DEVELOPING APPARATUS AND METHOD
A developing apparatus for developing a substrate whose surface is coated with a coating solution and then exposed includes a substrate supporting unit for horizontally supporting the substrate, a rotation driving mechanism for rotating the substrate supporting unit forwardly or backwardly with respect to a vertical axis, a developer nozzle, disposed to face a surface of the substrate supported by the substrate supporting unit, having a strip-shaped injection opening extended along a direction extending from a periphery of the substrate toward a central portion thereof, a moving unit for moving the developer nozzle from an outer portion of the substrate toward the central portion thereof, and a controller for controlling operations such that while the substrate is rotated forwardly by the rotation driving mechanism, a developer is supplied through the injection opening to the surface of the substrate by moving the developer nozzle and, then, the substrate is rotated backwardly by the rotation driving mechanism.
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This application is a divisional of U.S. Ser. No. 11/201,102 filed Aug. 11, 2005, the entire content of which is incorporated herein by reference and claims priority under 35 U.S.C. 119 to Japanese Application No. 2004-241442 filed on Aug. 20, 2004.
FIELD OF THE INVENTIONThe present invention relates to a developing apparatus and method, for developing a surface of a substrate coated with a resist and exposed to light.
BACKGROUND OF THE INVENTIONIn a photoresist process, one of the semiconductor manufacturing processes, a resist coated on a surface of a semiconductor wafer (hereinafter, referred to as a wafer) is exposed to light by employing a specified pattern and then developed, thereby forming a resist pattern on the surface of the wafer. Such process is generally carried out by using a system in which an exposure device is combined with a coating/developing apparatus for coating and developing a resist.
As illustrated in
Moreover, there has been known a technique: a developer is supplied to a wafer W whose surface is coated with a resist having a pattern portion extending in a direction intersecting a rotational direction of the wafer W that is rotating about a vertical axis, and the wafer W is rotated forwardly and backwardly, whereby a resist layer on a sidewall surface of the pattern, that has to be eliminated, is made to be surely removed (see, for example, Japanese Patent Laid-open Publication Nos. 2002-075854 and 2003-272988).
However, the aforementioned developing method has following drawbacks. Since the developer is supplied while the wafer W is rotated about the vertical axis, the developer flows outwardly from the central portion along a parabolic trace in a direction opposite to that of the rotation of the wafer W on the surface of the wafer W. Depending on a shape or layout of a pattern transcribed on a resist by an exposure, when the pattern begins to be revealed due to a contact with the developer, the pattern may hinder the flow of the solution. Accordingly, the developer may not uniformly reach all over the pattern, especially over a downstream side portion of the pattern, thereby deteriorating the accuracy in realizing a precise line width. But, since a nonsmooth solution flow causes only a very slight deterioration in the accuracy in realizing a precise line width and, thus, it was not conventionally considered to be much a problem. However, along with a recent trend of a pattern's miniaturization, it becomes imperative to make the solution flow smooth to achieve a higher degree of accuracy in realizing a precise line width.
Hereinafter, there will be described an exemplary pattern, which is subject to a nonsmooth solution flow. When patterns of multiple chips are transcribed on a surface of a wafer W by an exposure, the patterns are successively transcribed, for example, by moving the wafer W with respect to an exposure device. Thus, the multiple chips are transcribed on the surface of the wafer W along a same direction. The patterns of the chips vary depending on purposes. However, as schematically illustrated in
It is, therefore, an object of the present invention to provide a developing apparatus and method, whereby when a substrate whose surface has a resist coated thereon and is exposed to light is rotated and provided with the developer, a developer flow can be controlled on the substrate and a pattern having a high in-surface uniformity can be formed.
In accordance with one aspect of the invention, there is provided a developing apparatus for developing a substrate whose surface is coated with a coating solution and then exposed, the apparatus including a substrate supporting unit for horizontally supporting the substrate; a rotation driving mechanism for rotating the substrate supporting unit forwardly or backwardly with respect to a vertical axis; a developer nozzle, disposed to face a surface of the substrate supported by the substrate supporting unit, having a strip-shaped injection opening extended along a direction extending from a periphery of the substrate toward a central portion thereof; a moving unit for moving the developer nozzle from an outer portion of the substrate toward the central portion thereof; and a controller for controlling operations such that while the substrate is rotated forwardly by the rotation driving mechanism, a developer is supplied through the injection opening to the surface of the substrate by moving the developer nozzle and, then, the substrate is rotated backwardly by the rotation driving mechanism.
Preferably, patterns of chips may be regularly formed on a resist of the surface of the substrate, and each of the chips has a dense pattern portion and a sparse pattern portion. Further, when the substrate is rotated backwardly, the controller may control the developer to be discharged through the injection opening onto the central portion of the substrate. Furthermore, when the substrate is rotated backwardly, the controller may control the developer nozzle to move from the outer portion of the substrate toward the central portion thereof while discharging the developer through the injection opening. Moreover, when the rotation of the substrate is converted from the forward direction to the backward direction, the substrate may be stopped momentarily.
In accordance with another aspect of the invention, there is provided a developing apparatus for developing a substrate whose surface is coated with a coating solution and then exposed, the apparatus including a substrate supporting unit for horizontally supporting the substrate; a rotation driving mechanism for rotating the substrate supporting unit with respect to a vertical axis; a developer nozzle, disposed to face a surface of the substrate supported by the substrate supporting unit, having a strip-shaped injection opening extended along a direction extending from a periphery of the substrate toward a central portion thereof, the injection opening being inclined toward the central portion of the substrate; a moving unit for moving the developer nozzle from an outer portion of the substrate toward the central portion thereof; and a fluid supply nozzle, disposed to face the surface of the substrate supported by the substrate supporting unit, for supplying a fluid to push the developer supplied from the developer nozzle to the central portion of the substrate; and a moving mechanism for moving the fluid supply nozzle from the outer portion of the substrate toward the central portion thereof along with the developer nozzle. For example, the fluid may be a diluted developer or a gas.
In accordance with still another aspect of the invention, there is provided a developing apparatus for developing a substrate whose surface is coated with a coating solution and then exposed, the apparatus including a substrate supporting unit for slantingly supporting the substrate at an inclined angle; a rotation driving mechanism for rotating the substrate supporting unit with respect to a perpendicular axis; a developer nozzle, disposed to face a surface of the substrate supported by the substrate supporting unit, having a strip-shaped injection opening extended along a direction extending from a periphery of the substrate toward a central portion thereof; a moving unit for moving the developer nozzle from an outer portion of the substrate toward the central portion thereof; and a controller for controlling operations such that while the substrate is rotated forwardly by the rotation driving mechanism, a developer is supplied through the injection opening to the surface of the substrate by moving the developer nozzle. The inclined angle may range from, e.g., 1° to 10°.
In accordance with still another aspect of the invention, there is provided a developing apparatus for developing a substrate whose surface is coated with a coating solution and then exposed, the apparatus including a substrate supporting unit for horizontally supporting the substrate; a rotation driving mechanism for rotating the substrate supporting unit with respect to a vertical axis, which is provided at an eccentric position on the substrate; a developer nozzle, disposed to face a surface of the substrate supported by the substrate supporting unit, having a strip-shaped injection opening extended along a direction extending from a periphery of the substrate toward a central portion thereof; a moving unit for moving the developer nozzle from one end portion of the substrate toward the other end portion thereof, the end portions being positioned on a straight line passing through the eccentric position and the center of the substrate; and a controller for controlling operations such that the substrate is oscillated left and right by the rotation driving mechanism and a developer is supplied through the injection opening to the surface of the substrate by moving the developer nozzle.
In accordance with still another aspect of the invention, there is provided a developing method for developing a substrate whose surface is coated with a coating solution and then exposed, the method including the steps of horizontally supporting a bottom surface of the substrate by using a substrate supporting unit; rotating the substrate supported by the substrate supporting unit forwardly with respect to a vertical axis; discharging a developer through a strip-shaped injection opening provided at the developer nozzle onto a surface of the substrate while moving the developer nozzle, the injection opening extended along a direction extending from a periphery of the substrate to a central portion thereof; and rotating the substrate supported by the substrate supporting unit backwardly with respect to the vertical axis after the developer nozzle reaches the central portion of the substrate.
Preferably, patterns of chips may be regularly formed on a resist of the surface of the substrate, and each of the chips has a dense pattern portion and a sparse pattern portion. Further, when the substrate supported by the substrate supporting unit is rotated backwardly with respect to the vertical axis, the developer is discharged through the injection opening to the central portion of the substrate. Furthermore, when the substrate supported by the substrate supporting unit is rotated backwardly with respect to the vertical axis, the developer nozzle is moved from the outer portion of the substrate toward the central portion thereof while discharging the developer through the injection opening. Moreover, when the rotation of substrate is converted from the forward rotation to the backward rotation, the substrate is stopped momentarily.
In accordance with still another aspect of the invention, there is provided a developing method for developing a substrate whose surface is coated with a coating solution and then exposed, the method including the steps of horizontally supporting a bottom surface of the substrate by using a substrate supporting unit; rotating the substrate supported by the substrate supporting unit around a vertical axis; moving a developer nozzle facing a surface of the substrate from an outer portion of the substrate toward a central portion thereof; discharging a developer through a strip-shaped injection opening provided at the developer nozzle onto a surface of the substrate while moving the developer nozzle, the injection opening extended along a direction extending from a periphery of the substrate to the central portion thereof; and supplying fluid from a fluid supply nozzle to the surface of the substrate, wherein the fluid supply nozzle moves along with the developer nozzle and the fluid is for pushing the developer, which is supplied from the developer nozzle to the surface of the substrate, toward the central portion of the substrate. For example, the fluid may be a diluted developer or a gas.
In accordance with still another aspect of the invention, there is provided a developing method for developing a substrate whose surface is coated with a coating solution and then exposed, the method including the steps of slantingly supporting the substrate a bottom surface of the substrate at an inclined angle by using a substrate supporting unit; rotating the substrate supported by the substrate supporting unit with respect to a perpendicular axis; moving a developer nozzle facing a surface of the substrate from an outer portion of the substrate toward a central portion thereof; and discharging a developer from a strip-shaped injection opening provided at the developer nozzle onto a surface of the substrate, the injection opening extended along a direction extending from a periphery of the substrate to the central portion thereof. The inclined angle may range from, e.g., 1° to 10°.
In accordance with still another aspect of the invention, there is provided a developing method for developing a substrate whose surface is coated with a coating solution and then exposed, the method including the steps of horizontally supporting the substrate on a backside thereof by using a substrate supporting unit; oscillating the substrate supported by the substrate supporting unit left and right with respect to a vertical axis, which is provided at an eccentric position on the substrate; moving a developer nozzle facing a surface of the substrate from one end portion of the substrate toward the other end portion thereof, the end portions being positioned on the straight line passing through the eccentric position and the center of the substrate; and discharging a developer through a strip-shaped injection opening provided at the developer nozzle onto a surface of the substrate while moving the developer nozzle, the injection opening extended along a direction extending from a periphery of the substrate to a central portion thereof.
In accordance with the present invention, after the developer is supplied in a spiral shape while the wafer W is rotated forwardly, the wafer W is then rotated backwardly. Accordingly, a flow pattern of the developer is changed on the wafer W, so that the developer can uniformly reach all over the fine pattern in comparison with one-way flow of the developer. As a result, the developer can reach all fine parts of the pattern, thereby producing a pattern of a highly uniform line width after a developing process.
Moreover, the flow pattern of the developer on the substrate surface can be changed also in cases where: a developer is supplied through an injection opening inclined toward a central portion of the substrate and then pushed toward the central portion thereof by fluid supplied along behind the developer; the substrate is supported in an inclined state; and the substrate is oscillated left and right around an eccentric position on the substrate. As a result, the aforementioned effects of the present invention can be also realized in these cases.
The above and other objects and features of the present invention will become apparent from the following description of preferred embodiments, given in conjunction with the accompanying drawings, in which:
A developing apparatus in accordance with a preferred embodiment of the present invention will be described with reference to
A circular plate 34 is provided under the wafer W supported by the spin chuck 2, and a liquid-receiving section 35 having a recessed cross section is installed to surround the whole circular plate 34. Further, a drain port 36 is formed at a bottom of the liquid-receiving section 35. Furthermore, a ring member 37 having a mountain-shaped cross section is installed at the outside of the circular plate 34. Although it is not shown, there are provided three elevating pins, serving as substrate supporting pins, penetrating through the circular plate 34. The wafer W is transferred on the spin chuck 2 by operating a substrate transfer mechanism (not shown) as well as the elevating pins.
Installed above the wafer W supported by the spin chuck 2 is a vertically and horizontally movable developer nozzle 4 facing a surface of the wafer W. Hereinafter, the developer nozzle 4 will be described in detail with reference to
To be more specific, as depicted in
Referring back to
A vertically and horizontally movable rinse nozzle 6 having a small injection hole 60 for discharging a rinse, e.g., pure water, is installed to face the surface of the wafer W. The rinse nozzle 6 is connected to one end of a supply line, e.g., a rinse line 63. Meanwhile, the other end of the rinse line 63 is connected to a rinse supply source 62. Installed in the middle of the rinse line 63 is a liquid transfer unit (not shown), e.g., a bellows pump capable of controlling a discharge flow rate by changing a discharge stroke, and the like. Besides, the rinse nozzle 6 is connected to a moving platform 64 having an elevating mechanism (not shown) via the nozzle arm 63, and the moving platform 64 can move horizontally along the guide member 52. A reference numeral 65 indicates a standby section of the rinse nozzle 6.
A reference numeral 7 indicates a controller, and the controller 7 controls operations of the driving mechanism 22, the elevator 33 and the moving platforms 51 and 64. To be specific, the controller 7 can perform following operations: while the wafer W is rotated forwardly by the driving mechanism 22, a developer is supplied through the injection opening 41 to the surface of the wafer by moving the developer nozzle 4 from the outside of the substrate toward the center thereof and, then, the wafer W is rotated backwardly by the driving mechanism 22 thereafter. Further, the controller 7 controls temperatures of the main temperature control unit 45 and the double pipe 47 serving as an auxiliary temperature control unit so that the developer supplied to the surface of the wafer W is kept at a specified temperature, e.g., 5° C.-60° C. To be more specific, information on temperature setting values of the developer that are set corresponding to the kinds of resists is stored in a storage unit, e.g., a memory, included in the control unit 7, and a temperature setting value of the developer is determined within a range of 5° C.-60° C. based on the kind of a resist coated on the wafer W to be developed. In other words, the temperature of the developer is controlled based on resist solubility in the developer. Further, if temperature setting values of the developer can be determined based on the respective resists kinds, the memory of the control unit 7 does not necessarily store therein such information and, for example, an operator may input the temperature setting values via an input unit of the control unit 7.
There will be now described exemplary temperature setting values of the developer corresponding to resist kinds. For instance, as for a KrF resist, if there is provided a resist having a low solubility in the developer, the temperature setting value of the developer is set to range from 40° C. to 60° C. Further, as for an ArF resist under consideration for availability, if there is provided a resist having a high solubility in the developer, the temperature setting value of the developer is set to range from 20° C. to 40° C. Besides, if there is provided a resist for an I-ray source, a G-ray source or the like, having a higher solubility at a low temperature, the temperature setting value is set to range from 10° C. to 20° C. Typically, a resist solubility speed is used for distinguishing a KrF resist from an ArF resist. But, the temperature of the developer is determined by examining a temperature at which the solubility of the resist is promoted, not depending on whether a resist is the KrF resist or the ArF resist.
Hereinafter, an exemplary pattern transcribed by an exposure to light on a surface of a substrate, e.g., wafer W, to be developed by the aforementioned developing apparatus will be described with reference to
Hereinafter, a process for developing a substrate, e.g., a wafer by using the developing apparatus will be described with reference to
Next, the outer cup 31 is elevated. Further, as described in
Thereafter, as shown in
As illustrated in
At this time, since the wafer W is rotating, the developer spreads outwardly on the surface of the wafer W due to a centrifugal force, thereby forming a thin liquid film on the surface of the wafer W. Further, a soluble portion of the resist is dissolved in the developer and, then, an insoluble portion remains to form a pattern. To be precise, even if adjacent streams of the developer, which is discharged in a strip shape, have a slight gap therebetween or are overlapped partially while supplying the developer, the developer streams are merged by the rotation of the wafer W, which is included in the present invention.
After the developer is discharged through the developer nozzle 4 to the central portion, e.g., for a specified time period, the developer nozzle 4 stops discharging and is quickly retreated. Next, as illustrated in
The rinse supplied to the surface of the wafer W spreads outwardly on the surface thereof due to a centrifugal force of the wafer W′s rotation and washes away the developer containing the dissolved resist on the surface of the wafer W, thereby cleaning the surface of the wafer W. Once the rinse nozzle 6 stops discharging the rinse and is retreated, then, as shown in
In accordance with the aforementioned embodiment, after the developer is supplied in a spiral shape while the wafer W being rotated forwardly, the wafer W is then rotated backwardly. Accordingly, a flow pattern of the developer is changed on the wafer W, so that the developer can reach all over the fine pattern much more uniformly in comparison with one-way flow of the developer. To be more specific, as illustrated in
Hereinafter, a developing apparatus in accordance with another preferred embodiment of the present invention will be described with reference to
In such configuration, the developer nozzle 4 will scan through the surface of the wafer W while the developer D being discharged through the injection opening 41 and, at the same time, the fluid supply nozzle 8 will scan through by following the scanning of the developer nozzle 4 while a fluid, e.g., a diluted developer or a nonreactive gas such as a nitrogen gas, being discharged through the injection opening 80 (see
Hereinafter, a developing apparatus in accordance with still another preferred embodiment of the present invention will be described with reference to
In this case, although the wafer W is developed in the same sequence as in the aforementioned embodiment, since the wafer W is slantingly supported, the developer D flows downwardly along the inclined surface, as schematically illustrated in
Hereinafter, a developing apparatus in accordance with still another embodiment of the present invention will be described with reference to
As depicted in
In the present invention, the substrate can be, e.g., an LCD substrate and a reticle substrate for photomask without being limited to the wafer W. Further, the aforementioned configuration of the developer nozzle 4 can be applied to a coating solution nozzle for coating a resist on a substrate, for example.
Finally, an exemplary coating/developing apparatus accommodating therein the aforementioned developing apparatus will be briefly described with reference to
A processing section B2 surrounded by a housing 92 is connected to the carrier mounting section B1. Alternately installed in the processing section B2 are rack units U1, U2 and U3, each having heating and cooling units in multiple levels, and main transfer mechanisms A2 and A3 for transferring the wafer W between processing units including coating and developing units to be described later. In other words, the rack units U1, U2 and U3 and the main transfer mechanisms A2 and A3 are alternately arranged in line and, further, openings (not shown) for transferring the wafer W are formed at connecting portions therebetween. Thus, the wafer W can be easily moved from the rack unit U1 provided at one end portion to the rack unit U3 provided at the other end portion in the processing section B2. Further, the main transfer mechanisms A2 and A3 are provided in a space surrounded by surface portions of rack units U1, U2 and U3 arranged in line; surface portions of liquid processing units U4 and U5 to be described later; and partition walls 93. Reference numerals 94 and 95 indicate temperature/humidity control units for a processing liquid used in each unit, having a temperature controller, a temperature/humidity control duct or the like.
As shown in
An exposing section B4 is connected to the rack unit U3 of the processing section B2 via an interface section B3 including, e.g., a first transfer chamber 97 and a second transfer chamber 98. Installed inside the interface section B3 are two transfer mechanisms A4 and A5 for transferring the wafer W between the processing section B2 and the exposing section B4; a rack unit U6; and a buffer carrier C0.
There will be explained an exemplary wafer flow in the coating/developing apparatus. First of all, when the carrier C1 having therein the wafers W is mounted onto the mounting table 90, the opening/closing members 91 are opened and, at the same time, lids of the carriers C1 are removed, so that the wafers W can be unloaded by a transfer mechanism A1. Next, the wafer W is transferred to the main transfer mechanism A2 via a transfer unit (not shown) that occupies one level of the rack unit U1. Then, a pre-treatment of a coating process, e.g., an anti-reflective film forming process, is performed in the BARC, and a cooling process is carried out in one unit of the rack units U1 to U3. Thereafter, the resist solution is coated in the coating unit COT. Next, the wafer W is heated (baked) in the heating unit forming one unit of the rack units U1 to U3 and then cooled in the cooling unit to be loaded into the interface section B3 via a transfer unit of the rack unit U3. In the interface section B3, the wafer W is transferred through a transfer path of the transfer mechanism A4→the rack unit U6→the transfer mechanism A5 to the exposing section B4, wherein an exposure process is performed thereon. After the exposure process is completed, the wafer W is transferred to the main transfer mechanism A2 along the transfer path in a reversed order to be developed in the developing unit DEV, thereby forming a resist mask thereon. Thereafter, the wafer W returns to the original carrier C1 on the mounting table 90.
While the invention has been shown and described with respect to the preferred embodiments, it will be understood by those skilled in the art that various changes and modification may be made without departing from the spirit and scope of the invention as defined in the following claims.
Claims
1. A developing method for developing a substrate whose surface is coated with a coating solution and then exposed, the method comprising the steps of:
- horizontally supporting a bottom surface of the substrate by using a substrate supporting unit;
- rotating the substrate supported by the substrate supporting unit forwardly with respect to a vertical axis;
- discharging a developer through a strip-shaped injection opening provided at the developer nozzle onto a surface of the substrate while moving the developer nozzle, the injection opening extended along a direction extending from a periphery of the substrate to a central portion thereof; and
- rotating the substrate supported by the substrate supporting unit backwardly with respect to the vertical axis after the developer nozzle reaches the central portion of the substrate.
2. The developing method of claim 1, wherein patterns of chips are regularly formed on a resist of the surface of the substrate, and each of the chips has a dense pattern portion and a sparse pattern portion.
3. The developing method of claim 1, wherein when the substrate supported by the substrate supporting unit is rotated backwardly with respect to the vertical axis, the developer is discharged through the injection opening to the central portion of the substrate.
4. The developing method of claim 1, wherein when the substrate supported by the substrate supporting unit is rotated backwardly with respect to the vertical axis, the developer nozzle is moved from the outer portion of the substrate toward the central portion thereof while discharging the developer through the injection opening.
5. The developing method of claim 1, wherein when the rotation of substrate is converted from the forward rotation to the backward rotation, the substrate is stopped momentarily.
6. A developing method for developing a substrate whose surface is coated with a coating solution and then exposed, the method comprising the steps of:
- horizontally supporting a bottom surface of the substrate by using a substrate supporting unit;
- rotating the substrate supported by the substrate supporting unit around a vertical axis;
- moving a developer nozzle facing a surface of the substrate from an outer portion of the substrate toward a central portion thereof;
- discharging a developer through a strip-shaped injection opening provided at the developer nozzle onto a surface of the substrate while moving the developer nozzle, the injection opening extended along a direction extending from a periphery of the substrate to the central portion thereof; and
- supplying fluid from a fluid supply nozzle to the surface of the substrate, wherein the fluid supply nozzle moves along with the developer nozzle and the fluid is for pushing the developer, which is supplied from the developer nozzle to the surface of the substrate, toward the central portion of the substrate.
7. The developing method of claim 6, wherein the fluid is a diluted developer.
8. The developing method of claim 6, wherein the fluid is a gas.
9. A developing method for developing a substrate whose surface is coated with a coating solution and then exposed, the method comprising the steps of:
- slantingly supporting the substrate a bottom surface of the substrate at an inclined angle by using a substrate supporting unit;
- rotating the substrate supported by the substrate supporting unit with respect to a perpendicular axis;
- moving a developer nozzle facing a surface of the substrate from an outer portion of the substrate toward a central portion thereof; and
- discharging a developer from a strip-shaped injection opening provided at the developer nozzle onto a surface of the substrate, the injection opening extended along a direction extending from a periphery of the substrate to the central portion thereof.
10. The developing method of claim 9, wherein the inclined angle ranges from 1° to 10°.
11. A developing method for developing a substrate whose surface is coated with a coating solution and then exposed, the method comprising the steps of:
- horizontally supporting the substrate on a backside thereof by using a substrate supporting unit;
- oscillating the substrate supported by the substrate supporting unit left and right with respect to a vertical axis, which is provided at an eccentric position on the substrate;
- moving a developer nozzle facing a surface of the substrate from one end portion of the substrate toward the other end portion thereof, the end portions being positioned on the straight line passing through the eccentric position and the center of the substrate; and
- discharging a developer through a strip-shaped injection opening provided at the developer nozzle onto a surface of the substrate while moving the developer nozzle, the injection opening extended along a direction extending from a periphery of the substrate to a central portion thereof.
Type: Application
Filed: Aug 26, 2010
Publication Date: Dec 23, 2010
Applicant: TOKYO ELECTRON LIMITED (Tokyo)
Inventors: Taro Yamamoto (Kikuchi-gun), Atsushi Ookouchi (Kikuchi-gun), Hirofumi Takeguchi (Kikuchi-gun), Kousuke Yoshihara (Kikuchi-gun)
Application Number: 12/869,446