JP4165844B2 - Vibration isolator - Google Patents

Description

【００２３】
（２）式において、左辺の圧力ｐに掛かる係数ωは空気ばね５の機械的パラメータから定まる物理量である。また、右辺の空気弁駆動量ｕに掛かる係数Ｇ_q は空気弁４の圧力ゲインである。同じく右辺で除振台１の変位ｘを含む項は変位ｘによって空気ばね５の圧力ｐが変化することを表わしており、Ｇ_v はその影響係数である。（１）式および（２）式をラプラス変換することにより、図２の動力学モデルを数学的に示した図３のブロック線図が得られる。図３において、記号ｓはラプラス演算子を表わす。図３より、入力を空気弁駆動量ｕおよび外乱力ｆ、出力を除振台１の変位ｘとした入出力式は（３）式のようになる。（３）式においては、左辺のＡＧ_v ｓ／（ｓ＋ω）が空気ばね５の剛性を表わしている。
【００２４】
【数２】

【００２５】
本実施例による除振装置の動作を数学的に示したブロック線図が図４である。図４は剛性補償器８の動作を説明するのに必要十分な要素のみを示しており、変位補償器９、加速度補償器１０など他の構成要素は省略している。図４において圧力補償器１２は比例演算器でありそのゲインをＧとする。また剛性補償器８の伝達関数をＧ_k とする。入力を外乱力ｆ、出力を除振台１の変位ｘとした図４の入出力式は（４）式のとおりである。
【００２６】
【数３】

【００２７】
もしも剛性補償器８がなくてＧ_k ＝０であったとしたら、（４）式の入出力式は（５）式のようになる。この場合、空気ばね５の剛性を表わす剛性項は（５）式の左辺よりＡＧ_v ｓ／（ｓ＋ω＋Ｇ_q Ｇ）であるが、圧力補償器１２のゲインＧが剛性項の分母にあるので、ゲインＧが大きいほど剛性項は小さくなる。つまり、圧力のフィードバックループのゲインＧを大きくするほど空気ばね５の剛性は低下することが（５）式からわかる。
【００２８】
【数４】

【００２９】
剛性補償器８は圧力のフィードバック制御による空気ばね５の剛性低下を回避するように機能する。（４）式からわかるように、剛性補償器８の動作によって、空気ばね５の剛性項はＡＧ_v ｓ／（ｓ＋ω＋Ｇ_q Ｇ）＋ＡＧ_v ／（ｓ＋ω＋Ｇ_q Ｇ）ｘＧ_q ＧＧ_k ／Ｇ_v となっている。すなわち、剛性補償器８の伝達関数Ｇ_k を大きくとるほど剛性項も大きくなるので、空気ばね５にとって必要な剛性が確保できる。伝達関数Ｇ_k は、具体的には次のように設計すればよい。まず、圧力のフィードバック制御を行なわない場合、空気ばね５の剛性項は（３）式左辺よりＡＧ_v ｓ／（ｓ＋ω）であった。伝達関数Ｇ_k は、本発明による除振装置の入出力式である（４）式の剛性項がこれに一致するように設計する。（３）式と（４）式を比較すれば、剛性補償器８の伝達関数Ｇ_k は（６）式のように定まる。
【００３０】
【数５】

【００３１】
（６）式で定めた伝達関数Ｇ_k を本実施例による除振装置の入出力式である（４）式に代入すると（７）式が得られる。（７）式の左辺と、圧力のフィードバック制御を行なわない場合の入出力式である（３）式の左辺は全く同一である。剛性補償器８の動作によって、圧力のフィードバック制御を行なわない場合と全く同一な空気ばね５の剛性を確保できることがわかる。また、（６）式で示される剛性補償器８の伝達関数Ｇ_k はローカットフィルタを表わす伝達関数ｓ／（ｓ＋ω) と比例ゲインＧ_v （ω＋Ｇ_q Ｇ）／Ｇ_q Ｇとの直列結合で構成されている。本実施例による除振装置は、剛性補償器８がローカットフィルタ１４と比例ゲイン要素１５を有することを特徴としている。
【００３２】
【数６】

【００３３】
このように、剛性補償器８の動作によって空気ばね５の剛性低下を回避することができるので、本実施例による除振装置は好適な振動抑制性能を実現している。
なお、本発明による除振装置は図１に示した実施形態に限定されるものではない。空気ばねの剛性低下を生じることなく空気ばねの圧力のフィードバック制御を行なうことができる除振装置であるという本発明の本質は、除振台の形状やそれを支持する空気ばねの台数と配置などを問わず実施できる。また、本発明による除振装置を有する半導体製造装置は、逐次駆動型、走査型のいずれにおいても実現できる。
【００３４】
これまで用いた数式記号を次にまとめて列記する。
Ｍ：除振台１の質量
Ａ：空気ばね５の有効受圧面積
ｘ：除振台１の変位
ｐ：空気ばね５の圧力
ｕ：空気弁駆動量
ｆ：除振台１に作用する外乱力
ω：空気ばね５の機械的パラメータから定まる物理量
Ｇ_q ：空気弁４の圧力ゲイン
Ｇ_v ：除振台１の変位ｘから空気ばね５の圧力ｐへの影響係数
Ｇ：圧力補償器１２が比例演算器であるときのゲイン
Ｇ_k ：剛性補償器８の伝達関数
【００３５】
【デバイス生産方法の実施例】
次に上記説明した除振装置を有する露光装置を利用したデバイスの生産方法の実施例を説明する。
図８は微小デバイス（ＩＣやＬＳＩ等の半導体チップ、液晶パネル、ＣＣＤ、薄膜磁気ヘッド、マイクロマシン等）の製造のフローを示す。ステップ１（回路設計）ではデバイスのパターン設計を行なう。ステップ２（マスク製作）では設計したパターンを形成したマスクを製作する。一方、ステップ３（ウエハ製造）ではシリコンやガラス等の材料を用いてウエハを製造する。ステップ４（ウエハプロセス）は前工程と呼ばれ、上記用意したマスクとウエハを用いて、リソグラフィ技術によってウエハ上に実際の回路を形成する。次のステップ５（組み立て）は後工程と呼ばれ、ステップ４によって作製されたウエハを用いて半導体チップ化する工程であり、アッセンブリ工程（ダイシング、ボンディング）、パッケージング工程（チップ封入）等の工程を含む。ステップ６（検査）ではステップ５で作製された半導体デバイスの動作確認テスト、耐久性テスト等の検査を行なう。こうした工程を経て半導体デバイスが完成し、これが出荷（ステップ７）される。
【００３６】
図９は上記ウエハプロセスの詳細なフローを示す。ステップ１１（酸化）ではウエハの表面を酸化させる。ステップ１２（ＣＶＤ）ではウエハ表面に絶縁膜を形成する。ステップ１３（電極形成）ではウエハ上に電極を蒸着によって形成する。ステップ１４（イオン打込み）ではウエハにイオンを打ち込む。ステップ１５（レジスト処理）ではウエハに感光剤を塗布する。ステップ１６（露光）では上記説明した除振装置を有する露光装置によってマスクの回路パターンをウエハに焼付露光する。ステップ１７（現像）では露光したウエハを現像する。ステップ１８（エッチング）では現像したレジスト像以外の部分を削り取る。ステップ１９（レジスト剥離）ではエッチングが済んで不要となったレジストを取り除く。これらのステップを繰り返し行なうことによって、ウエハ上に多重に回路パターンが形成される。
本実施例の生産方法を用いれば、従来は製造が難しかった高集積度のデバイスを低コストに製造することができる。
【００３７】
【発明の効果】
以上説明したように、本発明によれば、空気ばねの剛性を低下させずに空気ばねの圧力のフィードバック制御を行なうことができる除振装置を提供することができる。本発明による除振装置においては、圧力のフィードバック制御が空気弁の非線形特性を補正し、空気ばねの圧力の定位性を改善する。同時に、従来技術で問題となっていた空気ばねの剛性低下は生じないので、好適な振動抑制性能を実現することができる。
【図面の簡単な説明】
【図１】 本発明の一実施例に係る除振装置の構成図である。
【図２】 除振台と空気ばねの動力学モデルを示す図面である。
【図３】 除振台と空気ばねの動力学モデルを数学的に示す図面である。
【図４】 本発明による除振装置の動作を数学的に示す図面である。
【図５】 従来技術による除振装置を示す図面である。
【図６】 空気弁の構造を示す図面である。
【図７】 空気弁の特性を示す図面である。
【図８】 微小デバイスの製造の流れを示す図である。
【図９】 図８におけるウエハプロセスの詳細な流れを示す図である。
【符号の説明】
１：除振台、２：変位センサ、３：圧力センサ、４：空気弁、５：空気ばね、６：加速度センサ、７：変位目標生成器、８：剛性補償器、９：変位補償器、１０: 加速度補償器、１１: 圧力目標生成器、１２: 圧力補償器、１３：パワー増幅器、１４：ローカットフィルタ、１５：比例ゲイン要素。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an anti-vibration apparatus for reducing vibration transmission from an apparatus installation base in a precision instrument such as an exposure apparatus used for manufacturing a semiconductor device such as an IC, LSI, or CCD, or a liquid crystal device such as a liquid crystal panel.
[0002]
[Prior art]
As precision instruments such as electron microscopes and semiconductor manufacturing equipment become more precise, there is a need for higher performance of precision vibration isolation devices that mount them. In particular, in a semiconductor manufacturing apparatus, a vibration isolator that eliminates vibrations transmitted from the outside such as installation floor vibrations as much as possible is necessary in order to perform appropriate and rapid exposure. This is because, in the semiconductor manufacturing apparatus, the exposure XY stage must be completely stopped when the semiconductor wafer is exposed. Further, since the XY stage for exposure is characterized by an intermittent operation called step-and-repeat, repeated step motion excites vibration of the vibration isolation table itself. Therefore, the vibration isolator is required to achieve a good balance between the vibration isolation performance against external vibration and the vibration suppression performance against vibration generated by the operation of the mounted device itself.
[0003]
In response to such demands, so-called active type vibration isolation devices have been put into practical use in which vibration of a vibration isolation table is measured by a vibration sensor and an vibration isolation table is driven by an actuator in accordance with the measurement signal. In an active vibration isolator, an air spring is generally used as an actuator. This is because the air spring can easily generate a thrust sufficient to support a heavy object such as a semiconductor manufacturing apparatus. FIG. 5 shows a configuration of a typical vibration isolation device found in the prior art.
[0004]
The operation of the vibration isolator shown in the prior art shown in FIG. 5 will be described. An anti-vibration table 1 on which precision equipment such as an XY stage for exposure is mounted is levitated and supported from an installation floor 100 by an air spring 5. By supporting the vibration isolation table 1 by the air spring 5, the vibration isolation table 1 can be vibration-insulated from the installation floor 100. The pressure of the air spring 5 is adjusted by the air valve 4. As shown in FIG. 6, the air valve 4 is generally a nozzle flapper type having three ports of an air supply port 61, an exhaust port 62 and an output pressure port 63. The output pressure changes according to the air valve drive amount (flapper opening). FIG. 7 shows the characteristics of the air valve driving amount and the output pressure. As shown in FIG. 7, the air valve drive amount-output pressure characteristic is non-linear, has hysteresis, and has strong nonlinearity. In general, air springs have a slow response and poor pressure localization. Therefore, when adjusting the pressure of the air spring 5 using the air valve 4, pressure feedback control is performed such that the pressure of the air spring 5 is measured and the air valve driving amount is adjusted according to the measurement signal. There are many cases.
[0005]
In FIG. 5, the pressure sensor 3 measures the pressure of the air spring 5. The pressure target generator 11 outputs a target value for a steady-state pressure in which the air spring 5 floats and supports the vibration isolation table 1. The pressure compensator 12 performs compensation so that the output signal of the pressure sensor 3 coincides with the sum of the output signals of the displacement compensator 9 and the acceleration compensator 10 described later and the output signal of the pressure target generator 11. . The power amplifier 13 supplies power to the air valve 4 according to the output of the pressure compensator 11 and drives the air valve 4. By such pressure feedback control, the pressure of the air spring 5 is controlled to a desired value.
[0006]
The displacement sensor 2 measures the displacement of the vibration isolation table 1 and the air spring 5. The displacement target generator 7 outputs a target value for the flying displacement of the vibration isolation table 1 and the air spring 5. The displacement compensator 9 performs compensation so that the difference between the output signal of the displacement target generator 7 and the output signal of the displacement sensor 2 becomes zero. As a result, the flying displacement of the vibration isolation table 1 and the air spring 5 is kept constant. The acceleration sensor 6 measures the vibration of the vibration isolation table 1. The acceleration compensator 10 compensates the output signal of the acceleration sensor 6 to form an acceleration negative feedback system. As a result, vibration generated in the vibration isolation table 1 is suppressed.
[0007]
[Problems to be solved by the invention]
In an anti-vibration device using an air spring, the pressure of the air spring is measured by a pressure sensor in order to correct the non-linear characteristics of the air valve and to improve the localization of the pressure of the air spring. So-called pressure feedback control for driving the valve is performed. However, when pressure feedback control is performed on the air spring, there is a problem in that the rigidity of the air spring decreases and the vibration of the vibration isolation table increases. The vibration isolation table that is levitated and supported by the air spring is balanced in a state in which the gravity acting on the vibration isolation table and the support force from the air spring coincide. The support force from the air spring is determined by multiplying the effective pressure receiving area at the contact portion between the air spring and the vibration isolation table by the pressure of the air spring. When vibration is generated in the vibration isolation table due to some disturbance force such as the driving reaction force of the exposure XY stage placed on the vibration isolation table in the semiconductor manufacturing apparatus, the air spring is originally changed according to the displacement of the vibration isolation table. Since the volume changes and the pressure of the air spring changes, a restoring force to the equilibrium state proportional to the displacement, such as returning the vibration isolation table to the equilibrium state, acts on the vibration isolation table from the air spring. This is the stiffness of the air spring. Since the pressure feedback control functions to keep the pressure of the air spring constant, the pressure of the air spring does not change even if the displacement of the vibration isolation table and the volume change of the air spring occur. That is, the rigidity of the air spring is lowered, and the restoring force to the equilibrium state does not act on the vibration isolation table. Therefore, when pressure feedback control is performed, there is a problem that when vibration is generated in the vibration isolation table due to some factor such as a disturbance force, the vibration of the vibration isolation table increases due to a decrease in rigidity of the air spring. In the conventional vibration isolator, there is no one that solves the decrease in rigidity of the air spring by pressure feedback control.
[0008]
The present invention has been made in consideration of such circumstances. That is, an object of the present invention is to provide a vibration isolation device capable of performing feedback control of the pressure of the air spring without causing a decrease in rigidity of the air spring.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, a vibration isolation device according to the present invention includes a vibration isolation table, an air spring that supports the vibration isolation table, an air valve that adjusts the pressure of the air spring, and a displacement of the vibration isolation table . A displacement sensor that measures the displacement, a displacement target generator that outputs a target value for the displacement of the vibration isolation table , and a difference signal between the output signal of the displacement target generator and the output signal of the displacement sensor to compensate the displacement. a displacement compensator for controlling the displacement of the vibration table, and an acceleration sensor for measuring the vibration of the vibration isolating stand, the acceleration compensator is negatively fed back to the input side of the displacement compensator applies compensation to the output signal of the acceleration sensor A pressure sensor that measures the pressure of the air spring, a pressure target generator that outputs a target value for the pressure of the air spring, an output signal of the displacement compensator and the pressure target generator, and an output of the pressure sensor To the composite signal with the signal A pressure compensator that compensates and controls the pressure of the air spring, a power amplifier that drives the air valve according to an output signal of the pressure compensator, a stiffness compensator having a low-cut filter and a proportional gain element, And a stiffness compensator that compensates the output signal of the displacement sensor and negatively feeds back to the input side of the pressure compensator to control the stiffness of the air spring.
[0011]
[Action]
The air spring levitates and supports a vibration isolation table on which precision equipment such as an exposure XY stage is mounted. The air valve regulates the pressure of the air spring. The pressure sensor measures the pressure of the air spring.
The pressure target generator outputs a target value for the steady-state pressure in which the air spring levitates and supports the vibration isolation table. The pressure compensator performs compensation such that the output signal of the pressure sensor matches the sum of the output signal of the stiffness compensator, the displacement compensator, and the acceleration compensator and the output signal of the pressure target generator. The power amplifier supplies power to the air valve according to the output of the pressure compensator and drives the air valve.
[0012]
The displacement sensor measures the displacement of the vibration isolation table and the floating displacement of the air spring. The displacement target generator outputs target values for the vibration isolation table displacement and the air spring displacement. The displacement compensator performs compensation so that the difference between the output signal of the displacement target generator and the output signal of the displacement sensor becomes zero so that the vibration isolation table is localized at a desired floating position.
The acceleration sensor is fixed to the vibration isolation table, and measures vibration generated on the vibration isolation table as an acceleration signal. The acceleration compensator compensates for the output signal of the acceleration sensor and forms a negative feedback of acceleration. This gives damping to the vibration isolation table.
[0013]
A stiffness compensator having a low cut filter and a proportional gain element compensates for the output signal of the displacement sensor so as to impart stiffness to the vibration isolation table and the air spring. The vibration isolation table that is levitated and supported by the air spring is balanced in a state in which the gravity acting on the vibration isolation table and the support force from the air spring coincide. When vibration is generated in the vibration isolation table due to some disturbance force such as the driving reaction force of the exposure XY stage placed on the vibration isolation table in the semiconductor manufacturing equipment, the stiffness compensator is removed via an air spring as an actuator. It functions so that a restoring force to an equilibrium state proportional to the displacement of the shaking table or the displacement of the air spring acts on the vibration isolation table.
[0014]
As described above, even if the pressure feedback control is performed, the rigidity of the air spring does not decrease due to the function of the rigidity compensator. Pressure feedback control corrects the non-linear characteristics of the air valve and improves the localization of the air spring pressure. At the same time, since the rigidity of the air spring does not decrease, a vibration isolator having good vibration suppression performance can be realized.
[0015]
【Example】
Embodiments of the vibration isolator according to the present invention will be described in detail with reference to the drawings. FIG. 1 shows the configuration of a vibration isolation device according to an embodiment of the present invention. In the figure, the vibration isolation table 1 is supported by levitation by an air spring 5. The air spring 5 is a support leg that floats and supports the vibration isolation table 1, and at the same time, is an actuator that applies a damping force to the vibration isolation table 1 by a pressure change of the air spring 5 in order to suppress vibration of the vibration isolation table 1. . The pressure of the air spring 5 is adjusted by the air valve 4.
[0016]
Pressure feedback control is realized as follows. The pressure sensor 3 measures the pressure of the air spring 5. The pressure target generator 11 outputs a target value for the steady-state pressure when the air spring 5 levitates and supports the vibration isolation table 1. In the pressure compensator 12, the output signal of the pressure sensor 3 matches the sum of the output signals of the stiffness compensator 8, the displacement compensator 9 and the acceleration compensator 10, which will be described later, and the output signal of the pressure target generator 11. Compensate like this. The power amplifier 13 supplies power to the air valve 4 according to the output of the pressure compensator 11 and drives the air valve 4. By such pressure feedback control, the pressure of the air spring 5 is controlled to a desired value.
[0017]
The displacement sensor 2 measures the displacement of the vibration isolation table 1 and the displacement of the air spring 5. The displacement of the air spring 5 here is the stroke of the air spring 5 and is the same as the displacement of the vibration isolation table 1. The displacement target generator 7 outputs target values for the displacement of the vibration isolation table 1 and the flying displacement of the air spring 5. The displacement compensator 9 performs compensation so that the difference between the output signal of the displacement target generator 7 and the output signal of the displacement sensor 2 becomes zero so that the vibration isolation table 1 is localized to a desired flying position. Conventionally, the displacement compensator 9 is designed so that the pressure of the air spring 5 is controlled by integration of its input signal. This is because the displacement of the vibration isolation table 1 can be quickly converged without overshooting the output signal of the displacement target generator 7.
[0018]
The acceleration sensor 6 is fixed to the vibration isolation table 1 and measures vibration generated in the vibration isolation table 1 as an acceleration signal. The acceleration compensator 10 compensates the output signal of the acceleration sensor 6 to form a negative feedback of acceleration. As described above, since the displacement compensator 9 is designed so that the pressure of the air spring 5 is controlled by integrating the input signal, the acceleration compensator 10 generates a compensation value proportional to the output of the acceleration sensor 6. If this compensation value is input to the displacement compensator 9, an acceleration integral, that is, a damping force proportional to the speed can be applied to the vibration isolation table 1. As a result, damping is applied to the vibration isolation table 1 to effectively suppress vibration generated in the vibration isolation table 1.
[0019]
A stiffness compensator 8 having a low cut filter 14 and a proportional gain element 15 compensates for the output signal of the displacement sensor 2 so as to impart stiffness to the vibration isolation table 1 and the air spring 5. The anti-vibration table 1 that the air spring 5 floats and supports is balanced in a state where the gravity acting on the anti-vibration table 1 and the supporting force from the air spring 5 coincide. When vibration is generated in the vibration isolation table 1 due to some disturbance force such as a driving reaction force of an exposure XY stage placed on the vibration isolation table 1 in the semiconductor manufacturing apparatus, the stiffness compensator 8 is an air spring 5 that is an actuator. Thus, the restoring force to the equilibrium state proportional to the displacement of the vibration isolation table 1 or the displacement of the air spring 5 functions so as to act on the vibration isolation table 1. Thereby, rigidity is given to the vibration isolation table 1 and the air spring 5, and vibration generated in the vibration isolation table 1 is effectively suppressed.
[0020]
The stiffness compensator 8 and the displacement compensator 9 both receive the signal from the displacement sensor 2, but their functions are completely different as described above. The stiffness compensator 8 functions to apply a restoring force to an equilibrium state proportional to the displacement of the vibration isolation table 1 or the displacement of the air spring 5 to the vibration isolation table 1. As a result, it is possible to avoid a decrease in the rigidity of the air spring 5 due to the pressure feedback described above. The displacement compensator 9 integrates the difference between the output signal of the displacement target generator 7 and the output signal of the displacement sensor 2 so that the vibration isolation table 1 is localized without overshooting to a desired floating position. It functions so that the force acts. Therefore, the air spring 5 cannot be given rigidity by the function of the displacement compensator 9. This is because the rigidity is a restoring force to an equilibrium state proportional to the displacement.
[0021]
Hereinafter, the operation of the stiffness compensator 8 will be described in more detail.
FIG. 2 shows a dynamic model of a part composed of the vibration isolation table 1, the air valve 4 and the air spring 5. The anti-vibration table 1 can be modeled as a mass element. The displacement is x, the disturbance force acting on the vibration isolation table 1 is f, and the effective pressure receiving area of the portion where the vibration isolation table 1 receives the force from the air spring 5 is A. The air valve 4 adjusts the air inflow / outflow flow rate and the pressure p of the air spring 5 according to the air valve drive amount u. Assuming that the pressure p is a fluctuation amount from the equilibrium state, the equation (1) is obtained with respect to the motion of the vibration isolation table 1 from FIG. Further, the expression (2) is established with respect to the pressure of the air spring 5.
[0022]
[Expression 1]

[0023]
In the equation (2), the coefficient ω applied to the pressure p on the left side is a physical quantity determined from the mechanical parameters of the air spring 5. The coefficient G _q applied to the air valve drive amount u on the right side is the pressure gain of the air valve 4. Similarly, the term including the displacement x of the vibration isolation table 1 on the right side indicates that the pressure p of the air spring 5 is changed by the displacement x, and G _v is an influence coefficient thereof. By performing Laplace transform on the equations (1) and (2), the block diagram of FIG. 3 that mathematically shows the dynamic model of FIG. 2 is obtained. In FIG. 3, the symbol s represents a Laplace operator. From FIG. 3, the input / output equation with the input as the air valve drive amount u and the disturbance force f and the output as the displacement x of the vibration isolation table 1 is expressed by equation (3). (3) In the formula, the left side of the _{AG v s / (s + ω} ) represents the stiffness of the air spring 5.
[0024]
[Expression 2]

[0025]
FIG. 4 is a block diagram mathematically showing the operation of the vibration isolator according to the present embodiment. FIG. 4 shows only elements necessary and sufficient for explaining the operation of the stiffness compensator 8, and other components such as the displacement compensator 9 and the acceleration compensator 10 are omitted. In FIG. 4, the pressure compensator 12 is a proportional calculator and its gain is G. Also the transfer function of the stiffness compensator 8 and G _k. The input / output equation of FIG. 4 where the input is the disturbance force f and the output is the displacement x of the vibration isolation table 1 is as shown in equation (4).
[0026]
[Equation 3]

[0027]
If there is no stiffness compensator 8 and G _k = 0, the input / output equation of the equation (4) becomes the equation (5). In this case, the stiffness term representing the stiffness of the air spring 5 is AG _v s / (s + ω + G _q G) from the left side of the equation (5), but the gain G of the pressure compensator 12 is in the denominator of the stiffness term. The greater the G, the smaller the stiffness term. That is, it can be seen from the equation (5) that the rigidity of the air spring 5 decreases as the gain G of the pressure feedback loop is increased.
[0028]
[Expression 4]

[0029]
The stiffness compensator 8 functions to avoid a decrease in stiffness of the air spring 5 due to pressure feedback control. (4) As can be seen from the equation, by the operation of the rigid compensator 8, the stiffness term of the air spring 5 becomes _{AG v s / (s + ω} + G q G) + AG v / (s + ω + G q G) xG q GG k / G v ing. That is, as the transfer function G _k of the stiffness compensator 8 is increased, the stiffness term is increased, so that the stiffness required for the air spring 5 can be ensured. Specifically, the transfer function G _k may be designed as follows. First, when pressure feedback control is not performed, the stiffness term of the air spring 5 is AG _v s / (s + ω) from the left side of the equation (3). The transfer function G _k is designed so that the rigidity term of the equation (4), which is an input / output equation of the vibration isolator according to the present invention, matches this. Comparing equation (3) and equation (4), the transfer function G _k of the stiffness compensator 8 is determined as in equation (6).
[0030]
[Equation 5]

[0031]
Substituting (6) is an input-output type vibration isolator according to the present embodiment the transfer function G _k was determined by formula (4) (7) is obtained. The left side of equation (7) is exactly the same as the left side of equation (3), which is an input / output equation when pressure feedback control is not performed. It can be seen that the rigidity of the air spring 5 can be ensured by the operation of the stiffness compensator 8 exactly the same as when the pressure feedback control is not performed. Further, the transfer function G _k of the stiffness compensator 8 expressed by the equation (6) is constituted by a series combination of a transfer function s / (s + ω) representing a low cut filter and a proportional gain G _v (ω + G _q G) / G _q G. Has been. The vibration isolator according to the present embodiment is characterized in that the stiffness compensator 8 includes a low cut filter 14 and a proportional gain element 15.
[0032]
[Formula 6]

[0033]
As described above, since the rigidity of the air spring 5 can be avoided by the operation of the stiffness compensator 8, the vibration isolation device according to the present embodiment realizes a preferable vibration suppression performance.
The vibration isolator according to the present invention is not limited to the embodiment shown in FIG. The essence of the present invention that it is a vibration isolation device capable of performing feedback control of the pressure of the air spring without causing a decrease in rigidity of the air spring is the shape of the vibration isolation table, the number and arrangement of the air springs supporting the vibration isolation table, etc. It can be implemented regardless. Moreover, the semiconductor manufacturing apparatus having the vibration isolator according to the present invention can be realized by either a sequential drive type or a scanning type.
[0034]
The mathematical symbols used so far are listed below.
M: Mass of the vibration isolation table 1 A: Effective pressure receiving area of the air spring 5 x: Displacement of the vibration isolation table 1 p: Pressure of the air spring 5 u: Air valve drive amount f: Disturbance force ω acting on the vibration isolation table 1 : physical quantity determined from the mechanical parameters of the air spring 5 G _q: pressure gain of the air valve 4 G _v: influence coefficient from the displacement x of the vibration isolation base 1 to the pressure p of the air spring 5 G: pressure compensator 12 is proportional operation Gain G _k when it is a transformer: transfer function of the stiffness compensator 8
[Example of device production method]
Next, an embodiment of a device production method using the exposure apparatus having the vibration isolator described above will be described.
FIG. 8 shows the flow of manufacturing a microdevice (semiconductor chip such as IC or LSI, liquid crystal panel, CCD, thin film magnetic head, micromachine, etc.). In step 1 (circuit design), a device pattern is designed. In step 2 (mask production), a mask on which the designed pattern is formed is produced. On the other hand, in step 3 (wafer manufacture), a wafer is manufactured using a material such as silicon or glass. Step 4 (wafer process) is called a pre-process, and an actual circuit is formed on the wafer by lithography using the prepared mask and wafer. The next step 5 (assembly) is referred to as a post-process, and is a process for forming a semiconductor chip using the wafer produced in step 4, such as an assembly process (dicing, bonding), a packaging process (chip encapsulation), and the like. including. In step 6 (inspection), inspections such as an operation confirmation test and a durability test of the semiconductor device manufactured in step 5 are performed. Through these steps, the semiconductor device is completed and shipped (step 7).
[0036]
FIG. 9 shows a detailed flow of the wafer process. In step 11 (oxidation), the wafer surface is oxidized. In step 12 (CVD), an insulating film is formed on the wafer surface. In step 13 (electrode formation), an electrode is formed on the wafer by vapor deposition. In step 14 (ion implantation), ions are implanted into the wafer. In step 15 (resist process), a photosensitive agent is applied to the wafer. In step 16 (exposure), the circuit pattern of the mask is printed on the wafer by exposure using the exposure apparatus having the vibration isolator described above. In step 17 (development), the exposed wafer is developed. In step 18 (etching), portions other than the developed resist image are removed. In step 19 (resist stripping), unnecessary resist after etching is removed. By repeating these steps, multiple circuit patterns are formed on the wafer.
By using the production method of this embodiment, a highly integrated device that has been difficult to manufacture can be manufactured at low cost.
[0037]
【The invention's effect】
As described above, according to the present invention, it is possible to provide a vibration isolator that can perform feedback control of the pressure of the air spring without reducing the rigidity of the air spring. In the vibration isolator according to the present invention, the pressure feedback control corrects the non-linear characteristic of the air valve and improves the localization of the pressure of the air spring. At the same time, since the rigidity of the air spring, which has been a problem in the prior art, does not deteriorate, a suitable vibration suppression performance can be realized.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a vibration isolation device according to an embodiment of the present invention.
FIG. 2 is a drawing showing a dynamic model of a vibration isolation table and an air spring.
FIG. 3 is a drawing mathematically showing a dynamic model of a vibration isolation table and an air spring.
FIG. 4 is a drawing mathematically showing the operation of the vibration isolator according to the present invention.
FIG. 5 is a view showing a vibration isolator according to the prior art.
FIG. 6 is a view showing a structure of an air valve.
FIG. 7 is a view showing characteristics of an air valve.
FIG. 8 is a diagram showing a flow of manufacturing a microdevice.
9 is a diagram showing a detailed flow of the wafer process in FIG. 8. FIG.
[Explanation of symbols]
1: vibration isolator, 2: displacement sensor, 3: pressure sensor, 4: air valve, 5: air spring, 6: acceleration sensor, 7: displacement target generator, 8: stiffness compensator, 9: displacement compensator, 10: acceleration compensator, 11: pressure target generator, 12: pressure compensator, 13: power amplifier, 14: low cut filter, 15: proportional gain element.

Claims (3)

A vibration isolation table,
An air spring that supports the vibration isolation table;
An air valve for adjusting the pressure of the air spring;
A displacement sensor for measuring the displacement of the anti-vibration table,
A displacement target generator for outputting a target value for the displacement of the vibration isolation table;
A displacement compensator for controlling the displacement of the anti-vibration table performs compensation on the difference signal between the output signal of the output signal of the displacement sensor of the displacement target generator,
An acceleration sensor for measuring vibration of the vibration isolation table;
An acceleration compensator that compensates the output signal of the acceleration sensor and negatively feeds back to the input side of the displacement compensator;
A pressure sensor for measuring the pressure of the air spring;
A pressure target generator for outputting a target value for the pressure of the air spring;
A pressure compensator for compensating the combined signal of the output signal of the displacement compensator and the pressure target generator and the output signal of the pressure sensor to control the pressure of the air spring;
A power amplifier that drives the air valve in response to an output signal of the pressure compensator;
A stiffness compensator having a low-cut filter and a proportional gain element, and compensating the output signal of the displacement sensor and negatively feeding back to the input side of the pressure compensator to control the stiffness of the air spring. An anti-vibration device comprising:  A device manufacturing apparatus comprising the vibration isolation device according to claim 1.  A device manufacturing method using the device manufacturing apparatus according to claim 2.

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