit, and the current time, the current date, or calendar information, and the like, is displayed in the display unit 125.
The communication unit 124 has the same kinds of function as the heretofore known portable telephone, and includes a wireless unit 127, a voice processing unit 128, a switching unit 129, an amplification unit 130, a voice input-output unit 131, a telephone number input unit 132, a ring tone emission unit 133, and a call control memory unit 134.
The wireless unit 127 carries out a transmission and reception of various kinds of data, such as voice data, with a base station via an antenna 135. The voice processing unit 128 encodes and decodes a voice signal input from the wireless unit 127 or amplification unit 130. The amplification unit 130 amplifies a signal input from the voice processing unit 128 or voice input-output unit 131 to a predetermined level. The voice input-output unit 131, being configured of a speaker, a microphone, and the like, amplifies the ring tone or a received voice, and collects the sound of a voice.
Also, the ring tone emission unit 133 generates a ring tone in response to a call from the base station. By the switching unit 129, only at a time of an incoming call, switching the amplification unit 130 connected to the voice processing unit 128 to the ring tone emission unit 133, the ring tone generated in the ring tone emission unit 133 is output to the voice input-output unit 131 via the amplification unit 130.
The call control memory unit 134 stores a communication program relating to incoming and outgoing call control. Also, the telephone number input unit 132 includes, for example, number keys from 0 to 9 and other keys, and the telephone number or the like of a call destination is input by the number keys and the like being depressed.
When the voltage applied to each functional unit, such as the controller 122, by the power source unit 121 goes below a predetermined value, the voltage detection unit 126 detects the voltage drop, and notifies the controller 122. The predetermined voltage value at this time, being a value set in advance as a minimum voltage needed in order to stably operate the communication unit 124, is, for example, around 3V. The controller 122, on receiving the notification of the voltage drop from the voltage detection unit 126, prohibits the operation of the wireless unit 127, voice processing unit 128, switching unit 129, and ring tone emission unit 133. In particular, stopping the operation of the wireless unit 127, which has a high power consumption, is essential. Furthermore, the fact that the communication unit 124 has become unusable due to an insufficient battery level is displayed in the display unit 125.
That is, it is possible to prohibit the operation of the communication unit 124 with the voltage detection unit 126 and controller 122, and display the fact in the display unit 125. Although the display may be a written message, it is also acceptable, as a more intuitive display, to apply a x (cross) sign to a telephone icon displayed in the upper portion of the display screen of the display unit 125.
By including a power shutdown unit 136 that can selectively shut down the power of portions relating to the functions of the communication unit 124, it is possible to more reliably stop the functions of the communication unit 124.
According to the portable information instrument 120 of the embodiment, as it includes the piezoelectric vibrator 1 manufactured using a manufacturing method with which good electrical characteristics can be obtained, it is possible to provide a portable information instrument 120 with good performance.
Next, a description will be given, referring to
An atomic timepiece 140 of the embodiment, including the piezoelectric vibrator 1 electrically connected to a filter unit 141, as shown in
Within Japan, there are transmission sites (transmission stations) that transmit time calibration signals in Fukushima Prefecture (40 kHz) and Saga Prefecture (60 kHz), each of which transmits a time calibration signal. As a long wave such as one of 40 kHz or 60 kHz combines a property of being transmitted along the earth's surface and a property of being transmitted while being reflected between the ionosphere and the earth's surface, the transmission range is wide, and the two previously mentioned transmission sites cover the whole of Japan.
Hereafter, a detailed description will be given of a functional configuration of the atomic timepiece 140.
An antenna 142 receives a long wave time calibration signal of 40 kHz or 60 kHz. The long wave time calibration signal is such that time information called a time code is AM modulated into a carrier wave of 40 kHz or 60 kHz. The received long wave time calibration signal is amplified by an amplifier 143, and filtered and tuned by the filter unit 141 having a plurality of the piezoelectric vibrators 1.
The piezoelectric vibrator 1 in the embodiment includes each of quartz vibrator units 148 and 149 having resonance frequencies the same as the carrier frequencies of 40 kHz and 60 kHz.
Furthermore, a filtered signal of a predetermined frequency is detected and demodulated by a detector/rectifier circuit 144.
Continuing, the time code is extracted via a waveform shaping circuit 145, and counted in a CPU 146. Information such as the current year, accumulated days, the day of the week, and the time is read in the CPU 146. The information read is reflected in an RTC 148, and correct time information is displayed.
As the carrier wave is of 40 kHz or 60 kHz, it is preferable that the quartz vibrator units 148 and 149 are vibrators having the tuning-fork shaped structure.
The description given above shows an example from within Japan, but the frequency of the long wave time calibration signal differs overseas. For example, in Germany, a time calibration signal of 77.5 kHz is used. Consequently, when incorporating an atomic timepiece 140 that can also function overseas into the portable instrument, there is a further need for a piezoelectric vibrator 1 of a frequency differing from that when used in Japan.
According to the atomic timepiece 140 of the embodiment, as it includes the piezoelectric vibrator 1 manufactured using a manufacturing method with which good electrical characteristics can be obtained, it is possible to provide an atomic timepiece 140 with good performance.
The invention is not limited to the heretofore described embodiments.
In the embodiments, a description of the manufacturing method is given citing an example of a piezoelectric vibrator using a tuning fork-shaped piezoelectric vibrating piece. However, the manufacturing method of the embodiments may also be employed for a piezoelectric vibrator using, for example, an AT cut type of piezoelectric vibrating piece (a thickness-shear vibrating piece).
In the embodiments, the getter material and the bonding film are formed from differing materials—the getter material being formed from Cr and the bonding film being formed from Si—but both may be formed from the same material. However, as the corrosion resistance improves when the bonding film is formed from Si, the embodiments are superior.
In the embodiments, a green laser (wavelength 532 nm) is employed as the first laser and second laser. However, a laser of a different wavelength may be employed. However, the green laser of the embodiments is superior in that it is excellent for microfabrication.
In the embodiments, the irradiation with the first laser in the gettering step and with the second laser in the frequency adjustment step is carried out using the same laser emitting device. However, the first laser and second laser may be emitted from separate laser emitting devices. By having separate laser emitting devices, there is no longer a need to adjust the laser intensities of the first laser and second laser. Consequently, it is possible to reduce manufacturing man-hours. However, from the point of view of the manufacturing facility cost, the embodiments, wherein the laser emitting device is shared, are superior.
Number | Date | Country | Kind |
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2010-003352 | Jan 2010 | JP | national |