WO2018062500A1 - 移動体装置、移動方法、露光装置、露光方法、フラットパネルディスプレイの製造方法、並びにデバイス製造方法 - Google Patents
移動体装置、移動方法、露光装置、露光方法、フラットパネルディスプレイの製造方法、並びにデバイス製造方法 Download PDFInfo
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- WO2018062500A1 WO2018062500A1 PCT/JP2017/035515 JP2017035515W WO2018062500A1 WO 2018062500 A1 WO2018062500 A1 WO 2018062500A1 JP 2017035515 W JP2017035515 W JP 2017035515W WO 2018062500 A1 WO2018062500 A1 WO 2018062500A1
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70691—Handling of masks or workpieces
- G03F7/70716—Stages
- G03F7/70725—Stages control
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B11/00—Measuring arrangements characterised by the use of optical techniques
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/20—Exposure; Apparatus therefor
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70058—Mask illumination systems
- G03F7/70141—Illumination system adjustment, e.g. adjustments during exposure or alignment during assembly of illumination system
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70483—Information management; Active and passive control; Testing; Wafer monitoring, e.g. pattern monitoring
- G03F7/70591—Testing optical components
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70691—Handling of masks or workpieces
- G03F7/70716—Stages
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70691—Handling of masks or workpieces
- G03F7/70758—Drive means, e.g. actuators, motors for long- or short-stroke modules or fine or coarse driving
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70691—Handling of masks or workpieces
- G03F7/70775—Position control, e.g. interferometers or encoders for determining the stage position
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/708—Construction of apparatus, e.g. environment aspects, hygiene aspects or materials
- G03F7/70808—Construction details, e.g. housing, load-lock, seals or windows for passing light in or out of apparatus
- G03F7/70833—Mounting of optical systems, e.g. mounting of illumination system, projection system or stage systems on base-plate or ground
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/708—Construction of apparatus, e.g. environment aspects, hygiene aspects or materials
- G03F7/7085—Detection arrangement, e.g. detectors of apparatus alignment possibly mounted on wafers, exposure dose, photo-cleaning flux, stray light, thermal load
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/708—Construction of apparatus, e.g. environment aspects, hygiene aspects or materials
- G03F7/70975—Assembly, maintenance, transport or storage of apparatus
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/67—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere
- H01L21/68—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere for positioning, orientation or alignment
Definitions
- the present invention relates to a moving body device, a moving method, an exposure apparatus, an exposure method, a flat panel display manufacturing method, and a device manufacturing method.
- an exposure apparatus that exposes a wafer (hereinafter collectively referred to as “substrate”) to transfer a predetermined pattern of a mask (photomask) or reticle (hereinafter collectively referred to as “mask”) onto the substrate. ing.
- Patent Document 1 an apparatus using an encoder system is known as a substrate position measurement system (for example, Patent Document 1). reference).
- the optical path length of the laser to the bar mirror becomes long and the influence of so-called air fluctuation cannot be ignored.
- the first moving body that holds the object and is movable in the first direction and the second direction intersecting each other, and the plurality of lattice regions are arranged apart from each other with respect to the first direction.
- One of the first grating region including the measurement components in the first and second directions and the plurality of first heads that irradiate the measurement beam while moving in the first direction with respect to the first grating region.
- the first moving body is related to the first direction measured by at least three first heads that are irradiated with at least one of the plurality of lattice regions, among the plurality of first heads.
- a first measurement system that measures positional information of the first moving body; a second moving body that is provided on the other of the first lattice region and the plurality of first heads and is movable in the second direction;
- the measurement components in the first and second directions are One of the second grating region and the second head that irradiates the measurement beam while moving in the second direction with respect to the second grating region is provided in the second moving body,
- a second measurement system configured to measure the positional information of the second moving body with respect to the second direction, the second measurement area being provided so that the other of the second lattice area faces the second moving body; and the first and second measurements Compensates for the position information measured by the system and the measurement error of the measurement system caused by at least one movement of the first grid member, the plurality of first heads, and the first moving body
- a control system that controls the movement of the first moving body in the direction of three degrees of freedom within a predetermined plane including the first and second directions based on the correction information for Is done.
- a moving body device that exposes a substrate with illumination light through an optical system, the moving body being disposed below the optical system and holding the substrate, and the optical device.
- a driving system capable of moving the movable body in first and second directions orthogonal to each other within a predetermined plane orthogonal to the optical axis of the system, and a grating member in which a plurality of grating regions are arranged apart from each other in the first direction
- one of a plurality of first heads each irradiating a measurement beam to the lattice member and movable in the second direction is provided on the movable body, and the lattice member and the plurality of first heads
- the measurement system is provided so that the other of the movable body and the movable body is opposed to the movable body, wherein the measurement system includes one of a scale member and a second head provided on the plurality of first heads, and the scale member; Said Position information of the plurality of first heads in the second
- a control system for controlling the drive system based on correction information for compensating for an error and position information measured by the measurement system, the plurality of first heads including
- the movable body device that switches to another lattice region adjacent to the one lattice region as the measurement beam deviates from one of the plurality of lattice regions.
- the mobile device according to any one of the first aspect and the second aspect, an optical system that irradiates the object with an energy beam and exposes the object, An exposure apparatus is provided.
- a flat panel display manufacturing method comprising: exposing a substrate using the exposure apparatus according to the third aspect; and developing the exposed substrate.
- a flat panel display manufacturing method is provided.
- a device manufacturing method comprising: exposing a substrate using the exposure apparatus according to the third aspect; and developing the exposed substrate. A method is provided.
- the first moving body holding the object is moved in the first direction and the second direction intersecting each other, and a plurality of the first directions are obtained by the first measurement system.
- a plurality of grid areas that are arranged apart from each other and irradiate a measurement beam while moving in the first direction with respect to the first grid area, the first grid area including measurement components in the first and second directions;
- One of the first heads is provided on the first moving body, and measurement is performed by at least three first heads of the plurality of first heads that are irradiated with at least one of the plurality of grating regions.
- the first moving body is moved in the second direction by a second moving body provided on the other of the first lattice region and the plurality of first heads, and the first measurement system is used to move the first moving body to the first direction.
- One of the second grating region including the measurement component in the second direction and the second head that irradiates the measurement beam while moving in the second direction with respect to the second grating region is provided in the second moving body.
- the object is moved in the first direction, and an energy beam is applied to the object moved in the first direction. Irradiating and exposing the object is provided.
- a flat panel display manufacturing method comprising: exposing a substrate using the exposure method according to the seventh aspect; and developing the exposed substrate.
- a flat panel display manufacturing method is provided.
- a device manufacturing method comprising: exposing a substrate using the exposure method according to the seventh aspect; and developing the exposed substrate.
- a manufacturing method is provided.
- FIG. (1) for demonstrating operation
- FIG. (2) for demonstrating operation
- FIG. (1) for demonstrating operation
- FIG. (2) for demonstrating operation
- FIG. (1) for demonstrating operation
- FIG. (2) for demonstrating operation
- FIG. (1) for demonstrating operation
- FIG. (2) for demonstrating operation
- FIG. (1) for demonstrating operation
- FIG. (2) for demonstrating operation
- FIG. (1) for demonstrating operation
- FIG. (2) for demonstrating operation
- FIG. (1) for demonstrating operation
- FIG. (2) for demonstrating operation
- FIG. 8 is a diagram showing a first system of the substrate stage apparatus of FIG. 7. It is a top view which shows the substrate stage apparatus which concerns on 3rd Embodiment. It is sectional drawing of the substrate stage apparatus of FIG. It is a figure which shows the 2nd system of the substrate stage apparatus of FIG.
- FIG. 12 is a diagram showing a first system of the substrate stage apparatus of FIG. 11. It is a top view which shows the substrate stage apparatus which concerns on 4th Embodiment. It is sectional drawing of the substrate stage apparatus of FIG. It is a figure which shows the 2nd system of the substrate stage apparatus of FIG.
- FIG. 16 is a diagram showing a first system of the substrate stage apparatus of FIG. 15.
- FIG. 20 is a diagram showing a second system of the substrate stage apparatus of FIG. 19.
- FIG. 20 is a diagram showing a first system of the substrate stage apparatus of FIG. 19. It is a figure which shows the substrate stage apparatus which concerns on 6th Embodiment. It is a figure which shows the substrate holder which is a part of substrate stage apparatus of FIG.
- FIG. 24 is a diagram showing a system including a substrate table that is a part of the substrate stage apparatus of FIG. 23. It is a figure for demonstrating the structure of the board
- FIG. 29 is a diagram showing a system including a substrate table which is a part of the substrate stage apparatus of FIG. 28. It is a figure for demonstrating the structure of the board
- FIG. 33 is a diagram showing a system including a substrate table that is a part of the substrate stage apparatus of FIG. 32. It is a figure for demonstrating the structure of the board
- FIG. 45 is a diagram showing a substrate holder that is a part of the substrate stage apparatus of FIG. 44.
- FIG. 45 is a diagram showing a system including a substrate table that is a part of the substrate stage apparatus of FIG. 44.
- FIG. 49 is a diagram showing a system including a weight cancellation device that is a part of the substrate stage device of FIG. 48.
- FIG. 49 is a diagram showing a system including a Y coarse movement stage which is a part of the substrate stage apparatus of FIG. 48.
- FIG. 49 is a diagram showing a system including a substrate table that is a part of the substrate stage apparatus of FIG. 48.
- FIG. 56 is a diagram showing a system including a substrate table that is a part of the substrate stage apparatus of FIG. 55. It is a figure for demonstrating the structure of the board
- FIG. 61 is a diagram for explaining an operation of the substrate stage apparatus of FIG. 60.
- FIG. 61 is a diagram showing a substrate holder that is a part of the substrate stage apparatus of FIG. 60.
- FIG. 61 is a diagram showing a system including a substrate table that is a part of the substrate stage apparatus of FIG. 60. It is a figure which shows the substrate stage apparatus based on 16th Embodiment. It is a figure which shows the substrate stage apparatus which concerns on 17th Embodiment. It is a figure which shows the substrate stage apparatus based on 18th Embodiment. It is a figure for demonstrating the structure of the board
- 71A and 71B are diagrams for explaining the movement range of the substrate holder in the X-axis direction when position measurement of the substrate holder is performed.
- FIG. 6 is a diagram for explaining a state to a fourth state.
- 74 (A) to 74 (C) explain a connecting process performed by the liquid crystal exposure apparatus according to the twentieth embodiment at the time of switching the head of the substrate encoder system for measuring the position information of the substrate holder.
- FIG. It is a top view which shows a pair of head base of the substrate holder and substrate encoder system which a liquid-crystal exposure apparatus which concerns on 21st Embodiment has with a projection optical system.
- FIG. 1 schematically shows a configuration of an exposure apparatus (here, a liquid crystal exposure apparatus 10) according to the first embodiment.
- the liquid crystal exposure apparatus 10 is a so-called scanner, a step-and-scan projection exposure apparatus that uses an object (here, the glass substrate P) as an exposure target.
- a glass substrate P (hereinafter simply referred to as “substrate P”) is formed in a rectangular shape (planar shape) in plan view, and is used for a liquid crystal display device (flat panel display) or the like.
- the liquid crystal exposure apparatus 10 has an illumination system 12, a mask stage apparatus 14 that holds a mask M on which a circuit pattern and the like are formed, a projection optical system 16, an apparatus body 18, and a resist (surface facing the + Z side in FIG. 1) on the surface. It has a substrate stage device 20 that holds a substrate P coated with (sensitive agent), a control system for these, and the like.
- the direction in which the mask M and the substrate P are relatively scanned with respect to the projection optical system 16 at the time of exposure is defined as the X-axis direction
- the direction orthogonal to the X-axis in the horizontal plane is defined as the Y-axis direction, the X-axis, and the Y-axis.
- the orthogonal direction is the Z-axis direction (the direction parallel to the optical axis direction of the projection optical system 16), and the rotation directions around the X-axis, Y-axis, and Z-axis are the ⁇ x, ⁇ y, and ⁇ z directions, respectively. Further, description will be made assuming that the positions in the X-axis, Y-axis, and Z-axis directions are the X position, the Y position, and the Z position, respectively.
- the illumination system 12 is configured in the same manner as the illumination system disclosed in US Pat. No. 5,729,331 and the like.
- a light source such as a mercury lamp or a laser diode
- the mask M is irradiated as exposure illumination light (illumination light) IL through a reflecting mirror, a dichroic mirror, a shutter, a wavelength selection filter, various lenses, and the like (not shown).
- the illumination light IL light such as i-line (wavelength 365 nm), g-line (wavelength 436 nm), and h-line (wavelength 405 nm) (or combined light of the i-line, g-line, and h-line) is used.
- a transmissive photomask As the mask M held by the mask stage device 14, a transmissive photomask is used. A predetermined circuit pattern is formed on the lower surface of the mask M (the surface facing the -Z side in FIG. 1).
- the mask M has a predetermined length in the scanning direction (X-axis direction) by a main controller 100 (not shown in FIG. 1; see FIG. 6) via a mask drive system 102 including an actuator such as a linear motor and a ball screw device. While being driven by a stroke, it is slightly driven as appropriate in the Y-axis direction and the ⁇ z direction.
- Position information of the mask M in the XY plane is transmitted to the main controller 100 (respectively) via a mask measurement system 104 including a measurement system such as an encoder system or an interferometer system. 1 (not shown in FIG. 1, see FIG. 6).
- the projection optical system 16 is disposed below the mask stage device 14.
- the projection optical system 16 is a so-called multi-lens projection optical system having the same configuration as the projection optical system disclosed in US Pat. No. 6,552,775 and the like. Are provided with a plurality of lens modules.
- the illumination area on the mask M is illuminated by the illumination light IL from the illumination system 12
- the illumination area IL passes through (transmits) the mask M via the projection optical system 16.
- a projection image (partial upright image) of the circuit pattern of the mask M is formed in an irradiation area (exposure area) of illumination light conjugate to the illumination area on the substrate P.
- the mask M moves relative to the illumination area (illumination light IL) in the scanning direction
- the substrate P moves relative to the exposure area (illumination light IL) in the scanning direction. Scanning exposure of one shot area is performed, and the pattern formed on the mask M is transferred to the shot area.
- the apparatus main body 18 supports the mask stage apparatus 14 and the projection optical system 16, and is installed on the floor F of the clean room via the vibration isolator 19.
- the apparatus main body 18 is configured in the same manner as the apparatus main body disclosed in US Patent Application Publication No. 2008/0030702, and includes an upper frame part 18a, a pair of middle frame parts 18b, and a lower frame part 18c. ing. Since the upper pedestal 18a is a member that supports the projection optical system 16, the upper pedestal 18a is hereinafter referred to as an “optical surface plate 18a” in the present specification.
- the position of the substrate P is controlled with respect to the illumination light IL irradiated through the projection optical system 16.
- the optical surface plate 18a that supports the substrate functions as a reference member when the position of the substrate P is controlled.
- the substrate stage device 20 is a device for controlling the position of the substrate P with respect to the projection optical system 16 (illumination light IL) with high accuracy, and the substrate P is aligned along the horizontal plane (X-axis direction and Y-axis direction). While driving with a predetermined long stroke, it is slightly driven in the direction of 6 degrees of freedom.
- the configuration of the substrate stage apparatus used in the liquid crystal exposure apparatus 10 is not particularly limited, but in the first embodiment, the gantry type as disclosed in, for example, US Patent Application Publication No. 2012/0057140, as an example.
- a substrate stage apparatus 20 having a so-called coarse / fine movement configuration is used, which includes a two-dimensional coarse movement stage and a fine movement stage that is finely driven with respect to the two-dimensional coarse movement stage.
- the substrate stage device 20 includes a fine movement stage 22, a Y coarse movement stage 24, an X coarse movement stage 26, a support portion (herein, a self-weight support device 28), and a pair of base frames 30 (one is not shown in FIG. 1, see FIG. 4). ), A substrate driving system 60 (not shown in FIG. 1, refer to FIG. 6) for driving each element constituting the substrate stage apparatus 20, and a substrate measuring system 70 (see FIG. 6) for measuring positional information of each element. 1 (not shown, see FIG. 6).
- the fine movement stage 22 includes a substrate holder 32 and a stage main body 34.
- the substrate holder 32 is formed in a plate shape (or box shape) having a rectangular shape in plan view (see FIG. 4), and the substrate P is placed on the upper surface (substrate placement surface).
- the dimensions of the upper surface of the substrate holder 32 in the X-axis and Y-axis directions are set to be approximately the same as the substrate P (actually somewhat shorter).
- the substrate P is vacuum-sucked and held on the substrate holder 32 in a state of being placed on the upper surface of the substrate holder 32, so that almost the entire surface (the entire surface) is flattened along the upper surface of the substrate holder 32.
- the stage main body 34 is made of a plate-shaped (or box-shaped) member having a rectangular shape in a plan view and shorter than the substrate holder 32 in the X-axis and Y-axis directions, and is integrally connected to the lower surface of the substrate holder 32.
- the Y coarse movement stage 24 is disposed below the fine movement stage 22 (on the ⁇ Z side) and on the pair of base frames 30.
- the Y coarse movement stage 24 has a pair of X beams 36.
- the X beam 36 is composed of a member having a rectangular YZ section (see FIG. 2) extending in the X-axis direction.
- the pair of X beams 36 are arranged in parallel at a predetermined interval in the Y-axis direction.
- the pair of X beams 36 are placed on the pair of base frames 30 via a mechanical linear guide device, and are movable in the Y-axis direction on the pair of base frames 30.
- the X coarse movement stage 26 is disposed above (+ Z side) the Y coarse movement stage 24 and below the fine movement stage 22 (between the fine movement stage 22 and the Y coarse movement stage 24). ing.
- the X coarse movement stage 26 is a plate-like member having a rectangular shape in plan view, and a plurality of mechanical linear guide devices 38 (see FIG. 2) on a pair of X beams 36 (see FIG. 4) of the Y coarse movement stage 24.
- the Y coarse movement stage 24 is movable with respect to the Y coarse movement stage 24, whereas the Y coarse movement stage 24 moves integrally with the Y coarse movement stage 24.
- the substrate drive system 60 moves the fine movement stage 22 in directions of six degrees of freedom (X axis, Y axis, Z axis, ⁇ x, ⁇ y, and so on) with respect to the optical surface plate 18a (see FIG. 1 respectively).
- a first drive system 62 for finely driving in each direction of ⁇ z
- a second drive system 64 for driving the Y coarse movement stage 24 with a long stroke in the Y-axis direction on the base frame 30 (see FIG. 1 respectively).
- a third drive system 66 for driving the X coarse movement stage 26 on the Y coarse movement stage 24 (see FIG. 1 respectively) with a long stroke in the X-axis direction.
- the type of actuator that constitutes the second drive system 64 and the third drive system 66 is not particularly limited, but as an example, a linear motor, a ball screw drive device, or the like can be used (in FIG. 1 and the like). A linear motor is shown).
- the type of actuator constituting the first drive system 62 is not particularly limited, but in FIG. 2 and the like, as an example, a plurality of linear motors (voice coil motors) 40 that generate thrust in the X axis, Y axis, and Z axis directions.
- the X linear motor is not shown in FIGS. 1 and 2).
- Each linear motor 40 has a stator attached to the X coarse movement stage 26 and a mover attached to the stage main body 34 of the fine movement stage 22. Thrust is applied in the direction of 6 degrees of freedom via the linear motor 40.
- the detailed configuration of the first to third drive systems 62, 64, 66 is disclosed in, for example, US Patent Application Publication No. 2010/0018950 and the like, and will not be described.
- the main controller 100 uses the first drive system 62 to adjust the relative position between the fine movement stage 22 and the X coarse movement stage 26 (refer to FIG. 1 respectively) within a predetermined range with respect to the X-axis and Y-axis directions.
- the thrust is given to 22.
- “the position falls within a predetermined range” means that the X coarse movement stage 26 (the fine movement stage 22 is moved in the Y-axis direction when the fine movement stage 22 is moved with a long stroke in the X-axis or Y-axis direction.
- the own weight support device 28 includes a weight cancellation device 42 that supports the weight of the fine movement stage 22 from below, and a Y step guide 44 that supports the weight cancellation device 42 from below.
- the weight cancellation device 42 (also referred to as a core column) is inserted into an opening formed in the X coarse movement stage 26, and a plurality of couplings are made to the X coarse movement stage 26 at the height of the center of gravity. It is mechanically connected via a member 46 (also referred to as a flexure device).
- the X coarse movement stage 26 and the weight cancellation device 42 are coupled by a plurality of coupling members 46 in a state of being separated in a vibrational (physical) manner with respect to the Z-axis direction, the ⁇ x direction, and the ⁇ y direction.
- the weight cancellation device 42 When the weight cancellation device 42 is pulled by the X coarse movement stage 26, it moves integrally with the X coarse movement stage 26 in the X-axis and / or Y-axis direction.
- the weight canceling device 42 supports the self-weight of the fine movement stage 22 from below without contact through a pseudo spherical bearing device called a leveling device 48.
- a leveling device 48 a pseudo spherical bearing device.
- the configurations and functions of the weight canceling device 42 and the leveling device 48 are disclosed in, for example, US Patent Application Publication No. 2010/0018950 as an example, and thus the description thereof is omitted.
- the Y step guide 44 is composed of a member extending in parallel with the X axis, and is disposed between a pair of X beams 36 included in the Y coarse movement stage 24 (see FIG. 4).
- the upper surface of the Y step guide 44 is set parallel to the XY plane (horizontal plane), and the weight cancellation device 42 is placed on the Y step guide 44 via the air bearing 50 in a non-contact manner.
- the Y step guide 44 functions as a surface plate when the weight canceling device 42 (that is, the fine movement stage 22 and the substrate P) moves in the X-axis direction (scanning direction).
- the Y step guide 44 is placed on the lower gantry 18c via a mechanical linear guide device 52, and is movable in the Y axis direction with respect to the lower gantry 18c, whereas in the X axis direction. Relative movement with respect to is restricted.
- the Y step guide 44 is mechanically connected to the Y coarse movement stage 24 (the pair of X beams 36) via a plurality of connecting members 54 at the center of gravity height position (see FIG. 4).
- the connecting member 54 is a so-called flexure device similar to the connecting member 46 described above, and vibrates the Y coarse movement stage 24 and the Y step guide 44 with respect to the 5 degrees of freedom direction excluding the Y axis direction out of the 6 degrees of freedom direction. They are linked in a state of being separated physically.
- the Y step guide 44 moves in the Y axis direction integrally with the Y coarse movement stage 24 by being pulled by the Y coarse movement stage 24.
- each of the pair of base frames 30 is composed of members extending in parallel with the Y axis, and is installed on the floor F (see FIG. 1) in parallel with each other.
- the base frame 30 is physically (or vibrationally) separated from the apparatus main body 18.
- the substrate measurement system 70 for obtaining position information in the direction of 6 degrees of freedom of the substrate P (actually, the fine movement stage 22 holding the substrate P).
- FIG. 3 shows a conceptual diagram of the substrate measurement system 70.
- the substrate measurement system 70 includes a first scale (here, an upward scale 72) included in the Y coarse movement stage 24 (associated with the Y coarse movement stage 24) and a first head (here, downward X head) included in the fine movement stage 22. 74x, a downward Y head 74y), and a second scale (here, a downward scale) of the optical surface plate 18a (see FIG. 2) and a first measurement system (here, fine movement stage measurement system 76 (see FIG. 6)).
- a first scale here, an upward scale 72
- Y coarse movement stage 24 included in the fine movement stage 22.
- a second scale here, a downward scale
- the fine movement stage 22 is schematically illustrated as a member that holds the substrate P.
- the spacing (pitch) between the diffraction gratings of each of the scales 72 and 78 is shown to be much wider than actual. The same applies to the other figures.
- the distance between each head and each scale is much shorter than the distance between the laser light source and the bar mirror of the conventional optical interferometer system, the influence of air fluctuation is less than that of the optical interferometer system, and the substrate P is highly accurate. Thus, the exposure accuracy can be improved.
- the upward scale 72 is fixed to the upper surface of the scale base 84.
- one scale base 84 is disposed on each of the fine movement stage 22 on the + Y side and on the ⁇ Y side.
- the scale base 84 is fixed to the X beam 36 of the Y coarse movement stage 24 through an arm member 86 formed in an L shape when viewed from the X-axis direction. Therefore, the scale base 84 (and the upward scale 72) is movable with a predetermined long stroke in the Y-axis direction integrally with the Y coarse movement stage 24.
- two arm members 86 are spaced apart in the X-axis direction for each X beam 36, but the number of arm members 86 is not limited to this, and may be increased or decreased as appropriate. Is possible.
- the scale base 84 is a member extending in parallel with the X axis, and the length in the X axis direction is twice the length in the X axis direction of the substrate holder 32 (that is, the substrate P (not shown in FIG. 4)). Is set to about (same as the Y step guide 44).
- the scale base 84 is preferably formed of a material that is unlikely to be thermally deformed, such as ceramics. The same applies to other scale bases 92 and head bases 88 and 96 described later.
- the upward scale 72 is a plate-shaped (strip-shaped) member extending in the X-axis direction, and has an upper surface (a surface facing + Z side (upper side)) in two axial directions orthogonal to each other (in this embodiment, the X-axis).
- a reflection type two-dimensional diffraction grating (so-called grating) having a periodic direction in the Y-axis direction) is formed.
- the head base 88 is fixed to the central part of the side surface on the + Y side and ⁇ Y side of the substrate holder 32 via the arm member 90 corresponding to the scale base 84 described above (see FIG. 2).
- Each downward head 74x, 74y (see FIG. 3) is fixed to the lower surface of the head base 88.
- downward X head 74x and downward Y head 74y are each in the X-axis direction with respect to one head base 88. Two are spaced apart. Each head 74x, 74y irradiates the corresponding upward scale 72 with a measurement beam and receives light (here, diffracted light) from the upward scale 72.
- the light from the upward scale 72 is supplied to a detector (not shown), and the output of the detector is supplied to the main controller 100 (see FIG. 6).
- Main controller 100 determines the relative movement amount of each head 74x, 74y with respect to scale 72 based on the output of the detector.
- the “head” means a portion that emits a measurement beam to the diffraction grating and is incident on the light from the diffraction grating, and the head itself illustrated in each drawing is a light source. And the detector may not be provided.
- 72 constitutes four X linear encoder systems, and a total of four (two on each of the + Y side and ⁇ Y side of the substrate P) downward Y heads 74y and corresponding upward scales 72, Four Y linear encoder systems are configured.
- Main controller 100 see FIG.
- first information uses the outputs of the four X linear encoder systems and the four Y linear encoder systems as appropriate to appropriately adjust the X axis direction, Y axis direction of fine movement stage 22 (substrate P), and Position information in the ⁇ z direction (hereinafter referred to as “first information”) is obtained.
- the upward scale 72 is set such that the measurable distance in the X-axis direction is longer than the measurable distance in the Y-axis direction.
- the length of the upward scale 72 in the X-axis direction is the same as that of the scale base 84, and the fine movement stage 22 can be moved in the X-axis direction. It is set to a length that can be covered.
- the dimension of the upward scale 72 in the width direction (Y-axis direction) (and the distance between the pair of heads 74x and 74y adjacent in the Y-axis direction) is adjusted so that the fine movement stage 22 is in the Y-axis direction with respect to the upward scale 72.
- the length is set such that the measurement beam from each of the heads 74x and 74y does not deviate from the lattice surface (measurement surface) of the corresponding upward scale 72 even if it is slightly driven.
- FIGS. 4 and 5 show the substrate stage device 20 before and after the fine movement stage 22 moves in a long stroke in the X-axis and Y-axis directions.
- FIG. 4 shows a state in which fine movement stage 22 is positioned approximately in the center of the movable range in the X-axis and Y-axis directions
- FIG. 5 shows + X of the movable range + X in the movable range in the X-axis direction.
- a state is shown that is located at the stroke end on the side and at the stroke end on the -Y side in the Y-axis direction.
- the measurement beam from each of the downward heads 74x and 74y attached to the fine movement stage 22 has the fine movement stage 22 in the Y-axis direction. Including the case where it is slightly driven, it does not deviate from the lattice plane of the upward scale 72.
- the measurement beams from the downward heads 74 x and 74 y do not deviate from the lattice plane of the upward scale 72.
- the coarse movement stage measurement system 82 (see FIG. 6) will be described.
- the coarse movement stage measurement system 82 of the present embodiment includes two pieces spaced apart in the X-axis direction on each of the + Y side and the ⁇ Y side of the projection optical system 16 (see FIG. 1). It has a downward scale 78 (ie a total of four downward scales 78).
- the downward scale 78 is fixed to the lower surface of the optical surface plate 18a via a scale base 92 (see FIG. 2).
- the scale base 92 is a plate-like member extending in the Y-axis direction, and the length in the Y-axis direction is a movable distance in the Y-axis direction of the fine movement stage 22 (that is, the substrate P (not shown in FIG. 4)). Is set to the same level as (and somewhat longer in practice).
- the downward scale 78 is a plate-shaped (strip-shaped) member extending in the Y-axis direction, and has a lower surface (a surface facing the ⁇ Z side (downside)), like the upper surface of the upward scale 72.
- a reflection type two-dimensional diffraction grating (so-called grating) having a periodic direction in two orthogonal directions (X-axis and Y-axis directions in the present embodiment) is formed.
- the grating pitch of the diffraction grating included in the downward scale 78 may be the same as or different from the grating pitch of the diffraction grating included in the upward scale 72.
- a head base 96 is fixed to each of the pair of scale bases 84 included in the Y coarse movement stage 24 via arm members 94 formed in an L shape when viewed from the X-axis direction. Yes.
- the head base 96 is disposed near the + X side end of the scale base 84 and near the ⁇ X side end.
- the upward heads 80 x and 80 y are fixed to the upper surface of the head base 96. Accordingly, a total of four head bases 96 (and upward heads 80x and 80y) are movable in the Y-axis direction integrally with the Y coarse movement stage 24.
- upward X head 80x and upward Y head 80y are each in the Y-axis direction with respect to one head base 96. Two are arranged apart from each other. Each of the heads 80x and 80y emits a measurement beam to the corresponding downward scale 78 and receives light (here, diffracted light) from the downward scale 78. Light from the downward scale 78 is supplied to a detector (not shown), and the output of the detector is supplied to the main controller 100 (see FIG. 6). Main controller 100 determines the relative movement amounts of heads 80x and 80y with respect to scale 78 based on the output of the detector.
- eight X linear encoder systems are configured by the eight upward X heads 80x in total and the corresponding downward scale 78, and a total of eight X linear encoder systems.
- Eight Y linear encoder systems are constituted by the upward Y head 80y and the corresponding downward scale 78.
- the main controller 100 uses the outputs of the eight X linear encoder systems and the eight Y linear encoder systems as appropriate, and uses the Y coarse movement stage 24 in the X axis direction, Y axis direction, and ⁇ z direction.
- Position information hereinafter referred to as “second information”).
- the upward scale 72 fixed to the scale base 84 and the upward heads 80x and 80y integrally fixed to the scale base 84 via the head base 96 are arranged so that their positional relationship is unchanged. It is assumed that the positional relationship with each other is known.
- information related to the relative positional relationship between the upward scale 72 and the upward heads 80x and 80y fixed integrally therewith is referred to as “third information”.
- the liquid crystal exposure apparatus 10 is provided with a measurement system for measuring the positional relationship between the two. May be. The same applies to each embodiment described later.
- Main controller 100 (see FIG. 6), based on the first to third information, position information in the XY plane of fine movement stage 22 (substrate P) with reference to optical surface plate 18a (projection optical system 16). And the position control of the substrate P with respect to the projection optical system 16 (illumination light IL) is performed using the substrate drive system 60 (see FIG. 6).
- the coarse movement stage measurement system 82 includes the downward scale 78 in which the measurable distance in the Y-axis direction is longer than the X-axis direction (the Y-axis direction is the main measurement direction).
- the position information of the Y coarse movement stage 24 moving with a long stroke in the Y-axis direction is obtained, and the measurable distance in the X-axis direction is longer than the Y-axis direction (the X-axis direction is the main measurement direction) upward
- the fine movement stage measurement system 76 including the scale 72 obtains positional information of the fine movement stage 22 that moves in the X-axis direction with a long stroke.
- the movement direction of each encoder head (74x, 74y, 80x, 80y) and the main measurement direction of the corresponding scale (72, 78) are respectively Match.
- Z tilt direction position information of the fine movement stage 22 (substrate P) in the Z-axis, ⁇ x, and ⁇ y directions
- the configuration of the Z tilt position measurement system 98 is not particularly limited, but as an example, a measurement system using a displacement sensor attached to the fine movement stage 22 as disclosed in, for example, US Patent Application Publication No. 2010/0018950. Can be used.
- the substrate measurement system 70 also has a measurement system for obtaining position information of the X coarse movement stage 26.
- the positional information in the X-axis direction of the fine movement stage 22 (substrate P) is obtained with reference to the optical surface plate 18a via the Y coarse movement stage 24, the measurement accuracy of the X coarse movement stage 26 itself is improved. It is not necessary to have the same accuracy as the fine movement stage 22.
- the position measurement of the X coarse movement stage 26 is performed based on the output of the fine movement stage measurement system 76 and the output of a measurement system (not shown) for measuring the relative position between the X coarse movement stage 26 and the fine movement stage 22.
- an independent measurement system may be used.
- the mask M is placed on the mask stage apparatus 14 by a mask loader (not shown) under the control of the main controller 100 (see FIG. 6).
- the substrate P is loaded onto the substrate holder 32 by a substrate loader (not shown).
- the main controller 100 performs alignment measurement using an alignment detection system (not shown), and after the alignment measurement is completed, a step-and-scan method is sequentially applied to a plurality of shot areas set on the substrate P. An exposure operation is performed. Since this exposure operation is the same as a conventional step-and-scan exposure operation, a detailed description thereof will be omitted.
- the substrate measurement system 70 measures the position information of the fine movement stage 22.
- the position of the fine movement stage 22 (substrate P) is measured using the substrate measurement system 70 including the encoder system, a conventional optical interferometer system is used. Compared with measurement, the influence of air fluctuations is small, and the position of the substrate P can be controlled with high accuracy, thereby improving the exposure accuracy.
- the substrate measuring system 70 measures the position of the substrate P with reference to the downward scale 78 fixed to the optical surface plate 18a (the apparatus main body 18) (via the upward scale 72), the projection optical system is substantially provided.
- the position of the substrate P can be measured with reference to 16.
- the position control of the substrate P can be performed based on the illumination light IL, so that the exposure accuracy can be improved.
- the configuration of the substrate measurement system 70 described above can be changed as appropriate as long as the position information of the fine movement stage 22 can be obtained with a desired accuracy within the movable range of the fine movement stage 22 (substrate P).
- a long scale having the same length as the scale base 84 is used as the upward scale 72, but the present invention is not limited to this, and the encoder disclosed in US Patent Publication No. 2015/147319 is used.
- scales having a shorter length in the X-axis direction may be arranged at predetermined intervals in the X-axis direction.
- the distance between the pair of heads 74x and 74y adjacent in the X-axis direction is made larger than the gap. Accordingly, it is preferable to always arrange one head 74x, 74y so as to face the scale. The same applies to the relationship between the downward scale 78 and the upward heads 80x and 80y.
- the upward scale 72 is arranged on the + Y side and the ⁇ Y side of the fine movement stage 22, respectively, it is not limited to this, and it may be arranged only on one side (+ Y side or ⁇ Y side only).
- the position measurement of the fine movement stage 22 in the ⁇ z direction is always performed.
- the number and arrangement of the heads 74x and 74y should be set so that at least two downward X heads 74x (or downward Y heads 74y) always face the scale.
- the downward scale 78 if the position measurement in the X axis, the Y axis, and the ⁇ z direction of the Y coarse movement stage 24 can always be performed, the number and arrangement of the downward scale 78 and the upward heads 80x and 80y are as follows. Changes can be made as appropriate.
- the upward scale 72 and the downward scale 78 are formed with two-dimensional diffraction gratings having the X-axis and Y-axis directions as periodic directions.
- Y diffraction gratings having a periodic direction may be individually formed on the scales 72 and 78.
- the X-axis and Y-axis directions are periodic directions.
- the diffraction grating The periodic direction is not limited to this and can be changed as appropriate.
- the Z tilt position information of the substrate P may be measured with a downward displacement sensor attached to the head base 88 and using the displacement sensor as a reference with respect to the scale base 84 (or the reflective surface of the upward scale 72). .
- at least three of the plurality of downward heads 74x and 74y are two-dimensional heads (so-called XZ heads or YZ heads) capable of measuring in the vertical direction together with position measurement in the direction parallel to the horizontal plane.
- the Z tilt position information of the substrate P may be obtained by using the lattice surface of the upward scale 72 by the two-dimensional head.
- the Z tilt information of the Y coarse movement stage 24 may be measured based on the scale base 92 (or the downward scale 78).
- the XZ head or YZ head for example, an encoder head having the same configuration as the displacement measurement sensor head disclosed in US Pat. No. 7,561,280 can be used.
- a liquid crystal exposure apparatus according to a second embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the second embodiment is substantially the same as that of the first embodiment except that the configuration of the substrate stage apparatus 220 (including the measurement system) is different. Only elements that have the same configuration or function as those of the first embodiment are denoted by the same reference numerals as those of the first embodiment, and description thereof is omitted as appropriate.
- the substrate stage apparatus 220 includes a first system including a first moving body (here, the substrate holder 32) and a second system including a second moving body (here, the X coarse movement stage 222).
- System. 9 and 10 are plan views showing only the second system and the first system, respectively.
- the X coarse movement stage 222 has a pair of floors (see FIG. 8) installed on the floor F (see FIG. 8), similarly to the Y coarse movement stage 24 (see FIG. 1) of the first embodiment. It is placed on the base frame 224 so as to be movable in the X-axis direction via a mechanical linear guide device (see FIG. 8).
- a Y stator 226 is attached in the vicinity of both ends of the X coarse movement stage 222 in the X-axis direction.
- the Y stator 226 is made of a member extending in the Y-axis direction, and an X mover 228 is attached in the vicinity of both ends in the longitudinal direction.
- Each X mover 228 constitutes an X linear motor in cooperation with an X stator 230 (not shown in FIG. 8), and the X coarse movement stage 222 is predetermined in the X-axis direction by a total of four X linear motors. It is driven with a long stroke.
- the X stator 230 is installed on the floor F in a state of being physically separated from the apparatus main body 18 (see FIG. 1).
- the substrate holder 32 is placed on the Y beam guide 232 via the Y table 234.
- the Y beam guide 232 is composed of a member extending in the Y-axis direction, and an X slide member 236 is attached to the vicinity of both ends in the longitudinal direction on the lower surface thereof.
- Each X slide member 236 is engaged with an X guide member 238 fixed to the lower base 18c (see FIG. 8) so as to be movable in the X-axis direction.
- X movers 240 are attached in the vicinity of both ends in the longitudinal direction of the Y beam guide 232.
- Each X mover 240 forms an X linear motor in cooperation with the X stator 230 (see FIG. 9), and the Y beam guide 232 has a predetermined long stroke in the X-axis direction by a total of two X linear motors. It is driven by.
- the Y table 234 is made of a member having an inverted U-shaped cross section, and the Y beam guide 232 is inserted through an air bearing 242 that is swingably mounted between a pair of opposing surfaces. Yes. Further, the Y table 234 is placed on the Y beam guide 232 via a minute gap by ejecting pressurized gas from an air bearing (not shown) on the upper surface of the Y beam guide 232. As a result, the Y table 234 is movable with a long stroke in the Y-axis direction with respect to the Y beam guide 232, and is rotatable with a slight angle in the ⁇ z direction.
- the Y table 234 moves integrally with the Y beam guide 232 in the X-axis direction due to the rigidity of the gas film formed by the air bearing 242.
- Y movers 244 are attached to the vicinity of both ends of the Y table 234 in the X-axis direction.
- the Y mover 244 forms a Y linear motor in cooperation with the Y stator 226, and the Y table 234 has a predetermined long stroke along the Y beam guide 232 in the Y axis direction by a total of two Y linear motors. And is slightly driven in the ⁇ z direction.
- the X coarse movement stage 222 is driven in the X-axis direction by four X linear motors (X mover 228, X stator 230), two Y attached to the X coarse movement stage 222.
- the stator 226 also moves in the X axis direction.
- the main controller (not shown) moves the Y beam guide 232 in the X-axis direction by two X linear motors (X mover 240 and X stator 230) so that a predetermined positional relationship with the X coarse movement stage 222 is maintained.
- the Y table 234 that is, the substrate holder 32
- the X coarse movement stage 222 is a member that can move so that the position of the substrate holder 32 and the X-axis direction is within a predetermined range.
- the main control device moves the substrate holder 32 by using two Y linear motors (Y mover 244 and Y stator 226) in parallel with or independently of the movement of the substrate holder 32 in the X-axis direction. Drive appropriately in the Y-axis direction and the ⁇ z direction.
- the substrate measurement system 250 is different from the first embodiment in the extending direction of each of the upward scale 252 and the downward scale 254 (in the wide measurement range) by 90 ° around the Z axis. Is that the position information of the first moving body (here, the substrate holder 32) is obtained with reference to the optical surface plate 18a (see FIG. 1) via the second moving body (here, the X coarse movement stage 222). This is substantially the same as the first embodiment.
- an upward scale 252 extending in the Y-axis direction is fixed to the upper surface of each of the pair of Y stators 226.
- a pair of head bases 256 spaced in the Y-axis direction are fixed to both side surfaces of the substrate holder 32 in the X-axis direction.
- two downward X heads 74x and two downward Y heads 74y are attached to the head base 256 so as to face the corresponding upward scales 252. ing.
- Position information in the XY plane of the substrate holder 32 with respect to the X coarse movement stage 222 is obtained by a main controller (not shown) using a total of eight X linear encoders and a total of eight Y linear encoders.
- a head base 258 is fixed in the vicinity of both ends of the Y stator 226 in the Y-axis direction.
- the head base 258 includes two upward X heads 80x and two upward Y heads 80y (see FIG. 9) on the lower surface of the optical surface plate 18a (see FIG. 1). It is attached so as to face the corresponding downward scale 254 fixed.
- the relative positional relationship between the upward scale 252 and each of the heads 80x and 80y is known.
- Position information in the XY plane with respect to the optical surface plate 18a of the X coarse movement stage 222 is obtained by a main controller (not shown) using a total of eight X linear encoders and a total of eight Y linear encoders.
- two upward scales 252 are attached to the X coarse movement stage 222, and four downward scales 254 are attached to the optical surface plate 18a (see FIG. 1).
- the number and arrangement of the scales 252 and 254 are not limited to this, and can be appropriately increased or decreased.
- the number and arrangement of the heads 74x, 74y, 80x, 80y facing the scales 252, 254 are not limited to this, and can be increased or decreased as appropriate. The same applies to third to seventeenth embodiments to be described later.
- a liquid crystal exposure apparatus according to a third embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the third embodiment is substantially the same as that of the second embodiment except that the configuration of the substrate stage device 320 (including the measurement system) is different. Only elements that have the same configuration or function as those of the second embodiment will be denoted by the same reference numerals as those of the second embodiment, and description thereof will be omitted as appropriate.
- the substrate stage apparatus 320 includes a first system including the substrate holder 32 (see FIG. 14) and a second system including the X coarse movement stage 222. (See FIG. 13). Since the configurations (including the drive system) of the substrate holder 32 and the X coarse movement stage 222 are the same as those in the second embodiment, description thereof is omitted.
- the substrate measurement system 350 of the third embodiment is conceptually similar to the first and second embodiments, and the position information of the first moving body (here, the substrate holder 32) is transferred to the second movement. It calculates
- the Y beam guide 232 is a member that can move so that the position of the substrate holder 32 and the X-axis direction is within a predetermined range.
- the substrate measurement system 350 will be described in detail.
- an upward scale 352 is fixed to the upper surface of the Y beam guide 232.
- head bases 354 are fixed to both side surfaces of the Y table 234 (not shown in FIG. 14; see FIG. 12) in the Y-axis direction.
- two downward X heads 74x and two downward Y heads 74y are attached to each head base 354 so as to face the upward scale 352.
- Position information in the XY plane with respect to the Y beam guide 232 of the substrate holder 32 is obtained by a main controller (not shown) using a total of four X linear encoders and a total of four Y linear encoders.
- head bases 356 are fixed in the vicinity of both ends of the Y beam guide 232 in the Y-axis direction.
- the head base 356 has two upward X heads 80x and two upward Y heads 80y fixed to the lower surface of the optical surface plate 18a (see FIG. 1). It is attached to face the downward scale 358.
- the relative positional relationship between the upward scale 352 and the respective heads 80x and 80y attached to the head base 356 is known.
- Position information of the Y beam guide 232 in the XY plane with respect to the optical surface plate 18a is obtained by a main controller (not shown) using a total of four X linear encoders and a total of four Y linear encoders.
- the third embodiment has a smaller number of each of the upward scale 352 and the downward scale 358 and has a simple configuration.
- a liquid crystal exposure apparatus according to a fourth embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the fourth embodiment is substantially the same as that of the second embodiment except that the configuration of the substrate stage apparatus 420 (including the measurement system) is different. Only elements that have the same configuration or function as those of the second embodiment will be denoted by the same reference numerals as those of the second embodiment, and description thereof will be omitted as appropriate.
- the substrate stage apparatus 420 includes a first system including the substrate holder 32 (see FIG. 18) and a second system including the X coarse movement stage 222. (See FIG. 17).
- an X mover 422 is fixed to the lower surface of the X coarse movement stage 222.
- the X mover 422 cooperates with the X stator 424 integrally attached to the pair of base frames 224 to drive the X coarse movement stage 222 with a predetermined long stroke in the X axis direction. Is configured.
- An XY stator 426 is attached in the vicinity of both ends of the X coarse movement stage 222 in the X-axis direction.
- the Y beam guide 232 is mechanically connected to the X coarse movement stage 222 by four connection members 428 (see FIG. 15).
- the structure of the connecting member 428 is the same as the connecting members 46 and 54 (see FIG. 2) described above.
- the Y table 430 is placed on the Y beam guide 232 in a non-contact state.
- a substrate holder 32 is fixed on the Y table 430.
- An XY mover 432 is attached in the vicinity of both ends of the Y table 430 in the X-axis direction.
- the XY mover 432 forms an XY2DOF motor in cooperation with the XY stator 426, and the Y table 430 is driven with a predetermined long stroke in the Y-axis direction by a total of two XY2DOF motors. It is slightly driven in the ⁇ z direction.
- the main controller uses a total of two XY2DOF motors to generate the Y table 430 (that is, the substrate).
- the holder 32) applies a thrust force in the X-axis direction so that a predetermined positional relationship with the Y-beam guide 232 is maintained in the X-axis direction.
- the X coarse movement stage 222 is a member that can move so that the position of the substrate holder 32 and the X-axis direction is within a predetermined range.
- the Y table 430 does not have a swingable air bearing 242 (see FIG. 8), and the Y beam guide 232 of this embodiment is actually a Y table. It does not guide the movement of 430 in the Y-axis direction.
- the substrate measurement system 450 of the fourth embodiment is conceptually similar to the first to third embodiments, and the position information of the first moving body (here, the substrate holder 32) is transferred to the second movement. It is determined based on the optical surface plate 18a (see FIG. 1) via a body (here, X coarse movement stage 222).
- a body here, X coarse movement stage 222.
- an upward scale 452 is fixed to the upper surface of one (here, ⁇ X side) XY stator 426 of the pair of XY stators 426.
- a pair of head bases 454 are fixed to the side surface on the ⁇ X side of the substrate holder 32 so as to be separated from each other in the Y-axis direction.
- two downward X heads 74x and two downward Y heads 74y are attached to each head base 454 so as to face the upward scale 452 (see FIG. (See FIG. 16).
- Position information in the XY plane of the substrate holder 32 with respect to the X coarse movement stage 222 is obtained by a main controller (not shown) using a total of four X linear encoders and a total of four Y linear encoders.
- a pair of head bases 456 are fixed to the ⁇ X side XY stator 426 so as to be separated in the Y-axis direction.
- two upward X heads 80x and two upward Y heads 80y are fixed to the head base 456 on the lower surface of the optical surface plate 18a (see FIG. 1). It is attached so as to face the downward scale 458 (see FIG. 15).
- the relative positional relationship between the upward scale 452 and the heads 80x and 80y attached to the head base 456 is known.
- Position information in the XY plane with respect to the optical surface plate 18a of the X coarse movement stage 222 is obtained by a main controller (not shown) using a total of four X linear encoders and a total of four Y linear encoders.
- an upward scale 452 may be attached only to the other of the pair of XY stators 426 or both.
- the head bases 454 and 456 and the downward scale 458 may be additionally arranged corresponding to the upward scale 452.
- a liquid crystal exposure apparatus according to a fifth embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the fifth embodiment is substantially the same as that of the fourth embodiment except that the configuration of the substrate measurement system 550 is different.
- the configuration of the substrate measurement system 550 is substantially the same as that of the substrate measurement system 350 (see FIG. 11 and the like) of the third embodiment.
- elements having the same configurations or functions as those of the third or fourth embodiment will be denoted by the same reference numerals as those of the third or fourth embodiment, and description thereof will be omitted as appropriate. To do.
- the configuration (excluding the measurement system) of the substrate stage apparatus 520 according to the fifth embodiment is substantially the same as the substrate stage apparatus 420 (see FIG. 15) according to the fourth embodiment. That is, the substrate stage apparatus 520 has a first system (see FIG. 22) including the substrate holder 32 and a second system (see FIG. 21) including the X coarse movement stage 222, and the X coarse movement stage 222. And the Y beam guide 232 move integrally in the X-axis direction.
- the Y table 430 to which the substrate holder 32 is fixed is driven with a long stroke in the Y-axis direction with respect to the X coarse movement stage 222 by two 2DOF motors, and is slightly driven in the X-axis direction and the ⁇ z direction.
- the conventional coarse movement stage is driven based on the measurement result of the encoder with low measurement accuracy, but in this embodiment, the X coarse movement stage 222 can be driven and controlled based on the measurement result of the high-precision two-dimensional encoder. Is possible. Therefore, although positioning can be performed with higher accuracy than the conventional fine movement stage, the X coarse movement stage 222 is not as responsive as the fine movement stage (the substrate holder 32 in the present embodiment) with respect to position control. Therefore, it is desired to control the X position of the substrate holder 32 so as to move while performing precise positioning at a constant speed regardless of the position of the X coarse movement stage 222 during the scanning operation.
- the X coarse movement stage 222 that moves while performing rough positioning control with low responsiveness is relatively slightly driven in the X-axis direction. At this time, if the X coarse movement stage 222 is accelerated, an encoder reading error with respect to the upward scale 452 may occur. Therefore, it is better to control the X coarse movement stage 222 so that it moves with loose positioning (low responsiveness). Of the embodiments described later, in the embodiment in which the coarse movement stage is driven for the scanning operation, the coarse movement stage may be controlled similarly.
- the configuration of the substrate measurement system 550 according to the fifth embodiment is substantially the same as the substrate measurement system 350 (see FIG. 11) according to the third embodiment, and the first moving body (here, the substrate)
- the position information of the holder 32) is obtained based on the optical surface plate 18a (see FIG. 1) via the second moving body (here, the Y beam guide 232).
- the pair of head bases 354 fixed to the Y table 430 see FIG. 20
- two downward X heads 74x and two downward Y heads 74y are fixed to the upper surface of the Y beam guide 232.
- the position information in the XY plane with respect to the Y beam guide 232 of the substrate holder 32 is a total of four X linear encoders, and a total of four Ys. It is obtained by a main controller (not shown) using a linear encoder.
- the pair of head bases 356 fixed to the Y beam guide 232 have two upward X heads 80x and two upward Y heads 80y fixed to the lower surface of the optical surface plate 18a (see FIG. 1). It is attached so as to face the corresponding downward scale 358 (see FIG. 19).
- Position information of the Y beam guide 232 in the XY plane with respect to the optical surface plate 18a is obtained by a main controller (not shown) using a total of four X linear encoders and a total of four Y linear encoders.
- the configuration of the liquid crystal exposure apparatus according to the sixth embodiment is substantially the same as that of the first embodiment except that the configuration of the substrate stage device 620 and its measurement system is different. Therefore, only the differences will be described below.
- the elements having the same configurations or functions as those of the first embodiment will be described with the same reference numerals as those of the first embodiment, and description thereof will be omitted as appropriate.
- the substrate stage device 620 includes a substrate measurement system 680 including a first moving body (here, a substrate holder 622), a second moving body (here, a measurement table 624), a substrate table 626, and X A coarse movement stage 628 is provided.
- a substrate measurement system 680 including a first moving body (here, a substrate holder 622), a second moving body (here, a measurement table 624), a substrate table 626, and X
- a coarse movement stage 628 is provided.
- the substrate holder 622 is a frame-like (frame-like) member having a rectangular shape in plan view, which is a combination of a pair of members extending in the Y-axis direction and a pair of members extending in the X-axis direction.
- the substrate P is disposed in the opening of the substrate holder 622.
- Four suction pads 630 protrude from the inner wall surface of the substrate holder 622, and the substrate P is placed on these suction pads 630.
- Each suction pad 630 sucks and holds a non-exposed area (in the present embodiment, near the four corners) set at the outer peripheral edge of the lower surface of the substrate P.
- the exposure region including the central portion is non-contact supported from below by the substrate table 626 as shown in FIG.
- the substrate holder 32 (see FIG. 2 and the like) in the first to fifth embodiments performs flattening by sucking and holding the substrate P, whereas the substrate table 626 according to the sixth embodiment is The flattening of the substrate P is performed in a non-contact state by performing the ejection of the pressurized gas to the lower surface of the substrate P and the suction of the gas between the substrate P and the upper surface of the substrate table 626 in parallel.
- the substrate holder 622 and the substrate table 626 are physically separated from each other.
- the substrate P held by the substrate holder 622 can move relative to the substrate table 626 in the XY plane integrally with the substrate holder 622.
- a stage main body 632 is fixed to the lower surface of the substrate table 626 as in the first embodiment.
- the X coarse movement stage 628 is a member for moving the substrate table 626 with a long stroke in the X-axis direction, and is a pair of base frames installed on the floor F in a state of being physically separated from the undercarriage 18c. It is placed on 634 in a state of being movable in the X-axis direction via a mechanical linear guide device 636.
- the X coarse movement stage 628 is driven with a long stroke in the X-axis direction on a pair of base frames 634 by an actuator (not shown) (such as a linear motor or a ball screw device).
- Y stators 638 are fixed (one is not shown in FIG. 23).
- the Y stator 638 forms a Y linear motor in cooperation with the Y mover 640.
- the Y mover 640 is mechanically constrained to move integrally in the X axis direction when the Y stator 638 moves in the X axis direction.
- a stator 644 constituting an XY2DOF motor is attached to the Y mover 640 in cooperation with a mover 642 (see FIG. 24) attached to the substrate holder 622.
- the substrate table 626 passes through a stage main body 632 (not shown in FIG. 25; see FIG. 23) with respect to the X coarse movement stage 628 (not shown in FIG. 25) (in FIG. 25). And mechanically connected via a plurality of connecting members 646.
- the structure of the connecting member 646 is the same as the connecting members 46 and 54 (see FIG. 2) described above.
- the substrate holder 32 moves with a long stroke in the X-axis and Y-axis directions with respect to the projection optical system 16 (see FIG. 5 and the like).
- the substrate table 626 of the embodiment is configured to be movable with a long stroke only in the X-axis direction, and is not movable in the Y-axis direction.
- the Y stator 638, the Y movable element 640, and the stator 644 are arranged in a plane (at the same height position).
- the stage main body 632 is connected to the X coarse movement stage 628 via a pseudo spherical bearing device similar to that in the first embodiment (in FIG. 23, hidden behind the paper surface such as the Y mover 640 and the like). Is supported from below by a weight canceling device 42 disposed in an opening (not shown) formed in the central portion of the.
- the configuration of the weight canceling device 42 is the same as that of the first embodiment, and is connected to the X coarse movement stage 628 via a connecting member (not shown), and integrally with the X coarse movement stage 628 in the X-axis direction. Move with a long stroke only.
- the weight cancellation device 42 is placed on the X guide 648.
- the weight cancellation device 42 of the present embodiment is configured to move only in the X-axis direction, unlike the Y step guide 44 (see FIG. 2) in the first embodiment, the X guide 648 includes the lower base 18c. It is fixed to.
- the stage body 632 is slightly driven in the Z axis, ⁇ x, and ⁇ y directions with respect to the X coarse movement stage 628 by a plurality of linear coil motors (hidden on the back side of the Y stator 638 in FIG. 23). The point is the same as in the first embodiment.
- a plurality of air guides 652 are attached to both side surfaces of the stage main body 632 in the Y-axis direction via support members 650.
- the air guides 652 are rectangular members in plan view, and in this embodiment, four air guides 652 are arranged on each of the + Y side and the ⁇ Y side of the substrate table 626.
- the length in the Y-axis direction of the guide surface formed by the four air guides 652 is set to be equivalent to that of the substrate table 626, and the height position of the guide surface is equivalent to (or somewhat to the upper surface of the substrate table 626). Low) is set.
- the substrate stage device 620 when the X coarse movement stage 628 moves with a long stroke in the X-axis direction during scanning exposure or the like, the substrate table 626 (and a plurality of airs) is pulled by the X coarse movement stage 628.
- the guide 652) integrally moves with a long stroke in the X-axis direction.
- the 2DOF motor stator 644 (see FIG. 25) attached to the Y mover 640 also moves in the X axis direction. To do.
- the main controller controls the 2DOF motor so that the positions of the substrate table 626 and the substrate holder 622 in the X-axis direction are within a predetermined range, and applies thrust in the X-axis direction to the substrate holder 622. . Further, the main control device controls the 2DOF motor to slightly drive the substrate holder 622 with respect to the substrate table 626 in the X axis, Y axis, and ⁇ z directions as appropriate. Thus, in this embodiment, the substrate holder 622 has a function as a so-called fine movement stage.
- the main controller moves Y by a Y linear motor as shown in FIG.
- the child 640 is moved in the Y-axis direction, and the substrate holder 622 is moved in the Y-axis direction with respect to the substrate table 626 by applying a thrust in the Y-axis direction to the substrate holder 622 using a 2DOF motor.
- a region (exposure region) of the substrate P on which the mask pattern is projected via the projection optical system 16 is always corrected by the substrate table 626 in the Y-axis direction of the substrate table 626.
- the dimensions are set.
- Each air guide 652 is disposed so as not to hinder relative movement of the substrate holder 622 and the substrate table 626 in the Y-axis direction (not to contact the substrate holder 622).
- Each air guide 652 supports a portion of the substrate P that protrudes from the substrate table 626 from below by cooperating with the substrate table 626 by jetting pressurized gas to the lower surface of the substrate P.
- Each air guide 652 does not perform flattening of the substrate P unlike the substrate table 626.
- the substrate table 626 and the substrate holder 622 are respectively connected to the projection optical system 16 (see FIG. 23) while the substrate P is supported by the substrate table 626 and the air guide 652.
- the air guide 652 may be driven in the X-axis direction integrally with the stage main body 632 or may not be driven.
- the dimension in the X-axis direction may be approximately the same as the driving range of the substrate P in the X-axis direction. Thereby, it is possible to prevent a partial region of the substrate not supported by the substrate table 626 from being supported.
- the position information of the first moving body (fine movement stage 22 in the first embodiment) is used as the Y coarse movement stage 24 which is a member for driving the fine movement stage 22.
- the position information of the first moving body (here, the substrate holder 622) is independent of the substrate holder 622. Is obtained with reference to the optical surface plate 18a via the second moving body (here, the measurement table 624) arranged at the position.
- two (four in total) measurement tables 624 are arranged on the + Y side and the ⁇ Y side of the projection optical system 16 so as to be separated from each other in the X-axis direction (FIG. 23, FIG. 23).
- the number and arrangement of the measurement tables 624 can be appropriately changed and are not limited to this.
- the measurement table 624 is movable in the Y axis direction by a Y linear actuator 682 fixed in a suspended state on the lower surface of the optical surface plate 18a (the substrate holder 622 can be moved in the Y axis direction). Driven with stroke (equivalent to distance).
- the type of the Y linear actuator 682 is not particularly limited, and a linear motor, a ball screw device, or the like can be used.
- each measurement table 624 Similar to the head base 96 of the first embodiment (see FIG. 2, FIG. 3, etc.), the upper surface of each measurement table 624 has two upward X heads 80x and two heads as shown in FIG. An upward Y head 80y is attached.
- downward scales 684 extending in the Y-axis direction corresponding to the respective measurement tables 624 (that is, four) are provided in the first embodiment. It is fixed in the same manner as the downward scale 78 (see FIG. 2, FIG. 3, etc.) (see FIG. 26).
- the downward scale 684 has a two-dimensional diffraction grating on its lower surface so that the measurement range in the Y-axis direction of the measurement table 624 is wider (longer) than the measurement range in the X-axis direction.
- two X linear encoder systems are configured by the two upward X heads 80x included in each measurement table 624 and the corresponding downward scale 684 (fixed scale), and each measurement table 624 includes 2 2
- Two upward Y heads 80y and a corresponding downward scale 684 (fixed scale) constitute two Y linear encoder systems.
- the main control device (not shown) drives the substrate holder 622 with a long stroke in the Y-axis direction so that the position in the Y-axis direction with respect to the substrate holder 622 is within a predetermined range.
- the position of each measurement table 624 in the Y-axis direction is controlled. Therefore, the four measurement tables 624 in total perform substantially the same operation. Note that the four measurement tables 624 do not need to move in strict synchronization with each other, and do not need to move in strict synchronization with the substrate holder 622.
- the main controller independently uses the outputs of the two X linear encoder systems and the two Y linear encoder systems described above to independently position information of each measurement table 624 in the X axis direction, the Y axis direction, and the ⁇ z direction. Ask.
- a downward scale 686 extending in the X-axis direction is attached to the lower surfaces of the two measurement tables 624 on the + Y side (see FIG. 23). That is, the two measurement tables 624 cooperate to support the downward scale 686 in a suspended manner.
- downward scales 686 extending in the X-axis direction are attached to the lower surfaces of the two measurement tables 624 on the ⁇ Y side.
- the downward scale 686 has a two-dimensional diffraction grating on its lower surface so that the measurement range in the X-axis direction of the substrate holder 622 is wider (longer) than the measurement range in the Y-axis direction.
- the relative positional relationship between the upward heads 80x and 80y fixed to the measurement table 624 and the downward scale 686 is known.
- two head bases 688 are fixed on the upper surface of the substrate holder 622 corresponding to the two downward scales 684 (see FIG. 26) in total.
- the head base 688 is disposed with the central portion of the substrate P sandwiched between the + Y side and the ⁇ Y side of the substrate P in a state where the substrate P is held by the substrate holder 622.
- Two upward X heads 80 x and two upward Y heads 80 y are attached to the upper surface of the head base 688.
- the position of the substrate holder 622 and each measurement table 624 are controlled so that the position in the Y-axis direction is within a predetermined range. Specifically, the position of each measurement table 624 in the Y-axis direction is controlled so that the measurement beams from the heads 80x and 80y attached to the substrate holder 622 do not deviate from the lattice plane of the downward scale 686. That is, the substrate holder 622 and each measurement table 624 move in the same direction at substantially the same speed so that the facing state of the head base 688 and the downward scale 686 is always maintained.
- four X linear encoder systems are configured by the four upward X heads 80x of the substrate holder 622 and the corresponding downward scale 686 (movable scale), and the substrate
- the four upward Y heads 80y included in the holder 622 and the corresponding downward scale 686 (movable scale) constitute a four Y linear encoder system.
- the main controller (not shown) obtains positional information of the substrate holder 622 in the XY plane with respect to the four measurement tables 624 in total. .
- the main control device includes position information (first information) with respect to each measurement table 624 of the substrate holder 622, position information (second information) with respect to the optical surface plate 18a of each measurement table 624, and an upward head 80x in each measurement table 624, Based on the position information (third information) between 80y and the downward scale 686, the position information of the substrate holder 622 (substrate P) is obtained with reference to the optical surface plate 18a.
- a liquid crystal exposure apparatus according to the seventh embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the seventh embodiment is substantially the same as that of the sixth embodiment except that the configuration of the substrate stage device 720 and its measurement system is different.
- the elements having the same configurations or functions as those of the sixth embodiment will be described with the same reference numerals as those of the sixth embodiment, and description thereof will be omitted as appropriate.
- the substrate stage device 720 includes a substrate measuring system 780 including a first moving body (here, a pair of substrate holders 722), a second moving body (here, a measurement table 624), and the like. ing.
- the substrate holder 622 is formed in a rectangular frame shape surrounding the entire outer periphery of the substrate P, whereas a pair of substrate holders according to the seventh embodiment. 722 are physically separated from each other, and one substrate holder 722 sucks and holds the vicinity of the + X side end of the substrate P, and the other substrate holder 722 closes the ⁇ X side end of the substrate P. It differs in the point of adsorption holding.
- the configuration and function of the substrate table 626 and the drive system (including the X coarse movement stage 628) for driving the substrate table 626 are the same as those in the sixth embodiment, and a description thereof will be omitted.
- each substrate holder 722 has a suction pad 726 that sucks and holds the central portion of the substrate P in the Y-axis direction from the lower surface.
- the -X side substrate holder 722 has a measurement plate 728 attached to the upper surface, and therefore the length in the Y-axis direction is set longer than the + X side substrate holder 722. Since the holding function, the position control operation of the substrate P, and the like are common to the pair of substrate holders 722, in this embodiment, the pair of substrate holders 722 will be described with the same reference numerals for convenience.
- an index used for calibration or the like related to optical characteristics (scaling, shift, rotation, etc.) of the projection optical system 16 is formed on the measurement plate 728.
- Each substrate holder 722 is made up of a corresponding Y by a 3DOF motor composed of a stator 730 (refer to FIG. 30) included in the Y mover 640 and a mover 732 (refer to FIG. 29) included in each substrate holder 722, respectively.
- the mover 640 is slightly driven in the X, Y, and ⁇ z directions.
- a combination of two X linear motors and one Y linear motor is used as the 3DOF motor, but the configuration of the 3DOF motor is not particularly limited and can be changed as appropriate.
- each substrate holder 722 is independently driven by a 3DOF motor, but the operation of the substrate P itself is the same as in the sixth embodiment.
- each substrate holder 722 is supported in a non-contact manner from below by an air guide 734 extending in the Y-axis direction (refer to FIG. 31 for the substrate holder 722 on the ⁇ X side).
- the height position of the upper surface of the air guide 734 is set lower than the height position of the upper surface of the substrate table 626 and the air guide 652.
- the length of the air guide 734 is set to be equal to (or somewhat longer than) the movable distance of the substrate holder 722 in the Y-axis direction.
- the air guide 734 is also fixed to the stage main body 632 similarly to the air guide 652, and moves with a long stroke in the X-axis direction integrally with the stage main body 632. Note that the air guide 734 may be applied to the substrate stage device 620 of the sixth embodiment.
- the substrate measurement system 780 according to the seventh embodiment is conceptually the substrate according to the sixth embodiment except that the arrangement of the heads on the substrate P side, the number and arrangement of the measurement tables 624 are different. This is almost the same as the measurement system 680 (see FIG. 26). That is, the substrate measurement system 780 obtains the position information of the first moving body (here, each substrate holder 722) with reference to the optical surface plate 18a via the measurement table 624. This will be specifically described below.
- the configuration of the measurement table 624 included in the substrate measurement system 780 is the same as that of the sixth embodiment except for the arrangement.
- the measurement table 624 is arranged on the + Y side and the ⁇ Y side of the projection optical system 16, whereas the measurement table according to the seventh embodiment is used.
- the position of the table 624 in the Y-axis direction overlaps with the projection optical system 16, and one measurement table 624 (see FIG. 28) is the + X side of the projection optical system 16 and the other measurement.
- a table 624 (not shown in FIG. 28) is arranged on the ⁇ X side of the projection optical system 16 (see FIG. 31).
- the measurement table 624 is driven by the Y linear actuator 682 with a predetermined stroke in the Y-axis direction.
- the position information of each measurement table 624 in the XY plane includes upward heads 80x and 80y (see FIG. 31) attached to the measurement table 624, and a corresponding downward scale 684 fixed to the lower surface of the optical surface plate 18a. are independently obtained by a main controller (not shown) using the encoder system configured by the above.
- a downward scale 782 is fixed to the lower surfaces of the two measurement tables 624 (see FIG. 31). That is, in the sixth embodiment (see FIG. 27), one downward scale 686 is suspended and supported by two measurement tables 624, whereas in the seventh embodiment, one measurement table 624 is supported. One downward scale 782 is suspended and supported.
- the downward scale 782 has a two-dimensional diffraction grating on its lower surface so that the measurement range in the X-axis direction of each substrate holder 722 is wider (longer) than the measurement range in the Y-axis direction.
- the relative positional relationship between the upward heads 80x and 80y fixed to the measurement table 624 and the downward scale 782 is known.
- a head base 784 is fixed to each substrate holder 722.
- two upward X heads 80x and two upward Y heads 80y are attached so as to face the corresponding downward scale 782 (see FIG. 31). ). Since the position measurement operation of the substrate P during the position control of the substrate P in the seventh embodiment is substantially the same as that in the sixth embodiment, description thereof will be omitted.
- a liquid crystal exposure apparatus according to the eighth embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the eighth embodiment is substantially the same as that of the sixth embodiment except that the configuration of the substrate stage device 820 and its measurement system is different.
- the elements having the same configurations or functions as those of the sixth embodiment will be described with the same reference numerals as those of the sixth embodiment, and description thereof will be omitted as appropriate.
- the substrate stage apparatus 820 of the eighth embodiment includes a first moving body (here, the substrate holder 822), a second moving body (here, the X coarse movement stage 628), a substrate measurement system 880, and the like.
- the substrate holder 822 for holding the substrate P is formed in a rectangular frame shape surrounding the entire outer periphery of the substrate P, as in the sixth embodiment (see FIG. 26 and the like). . Since the drive system for driving the substrate holder 822 and the substrate table 626 is the same as that of the sixth embodiment, description thereof is omitted. Note that the substrate stage apparatus 820 of the eighth embodiment includes an air guide 734 that supports the substrate holder 822 from the lower side in a non-contact manner, as in the seventh embodiment (see FIG. 30).
- the substrate measurement system 880 will be described.
- the position information of the substrate holder 622 is obtained based on the optical surface plate 18a via the measurement table 624
- the position information of the substrate holder 822 is obtained with reference to the optical surface plate 18a via the X coarse movement stage 628 for driving the substrate table 626 in the X-axis direction.
- the substrate measurement system 880 is conceptually common with the substrate measurement system 250 (see FIG. 8 and the like) according to the second embodiment.
- the X coarse movement stage 628 in the eighth embodiment is composed of a pair of flat plate (strip-shaped) members extending in the X-axis direction and disposed corresponding to the pair of base frames 634 (see FIG. 34). Since they are functionally the same, the same reference numerals as those of the X coarse movement stage 628 of the sixth embodiment are given for convenience.
- an upward scale 882 is fixed to the upper surface of each of the pair of Y stators 638 fixed to the X coarse movement stage 628, as in the second embodiment (see FIG. 9). ing. Since the configuration and function of the upward scale 882 are the same as those of the upward scale 252 (see FIG. 9) of the second embodiment, description thereof is omitted here.
- a pair of head bases 884 spaced in the Y-axis direction are fixed near the + X side and ⁇ X side ends of the substrate holder 822, respectively.
- a total of four head bases 884 are each provided with one downward X head 74x, one downward Y head 74y, and one downward Z head 74z so as to face the upward scale 882 (see FIG. 34). (See FIG. 33). Since the configurations and functions of the X head 74x and the Y head 74y are the same as those of the X head 74x and the Y head 74y (see FIG. 3 respectively) of the first embodiment, the description thereof is omitted here.
- a total of four downward X heads 74x and a corresponding upward scale 882 constitute four X linear encoder systems (see FIG. 35), and a total of four downward Y heads.
- 74 Y and the corresponding upward scale 882 constitute four Y linear encoder systems (see FIG. 35).
- the main control device uses the outputs of the four X linear encoder systems and the four Y linear encoder systems as appropriate to position information of the substrate holder 822 in the X axis direction, the Y axis direction, and the ⁇ z direction ( First information) is obtained with reference to the X coarse movement stage 628.
- the configuration of the downward Z head 74z is not particularly limited, but a known laser displacement sensor or the like can be used.
- the Z head 74z measures the amount of displacement of the head base 884 in the Z-axis direction using the lattice plane (reflecting surface) of the corresponding upward scale 882 (see FIG. 35).
- the main controller (not shown) obtains displacement information in the Z tilt direction of the substrate holder 822 (that is, the substrate P) with respect to the X coarse movement stage 628 based on the outputs of the four Z heads 74z in total.
- a pair of head bases 886 separated in the X-axis direction are fixed near the + Y side and ⁇ Y side ends of the Y stator 638, respectively.
- Each of the eight head bases 886 is attached with one upward X head 80x, upward Y head 80y, and upward Z head 80z. Since the configurations and functions of the X head 80x and the Y head 80y are the same as those of the X head 80x and the Y head 80y (see FIG. 3 respectively) of the first embodiment, description thereof is omitted here.
- Information (third information) relating to the relative positional relationship between the heads 80x, 80y, and 80z and the upward scale 882 described above is known.
- One downward scale 888 is fixed to the lower surface of the optical surface plate 18a (see FIG. 32) corresponding to the pair of head bases 884 described above. That is, as shown in FIG. 35, a total of four downward scales 888 are fixed to the lower surface of the optical surface plate 18a. Since the configuration and function of the downward scale 888 are the same as the downward scale 254 (see FIG. 8) of the second embodiment, the description thereof is omitted here.
- a total of eight upward X heads 80x and a corresponding downward scale 888 constitute eight X linear encoder systems (see FIG. 35), and a total of eight upward Y heads. Eight Y linear encoder systems (see FIG. 35) are configured by 80y and the corresponding downward scale 888.
- the main control device (not shown) appropriately uses the outputs of the eight X linear encoder systems and the eight Y linear encoder systems to position the X coarse movement stage 628 in the X axis direction, the Y axis direction, and the ⁇ z direction.
- Information (second information) is obtained based on the optical surface plate 18a.
- the main controller (not shown) obtains displacement information in the Z tilt direction with respect to the optical surface plate 18a of the X coarse movement stage 628 based on the outputs of the eight Z heads 74z in total.
- the position information of the substrate P is obtained based on the optical surface plate 18a via the X coarse movement stage 628 (based on the first to third information).
- positional information in the Z tilt direction of the substrate P is also obtained with reference to the optical surface plate 18a via the X coarse movement stage 628.
- the substrate stage apparatus 920 is a pair of substrate holders that are physically separated from each other as in the seventh embodiment (see FIG. 29). 922.
- One substrate holder 922 holds the vicinity of the + X side end of the substrate P
- the other substrate holder 922 holds the vicinity of the ⁇ X side end of the substrate P
- the pair of substrate holders 922 includes a 3DOF motor. Is the same as that in the seventh embodiment in that it is independently driven with respect to the X coarse movement stage 628.
- the configuration and operation of the substrate measurement system 980 (see FIG. 38) according to the ninth embodiment are the same as those of the eighth embodiment except that the position information of each of the pair of substrate holders 922 is obtained independently. It is. That is, as shown in FIG. 36, a pair of head bases 884 that are spaced apart in the Y-axis direction are fixed to each substrate holder 922. Downward heads 74x, 74y, and 74z are attached to the head base 884 so as to face an upward scale 882 (see FIG. 37) fixed to the upper surface of the Y stator 638 (see FIG. 37). Since the configuration and operation of the position measurement system based on the optical surface plate 18a (see FIG. 28, etc.) of the X coarse movement stage 628 are the same as those in the seventh embodiment, description thereof will be omitted.
- the substrate P is held by the substrate holder 922 in the vicinity of both ends in the X-axis direction, whereas as shown in FIG. In the embodiment, the substrate P is different in that only the vicinity of an end portion on one side (in this embodiment, ⁇ X side) in the X-axis direction is sucked and held by the substrate holder 922. Since the substrate holder 922 is the same as that of the ninth embodiment, the description thereof is omitted here. Further, the configuration and operation of the substrate measurement system 1080 (see FIG. 41) according to the tenth embodiment are the same as those in the ninth embodiment, and thus the description thereof is omitted here.
- the Y stator 638 is disposed only on the ⁇ X side of the substrate table 626.
- the base frame 1024 is shorter than the substrate stage apparatus 920 (see FIG. 38) according to the ninth embodiment, and the overall structure is compact.
- the connecting member 1022 that connects the Y stator 638 and the air guide 734 has rigidity in the X-axis direction, and the Y stator 638 presses or pulls the substrate table 626. (Push and pull) is possible.
- the X guide 648 that supports the weight cancellation device 42 is fixed on the lower base 18c, but is not limited thereto, and is physically separated from the device body 18. You may install on the floor F in the state which carried out.
- the substrate P is placed on one side ( ⁇ X side in this embodiment) in the X-axis direction, as in the tenth embodiment (see FIG. 41 and the like). Only the vicinity of the end is held by the substrate holder 1122 (see FIG. 47).
- the width of the substrate holder 1122 (X-axis direction) is set to be somewhat longer than that of the substrate holder 922 (see FIG. 39) according to the tenth embodiment. .
- the substrate holder 1122 is supported by the air guide 1124 in a non-contact manner from below.
- the configuration and function of the air guide 1124 are substantially the same as those of the air guide 734 (see FIG. 30 and the like) according to the seventh to tenth embodiments, but in the X-axis direction corresponding to the substrate holder 1122. The difference is that the dimensions are set somewhat longer.
- the substrate measurement system 1180 obtains positional information of the substrate holder 1122 with reference to the optical surface plate 18a via the X coarse movement stage 628, as described in the tenth embodiment (FIG. 41). (See FIG. 45), but the arrangement of the upward scale 882 and the downward heads 74x and 74y (see FIG. 45) is different.
- the upward scale 882 is fixed to an air guide 1124 that supports the substrate holder 1122 in a floating manner.
- the height position of the upper surface (guide surface) of the air guide 1124 and the height position of the lattice surface (measurement surface) of the upward scale 882 are set to be substantially the same. Since the air guide 1124 is fixed to the stage main body 632, the upward scale 882 moves with respect to the substrate P so that the position in the XY plane is within a predetermined range.
- the substrate holder 1122 is formed with a recessed portion that opens downward, and a pair of downward heads 74x, 74y, and 74z (see FIG. 45) are attached to the recessed portion so as to face the upward scale 882, respectively. Yes. Since the position measuring operation of the substrate holder 1122 is the same as that of the tenth embodiment, the description thereof is omitted.
- the head base 886 (see FIG. 41, etc.) is fixed to the Y stator 638, whereas in the eleventh embodiment, as shown in FIG. A head base 886 is fixed to the air guide 1124. A pair of head bases 886 are arranged in the vicinity of both ends of the air guide 1124 in the longitudinal direction. Since the position measuring operation of the X coarse movement stage 628 using the downward scale 888 fixed to the optical surface plate 18a (see FIG. 44) is the same as that of the tenth embodiment, the description thereof is omitted.
- the position information of the substrate holder 1122 is obtained based on the optical surface plate 18a via the air guide 1124. Since the air guide 1124 is fixed to the stage main body 632, the air guide 1124 is hardly affected by disturbance and can improve the exposure accuracy. Further, as compared with the tenth embodiment and the like, the positions of the upward scale 882 and the downward scale 888 approach the center position of the projection optical system 16, so the error is reduced and the exposure accuracy can be improved.
- a liquid crystal exposure apparatus according to the twelfth embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the twelfth embodiment is substantially the same as that of the seventh embodiment except that the configuration of the substrate stage apparatus 1220 and its measurement system is different.
- the elements having the same configurations or functions as those of the seventh embodiment are denoted by the same reference numerals as those of the seventh embodiment, and description thereof is omitted as appropriate.
- the substrate P is held in the vicinity of both ends in the X-axis direction by a pair of substrate holders 722 that move with a long stroke in the Y-axis direction.
- the substrate P has a point that the vicinity of both ends in the Y-axis direction is held by a pair of substrate holders 1222 that move in the X-axis direction with a long stroke.
- the substrate stage apparatus 1220 during the scan exposure operation, only the pair of substrate holders 1222 are driven in the X-axis direction with respect to the projection optical system 16 (see FIG. 48), thereby performing the scan exposure operation on the substrate P. .
- the substrate stage apparatus 1220 has a structure in which the substrate stage apparatus 720 (see FIG. 31 and the like) according to the seventh embodiment is rotated 90 ° around the Z axis with respect to the projection optical system 16. .
- the configuration of the substrate stage apparatus 1220 will be described.
- three surface plates 1224 extending in the Y-axis direction are fixed on the undercarriage portion 18c at predetermined intervals in the X-axis direction.
- a weight canceling device 42 is placed via a linear guide device 1226.
- a Z actuator 1228 is placed on the + X side and ⁇ X side surface plates 1224 via a linear guide device 1226.
- the point that the weight cancellation device 42 supports the substrate table 626 (see FIG. 48 respectively) from below via the stage main body 632 is the same as in the sixth embodiment (see FIG. 23 and the like).
- the Y coarse movement stage 1230 is mounted on a pair of base frames 1232 extending in the Y-axis direction, and is driven with a long stroke in the Y-axis direction by a Y linear actuator (not shown). .
- the weight canceling device 42 and the two Z actuators 1228 are connected to the Y coarse moving stage 1230 by a connecting member 46 (see FIG. 48). Moves integrally in the Y-axis direction.
- the stage main body 632 is also connected to the Y coarse movement stage 1230 by the connecting member 46 (see FIG. 48), and moves integrally with the Y coarse movement stage 1230 in the Y-axis direction. Near both ends of the Y coarse movement stage 1230 in the Y-axis direction, a stator 1234 extending in the X-axis direction is attached.
- air guides 1236 are arranged corresponding to the pair of substrate holders 1222 (see FIG. 53), respectively.
- the air guide 1236 is fixed to the stage main body 632 via a support member 1238 (see FIG. 48).
- the Z position on the upper surface of the air guide 1236 is set to a position lower than the Z position on the upper surface of the substrate table 626.
- a plurality (four in this embodiment) of air guides 1240 for supporting the substrate P from below are arranged on the + X side and the ⁇ X side of the substrate table 626.
- the Z position of the upper surface of the air guide 1240 is set to be substantially the same as the Z position of the upper surface of the substrate table 626.
- the air guide 1240 supports the substrate P from below in cooperation with the substrate table 626 when the substrate P moves relative to the substrate table 626 in the X-axis direction, such as during a scan exposure operation (see FIG. 54).
- air guides 1242 are arranged corresponding to the pair of substrate holders 1222, respectively.
- the air guide 1242 is a member similar to the air guide 1236 described above, and the Z position of the upper surface thereof is set to be substantially the same as the air guide 1236.
- the air guide 1242 supports the substrate holder 1222 from below when the substrate holder 1222 moves relative to the substrate table 626 in the X-axis direction in cooperation with the air guide 1236 (see FIG. 54).
- the air guides 1240 and 1242 are placed on the Z actuator 1228 (see FIG. 50) described above via a common base member. Since the Z actuator 1228 and the weight canceling device 42 (see FIG. 50) integrally move in the Y-axis direction, the air guides 1240, 1242, 1236, and the substrate table 626 move integrally in the Y-axis direction. .
- the pair of substrate holders 1222 are arranged with the central portion (center of gravity position) of the substrate P interposed therebetween, and the lower surface of the substrate P is sucked and held using the suction pad 1244.
- a movable element 1246 constituting a 2DOF motor is attached to each substrate holder 1222 in cooperation with the above-described stator 1234 (see FIG. 51).
- the main controller (not shown) drives each substrate holder 1222 with a long stroke in the X-axis direction with respect to the substrate table 626 (see FIG. 52) via the corresponding 2DOF motor.
- a thrust in the Y-axis direction is applied to the substrate holder 1222 so that the positional relationship in the Y-axis direction with the moving stage 1230 (see FIG. 51) falls within a predetermined range.
- the pair of substrate holders 1222 are driven on the air guides 1236 and 1242 by the 2DOF motor in the X-axis direction during a scanning exposure operation or the like.
- the scanning exposure operation for the substrate P is performed.
- a system including a pair of substrate holders 1222 and a substrate table 626 (substrate table 626, Y coarse movement stage 1230, stator 1234, air guides 1236, 1240, 1242, etc.) is integrated with Y. Move in the axial direction.
- the board measurement system 1280 is conceptually similar to the board measurement system 70 (see FIG. 4) according to the first embodiment. That is, a pair of downward heads 74x and 74y (see FIG. 49 respectively) are attached to members (each of the pair of substrate holders 1222 in this embodiment) holding the substrate P via a head base 1282, and the downward heads 74x and 74y are , Opposite a corresponding upward scale 1284 attached to the upper surface of the stator 1234.
- the main controller (not shown) appropriately uses the outputs of the two X linear encoder systems and the two Y linear encoder systems, and uses the X axis direction, the Y axis direction, and the ⁇ z direction with respect to the Y coarse movement stage 1230 of each substrate holder 1222.
- Direction position information (first information) is obtained independently.
- a head base 1286 is fixed to the central portion of the stator 1234 in the longitudinal direction.
- a pair of upward heads 80x and 80y are attached to the head base 1286, and the upward heads 80x and 80y are respectively provided with a corresponding downward scale 1288 fixed to the lower surface of the optical surface plate 18a (see FIG. 48) and an X linear encoder system.
- the Y linear encoder system is configured.
- the positional relationship (third information) between the upward scale 1284 and the upward heads 80x and 80y is known.
- a main controller (not shown) obtains positional information (second information) of the Y coarse movement stage 1230 in the horizontal plane by appropriately using outputs of the four X linear encoder systems and the four Y linear encoder systems.
- a liquid crystal exposure apparatus according to a thirteenth embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the thirteenth embodiment is substantially the same as that of the twelfth embodiment except that the configuration of the substrate stage apparatus 1320 and its measurement system is different.
- the elements having the same configuration or function as those of the twelfth embodiment will be denoted by the same reference numerals as those of the twelfth embodiment, and description thereof will be omitted as appropriate.
- the substrate P has a pair of portions near both ends in the Y-axis direction as shown in FIG. It is held by the substrate holder 1322.
- the pair of substrate holders 1322 is driven by the 2DOF motor with a long stroke in the X-axis direction, and is slightly driven in the Y-axis and ⁇ z directions as in the twelfth embodiment.
- the substrate holder 1222 includes an air guide 1236 and a pair of air guides 1242 (each of which is separated from each other) according to the position in the X-axis direction.
- the substrate holder 1322 according to the thirteenth embodiment is set to a length that can cover the entire movable region in the X-axis direction. It is supported from below by a single air guide 1324. As shown in FIG. 55, the air guide 1324 is connected to the stage main body 632 and can move in the Y-axis direction integrally with the substrate table 626.
- the substrate measurement system 1380 has a structure in which the substrate measurement system 1180 (see FIG. 44 and the like) according to the eleventh embodiment is rotated by 90 ° around the Z axis. That is, in the thirteenth embodiment, an upward scale 1382 is fixed to the upper surface of the air guide 1324 as shown in FIG. In the eleventh embodiment, the upward scale 882 (see FIG. 46 and the like) has a wider measurement range of position information regarding the Y-axis direction than the X-axis direction (so that the Y-axis direction becomes the longitudinal direction). In contrast to the arrangement, the upward scale 1382 of this embodiment is arranged so that the measurement range of the position information in the X-axis direction is wider than the Y-axis direction (the X-axis direction is the longitudinal direction). Yes.
- the substrate holder 1322 is formed with a recessed portion opened downward like the substrate holder 1122 (see FIG. 44, etc.) according to the eleventh embodiment, and the substrate holder 1322 faces downward in the recessed portion.
- a pair of heads 74x, 74y, and 74z are attached so as to face the upward scale 1382 (see FIG. 58).
- a head base 1384 is fixed in the vicinity of both ends of the air guide 1324 in the longitudinal direction, and each head base 1384 has two upward heads 80x, 80y, and 80z, respectively. It is attached so as to face the corresponding downward scale 1386 fixed to the lower surface of the surface plate 18a (see FIG. 55).
- the position information of the substrate P (a pair of substrate holders 1322) is also displayed on the substrate measurement system 1380 according to the thirteenth embodiment. It is obtained with reference to the optical surface plate 18a via the coarse movement stage 1230.
- a liquid crystal exposure apparatus according to the fourteenth embodiment will be described with reference to FIG.
- the configuration of the liquid crystal exposure apparatus according to the fourteenth embodiment is substantially the same as that of the thirteenth embodiment except that the configuration of the substrate stage apparatus 1420 and its measurement system is different.
- the elements having the same configurations or functions as those of the thirteenth embodiment will be described with the same reference numerals as those of the thirteenth embodiment, and description thereof will be omitted as appropriate.
- the substrate P is held by the substrate holder 1322 in the vicinity of both ends in the Y-axis direction, whereas as shown in FIG. In the embodiment, the substrate P is different in that only the vicinity of the end on one side (in the present embodiment, + Y side) in the Y-axis direction is sucked and held by the substrate holder 1422.
- the substrate holder 1422 is the same as that of the twelfth embodiment except that it is driven by a 3DOF motor with respect to the stator 1424. Therefore, the description thereof is omitted here.
- the connecting member 1426 that connects the stator 1424 and the air guide 1324 has rigidity in the Y-axis direction, and the stator 1424 can press or pull (push and pull) the substrate table 626. Yes. Since the configuration and operation of the substrate measurement system 1480 according to the fourteenth embodiment are the same as those of the thirteenth embodiment, description thereof is omitted here.
- ⁇ 15th Embodiment a liquid crystal exposure apparatus according to the fifteenth embodiment will be described with reference to FIGS. Since the configuration of the liquid crystal exposure apparatus according to the fifteenth embodiment is substantially the same as that of the first or sixth embodiment except that the configuration of the substrate stage apparatus 1520 is different, only the differences will be described below. Elements having the same configuration or function as those of the first or sixth embodiment are denoted by the same reference numerals as those of the first or sixth embodiment, and description thereof is omitted as appropriate.
- the substrate stage device 1520 includes a first moving body (here, the substrate holder 1522) and a second moving body (here, the Y coarse movement stage 24).
- the substrate holder 1522 is formed in a rectangular frame shape (frame shape) in plan view, like the substrate holder 622 of the sixth embodiment (see FIG. 26, etc.).
- the substrate holder 1522 is disposed in the opening.
- the substrate holder 1522 has four suction pads 1524 and sucks and holds the vicinity of the center of each of the four sides of the substrate P from below.
- the exposure area including the central portion is non-contact supported by the substrate table 626 from below as shown in FIG.
- the substrate table 626 performs flattening of the substrate P in a non-contact state as in the sixth embodiment (see FIG. 26 and the like).
- a stage main body 632 (see FIG. 23) is fixed to the lower surface of the substrate table 626 as in the sixth embodiment.
- the stage body 632 (not shown) is connected to the X coarse movement stage 26 via a plurality of connecting members 1526 in a state in which relative movement in the Z tilt direction is allowed.
- the substrate table 626 moves with a long stroke integrally with the X coarse movement stage 26 in the X-axis and Y-axis directions. Since the configurations and operations of the X coarse movement stage 26, the Y coarse movement stage 24, and the like are substantially the same as those in the first embodiment (see FIG. 4 and the like), description thereof will be omitted.
- the table member 1528 protrudes from the stage main body 632 (not shown in FIG. 63; see FIG. 23) in a total of four directions including the ⁇ Y direction and the ⁇ X direction.
- the substrate holder 1522 is placed on the four table members 1528 in a non-contact state via air bearings (not shown).
- the substrate holder 1522 includes a plurality of linear elements configured by a plurality of movers 1530 (see FIG. 62) attached to the substrate holder 1522 and a plurality of stators 1532 (see FIG. 63) attached to the stage main body 632.
- the motor is driven with respect to the substrate table 626 with a slight stroke in the X-axis, Y-axis, and ⁇ z directions.
- the substrate holder 622 of the sixth embodiment is separated from the substrate table 626 and can be relatively moved with a long stroke in the Y-axis direction (see FIG. 27).
- the illustrated main controller uses the plurality of linear motors so that the positions of the substrate holder 1522 and the substrate table 626 are within a predetermined range in the X-axis and Y-axis directions. Then, a thrust is applied to the substrate holder 1522. Accordingly, the entire exposure area of the substrate P is always supported from below by the substrate table 626.
- the substrate measurement system 1580 is conceptually substantially the same as the substrate measurement system 70 according to the first embodiment, and position information in the horizontal plane of the substrate holder 1522 is optically determined via the Y coarse movement stage 24. It is determined based on the board 18a (see FIG. 1 etc.).
- a pair of head bases 88 is fixed to the substrate holder 1522, and two downward X heads 74 x and two downward Y heads 74 y are attached to each head base 88. (See FIG. 62).
- a pair of scale bases 84 are attached to the Y coarse movement stage 24 via arm members 86, and the upper surfaces of the scale bases 84 extend in the X-axis direction ( The upward scale 72 is fixed (the measurable range in the X-axis direction is longer than the measurable range in the Y-axis direction).
- Position information of the substrate holder 1522 with respect to the Y coarse movement stage 24 is obtained by an encoder system including the heads 74x and 74y and the scale 72 corresponding thereto.
- a head base 96 is fixed to each of the pair of scale bases 84 attached to the Y coarse movement stage 24.
- Each head base 96 has two upward X heads 80x and two upward Y heads 80y. It is attached (see FIG. 63).
- the lower surface of the optical surface plate 18a extends in the Y-axis direction corresponding to each head base 96 (the measurable range in the Y-axis direction is longer than the measurable range in the X-axis direction).
- a scale 78 (see FIG. 60) is fixed. Position information of the Y coarse movement stage 24 with respect to the optical surface plate 18a is obtained by an encoder system constituted by the heads 80x and 80y and the scale 78 corresponding thereto.
- a liquid crystal exposure apparatus according to the sixteenth embodiment will be described with reference to FIG.
- the configuration of the liquid crystal exposure apparatus according to the sixteenth embodiment is substantially the same as that of the sixth or fifteenth embodiment except that the configuration of the substrate stage device 1620 and its measurement system is different. Only the points will be described, and elements having the same configuration or function as those of the sixth or fifteenth embodiment will be denoted by the same reference numerals as those of the sixth or fifteenth embodiment, and description thereof will be omitted as appropriate.
- the configurations (including the drive system) of the substrate holder 1522 and the substrate table 626 included in the substrate stage device 1620 according to the sixteenth embodiment are substantially the same as those of the fifteenth embodiment (see FIG. 60 and the like).
- the substrate measurement system 1580 (see FIG. 60, etc.) of the fifteenth embodiment determines the position information of the substrate holder 1522 with reference to the optical surface plate 18a via the Y coarse movement stage 24 (that is, the first embodiment).
- the substrate measurement system 1680 according to the sixteenth embodiment uses the position information of the substrate holder 1522 as in the sixth embodiment. The difference is that the optical table 18a is obtained as a reference via the measurement table 624.
- a pair of head bases 688 are fixed to the substrate holder 1522 according to the sixteenth embodiment, as in the sixth embodiment (see FIG. 24), and each head base 688 has an upward X
- Two heads 80x and two upward Y heads 80y are attached.
- a measurement table 624 is attached to the lower surface of the optical surface plate 18a so as to correspond to the pair of head bases 688 so that the position in the Y-axis direction with respect to the substrate holder 1522 is within a predetermined range.
- the position information of the substrate holder 1522 is obtained by a linear encoder system including the heads 80x and 80y and a downward scale 686 fixed to the lower surface of the corresponding measurement table 624 and extending in the X-axis direction.
- the position information of the measurement table 624 includes an upward X head 80x and an upward Y head 80y attached to the measurement table 624, and a downward scale 684 that is fixed to the lower surface of the optical surface plate 18a and extends in the Y-axis direction. Required by a linear encoder system.
- a liquid crystal exposure apparatus according to the seventeenth embodiment will be described with reference to FIG.
- the configuration of the liquid crystal exposure apparatus according to the seventeenth embodiment is substantially the same as that of the fifteenth or sixteenth embodiment except that the configuration of the substrate stage apparatus 1720 and its measurement system is different. Only the points will be described, and elements having the same configuration or function as those of the fifteenth or sixteenth embodiment are denoted by the same reference numerals as those of the fifteenth or sixteenth embodiment, and description thereof will be omitted as appropriate.
- the configurations (including the drive system) of the substrate holder 1522, the substrate table 626, and the like included in the substrate stage apparatus 1720 according to the seventeenth embodiment are substantially the same as those in the fifteenth embodiment (see FIG. 60 and the like).
- the substrate measurement system 1580 (see FIG. 60, etc.) of the fifteenth embodiment determines the position information of the substrate holder 1522 with reference to the optical surface plate 18a via the Y coarse movement stage 24 (that is, the first embodiment).
- the substrate measurement system 1780 according to the seventeenth embodiment includes the positional information of the substrate holder 1522, the Y coarse movement stage 24, and the measurement table 1782. The point which is calculated
- the scale base 1784 is fixed to the Y coarse movement stage 24 via the arm member 86 as in the fifteenth embodiment (see FIG. 63 and the like). Yes.
- one scale base 1784 is disposed on each of the + Y side and the ⁇ Y side of the substrate holder 1522 as in the fifteenth embodiment.
- a measurement table 1782 is also shown, but one is arranged on each of the + Y side and the ⁇ Y side of the projection optical system 16 corresponding to the scale base 1784.
- an upward scale 1786 used for position measurement of the substrate holder 1522 and an upward scale 1788 used for position measurement of the measurement table 1782 are attached at predetermined intervals in the Y-axis direction.
- the upward scales 1786 and 1788 have a two-dimensional diffraction grating on the upper surface so that the measurement range of the position information in the X-axis direction is wider than the Y-axis direction (so that the X-axis direction is the longitudinal direction). Yes.
- the positional relationship between the upward scale 1786 and the upward scale 1788 is assumed to be known. Note that the pitch of the two-dimensional diffraction gratings formed on the upward scales 1786 and 1788 may be the same or different.
- the scale base 1784 may have one wide upward scale that serves both for the position measurement of the substrate holder 1522 and for the position measurement of the measurement table 1782 instead of the two upward scales 1786 and 1788. .
- two downward heads 74x and 74y are attached to the substrate holder 1522 via the head base 88, respectively.
- the position information of the substrate holder 1522 in the XY plane with respect to the Y coarse movement stage 24 is obtained by the encoder system constituted by the downward heads 74x and 74y and the corresponding upward scale 1786, in the fifteenth embodiment ( That is, since it is the same as that of the first embodiment, the description is omitted.
- the measurement table 1782 is driven with a predetermined stroke in the Y-axis direction by the Y linear actuator 682, similarly to the measurement table 624 of the sixteenth embodiment (see FIG. 64). As in the sixteenth embodiment, two upward heads 80x and 80y are attached to the measurement table 1782, respectively.
- the point that the position information of the measurement table 1782 in the XY plane with respect to the optical surface plate 18a is obtained by the encoder system constituted by the upward heads 80x and 80y and the corresponding downward scale 984 is that in the sixteenth embodiment (ie, Since this is the same as in the sixth embodiment, the description thereof is omitted.
- the position information of the Y coarse movement stage 24 in the XY plane is obtained with reference to the optical surface plate 18a via the measurement table 1782.
- the measurement system for obtaining the position information of the Y coarse movement stage 24 is conceptually the same as the measurement system (encoder system) for obtaining the position information of the substrate holder 1522 with respect to the Y coarse movement stage 24.
- two downward X heads 74 x and two downward Y heads 74 y are attached to the measurement table 1782, and the measurement table is measured by an encoder system including the downward heads 74 x and 74 and the upward scale 1788.
- Position information in the XY plane of the Y coarse movement stage 24 with respect to 1782 is obtained.
- the main controller (not shown) is based on the position information of the measurement table 1782 with respect to the optical surface plate 18a, the position information of the Y coarse movement stage 24 with respect to the measurement table 1782, and the position information of the substrate holder 1522 with respect to the Y coarse movement stage 24.
- the position information of the substrate holder 1522 is obtained with reference to the optical surface plate 18a.
- the configuration of the liquid crystal exposure apparatus according to the eighteenth embodiment is substantially the same as that of the first embodiment except that the configuration of the substrate stage apparatus 1820 and its measurement system is different.
- the elements having the same configurations or functions as those of the first embodiment will be described with the same reference numerals as those of the first embodiment, and description thereof will be omitted as appropriate.
- the upward scale 72 for obtaining the position information of the fine movement stage 22 and the upward heads 80x and 80y for obtaining the position information of the upward scale 72 are respectively Y coarse movements.
- the upward scale 72 and the upward heads 80x and 80y are attached to the Y step guide 44 provided in the self-weight support device 28. It is different in that it is fixed.
- the upward scale 72 is fixed to the upper surface of the scale base 84.
- one scale base 84 is disposed on each of the fine movement stage 22 on the + Y side and the ⁇ Y side.
- the scale base 84 is fixed to the Y step guide 44 via an arm member 1886 formed in an L shape when viewed from the X-axis direction. Therefore, the scale base 84 (and the upward scale 72) is movable with a predetermined long stroke in the Y-axis direction integrally with the Y step guide 44 and the Y coarse movement stage 24.
- the Y step guide 44 is disposed between the pair of X beams 36 included in the Y coarse movement stage 24 (the Z position of the X beam 36 and the Z position of the Y step guide 44 partially overlap each other). For this reason, the X beam 36 is formed with a through hole 45 for allowing the arm member 1886 to pass therethrough (to prevent contact between the arm member 86 and the X beam 36).
- the coarse movement stage measurement system 82 actually measures the position information of the Y step guide 44, which is different from the first embodiment.
- the substrate measurement system 1870 of the present embodiment obtains the positional information of the fine movement stage 22 (substrate P) with reference to the optical surface plate 18 a via the Y step guide 44.
- the upward scale 72 is fixed to the Y step guide 44 that supports the fine movement stage 22 (included in the same system as the fine movement stage 22), compared to the first embodiment. Further, the influence of the operation of the coarse movement stages 24 and 26 can be suppressed, and the position measurement accuracy of the fine movement stage 22 can be further improved.
- FIGS. 1-10 a liquid crystal exposure apparatus according to a nineteenth embodiment will be described with reference to FIGS.
- the configuration of the liquid crystal exposure apparatus according to the nineteenth embodiment is substantially the same as that of the eighteenth embodiment except that the configuration of the apparatus main body 1918 and the substrate measurement system 1970 (see FIG. 70) is different. Only the differences will be described, and elements having the same configuration or function as those in the eighteenth embodiment are denoted by the same reference numerals as those in the eighteenth embodiment, and description thereof will be omitted as appropriate.
- the apparatus main body 18 is configured such that the optical surface plate 18a, the middle gantry 18b, and the lower gantry 18c are integrally assembled with the floor via the vibration isolator 19.
- the apparatus main body 1918 has a portion that supports the projection optical system 16 (hereinafter referred to as a “first portion”) as shown in FIG. ) And a portion that supports the Y step guide 44 (hereinafter referred to as a “second portion”) are installed on the floor F in a state of being physically separated from each other.
- the first portion of the apparatus main body 1918 that supports the projection optical system 16 includes an optical surface plate 18a, a pair of middle frame portions 18b, and a pair of first lower frame portions 18d. It is formed in a gate shape (inverted U shape).
- the first part is installed on the floor F via a plurality of vibration isolation devices 19.
- the second part of the apparatus main body 1918 that supports the Y step guide 44 includes a second lower mount part 18e.
- the second lower frame 18e is made of a flat plate-like member and is inserted between the pair of first lower frames 18d.
- the second undercarriage 18e is installed on the floor F via a plurality of vibration isolation devices 19 different from the plurality of vibration isolation devices 19 that support the first part.
- a gap is formed between the pair of first lower frame 18d and second lower frame 18e, and the first part and the second part are vibrationally separated (insulated). .
- the point that the Y step guide 44 is placed on the second undercarriage 18e via the mechanical linear guide device 52 is the same as in the eighteenth embodiment.
- the pair of base frames 30 includes a second lower base 18e, and is installed on the floor F in a state of being vibrationally separated from the apparatus main body 218.
- the Y coarse movement stage 24 and the X coarse movement stage 26 are placed on the pair of base frames 30, and the fine movement stage 22 is placed on the Y step guide 44 via the self-weight support device 28. The point is the same as in the eighteenth embodiment.
- the configuration and operation of the substrate measurement system 1970 according to the nineteenth embodiment will be described. Since the configuration and operation of the substrate stage apparatus 1920 excluding the measurement system are the same as those in the eighteenth embodiment, the description thereof is omitted.
- FIG. 70 shows a conceptual diagram of a substrate measurement system 1970 according to the nineteenth embodiment.
- the configuration of the fine movement stage measurement system 76 (see FIG. 6) for obtaining positional information in the XY plane of the fine movement stage 22 (actually the substrate holder 32) is the 18th (first). Since this is the same as the embodiment, the description is omitted.
- the configuration of the Z tilt position measurement system 1998 for obtaining position information in a direction intersecting the horizontal plane of the substrate holder 32 is the above-described eighteenth (first) implementation. Different from form.
- the Z tilt position measurement system 1998 obtains position information of the substrate holder 32 in the Z tilt direction via the Y coarse movement stage 24 as in the fine movement stage measurement system 76. (See FIG. 69).
- each of the head bases 1988 fixed to the side surfaces of the substrate holder 32 on the + Y side and the ⁇ Y side includes two downward X heads 74x and two downward Y heads 74y.
- Two downward Z heads 74z are mounted apart from each other in the X-axis direction (see FIG. 70).
- a known laser displacement meter that irradiates a measurement beam to the upward scale 72 is used as the downward Z head 74z.
- the main controller (not shown) obtains displacement amount information in the Z tilt direction of the fine movement stage 22 with respect to the Y coarse movement stage 24 based on the outputs of the four downward Z heads 74z (see FIG. 9) in total.
- each of the pair of scale bases 84 fixed to the side surfaces of the Y step guide 44 on the + Y side and the ⁇ Y side is similar to the head base 96 of the first embodiment (see FIG. 4).
- Two 1996 are fixed.
- one upward Z head 80 z is attached to the head base 1996 together with two upward X heads 84 x and two upward Y heads 80 y.
- the upward Z head 80z uses the same laser displacement meter as the downward Z head 74z, but the types of the Z heads 74z and 80z may be different.
- the main control device (not shown) has displacement information in the Z tilt direction with respect to the optical surface plate 18a (see FIG. 69) of the Y coarse movement stage 24 based on the outputs of the four upward Z heads 80z (see FIG. 70) in total. Ask for.
- the position information of the substrate P in the Z tilt direction can be obtained with reference to the optical surface plate 18a (that is, the projection optical system 16). Together with the position information, the position information of the substrate P in the Z tilt direction can be obtained with high accuracy. That is, as disclosed in International Publication No. 2015/147319 as an example, when the position information of the substrate P in the Z tilt direction is obtained based on the weight cancellation device 42, the weight cancellation device 42 is placed on the Y step guide 44. Therefore, there is a possibility that an error occurs in the position measurement of the substrate P due to vibration or the like when the Y step guide 44 moves.
- the position information of the Y step guide 44 is always measured with reference to the optical surface plate 18a. Even if the position information of the substrate P is measured via the position 44, the position shift of the Y step guide 44 is not reflected in the measurement result of the substrate P. Therefore, the position information of the substrate P can be measured with high accuracy.
- the second part (second lower mount part 18e) of the apparatus main body 1980 that supports the Y step guide 44 is vibrationally separated from the first part that supports the projection optical system 16,
- the influence on the projection optical system 16 such as vibration and deformation caused by the movement can be suppressed. Exposure accuracy can be improved.
- each of the pair of head bases 88 includes four heads for measuring the position of the fine movement stage 22 (substrate holder 32) (each pair of the downward X head 74x and the downward Y head 74y).
- the number of heads for measuring the substrate holder position may be less than eight.
- FIG. 71 shows a pair of head bases 88 of the substrate holder 32 and the substrate measurement system 2070 according to the twentieth embodiment together with the projection optical system 16 in a plan view.
- the Y coarse movement stage 24 and the like are not shown for easy understanding.
- the head base 88 is indicated by a dotted line.
- scale bases 84 are arranged in the + Y side and ⁇ Y side regions sandwiching the substrate placement region of the substrate holder 32, respectively. Yes.
- scales 2072 On the upper surface of each scale base 84, for example, five encoder scales 2072 (hereinafter simply referred to as scales 2072) are arranged at predetermined intervals in the X-axis direction so that the lattice regions are arranged apart from each other in the X-axis direction. ing.
- Each of the plurality of scales 2072 has a lattice region (lattice portion) where a reflective two-dimensional lattice is formed.
- a lattice region lattice portion
- a grid may be formed over the entire area of the scale 2072, it is difficult to accurately form a grid at the end of the scale 2072. Therefore, in this embodiment, the periphery of the grid area in the scale 2072 is blank.
- a lattice is formed so as to be a part. For this reason, the interval between the lattice regions is wider than the interval between the pair of adjacent scales 2072 in the X-axis direction, and the position measurement is not possible while the measurement beam is irradiated outside the lattice region. (Although also referred to as a non-measurement section, hereinafter, it is collectively referred to as a non-measurement period).
- the intervals between the adjacent scales 2072 (lattice regions) are the same, but the arrangement positions thereof are the same.
- the five scales 2072 on the + Y side generally shift to the predetermined distance D (a distance slightly larger than the interval between the adjacent scales 2072 (lattice regions)) + X side.
- Each scale 2072 is made of a plate-shaped (strip-shaped) member having a rectangular shape in plan view and extending in the X-axis direction, for example, formed of quartz glass.
- a reflective two-dimensional diffraction grating (two-dimensional grating) RG having a predetermined pitch (for example, 1 ⁇ m) with the X-axis direction and the Y-axis direction as periodic directions is formed.
- the above-described lattice region is also simply referred to as a two-dimensional grating RG.
- the interval (pitch) between the lattice lines of the two-dimensional grating RG is shown much wider than actual.
- the five scales 2072 disposed in the + Y side region of the substrate holder 32 are referred to as a first lattice group, and the five scales 2072 disposed in the ⁇ Y side region of the substrate holder 32 are referred to as the second lattice. It shall be called a group.
- the X head 74x and the Y head 74y are in a predetermined interval in the X axis direction (adjacent scale 2072) in a state of facing the scale 2072, respectively. A distance greater than the distance between) is fixed.
- the Y head 74y and the X head 74x are separated from each other by a predetermined distance in the X-axis direction on the lower surface (the surface on the ⁇ Z side) of the other head base 88 positioned on the ⁇ Y side in a state of facing the scale 2072. Is fixed.
- the X head 74x and Y head 74y that face the first lattice group and the X head 74x and Y head 74y that face the second lattice group are measured at intervals wider than the interval between the lattice regions of the adjacent scale 2072.
- the beam is irradiated on the scale 2072.
- the X head 74x and Y head 74y of one head base 88 are referred to as head 74a and head 74b, respectively, and the Y head 74y and X head 74x of the other head base 88 are respectively heads.
- 74c and head 74d are also called.
- the head 74a and the head 74c are arranged at the same X position (on the same straight line parallel to the Y-axis direction), and the head 74b and the head 74d are different from the X position of the head 74a and the head 74c. It is arranged at a position (on the same straight line parallel to the Y-axis direction).
- a pair of X linear encoders are configured by the two-dimensional gratings RG facing the heads 74a and 74d
- a pair of Y linear encoders are configured by the two-dimensional gratings RG facing the heads 74b and 74c.
- the remaining part of the head base 88 is included, and the configuration of the other parts is the drive control (position) of the substrate holder 32 using the substrate measurement system 2070 of the main controller 100. Except for control, the liquid crystal exposure apparatus 10 according to the first embodiment is the same as that described above.
- the heads of the pair of head bases 88 within a range in which the substrate holder 32 moves in the X-axis direction between the second position where the pair of head bases 88 oppose each other in the vicinity of the ⁇ X end portion of the scale base 84 shown in FIG. 74a to 74d, that is, the position of the substrate holder 32 can be measured by a pair of X linear encoders and a pair of Y linear encoders.
- 72A shows a state in which only the head 74b does not face any scale 2072
- FIG. 72B shows a state in which only the head 74c does not face any scale 2072. Yes.
- the pair of head bases 88 and the scale 2072 The positional relationship is such that the first state to the fourth state shown in FIGS. 73A to 73D and the four heads 74a to 74d are all two-dimensional gratings RG of any scale 2072. (I.e., all four heads 74a to 74d are irradiated with the measurement beam on the two-dimensional grating RG) and transition to a fifth state.
- the head faces the two-dimensional grating RG of the scale 2072 or that the measurement beam is irradiated on the two-dimensional grating RG of the scale 2072, it is expressed that the head just faces the scale.
- 73A shows a state in which the head 74a faces the scale 2072b, the heads 74c and 74d face the scale 2072e, and only the head 74b does not face any scale.
- the substrate holder 32 is moved a predetermined distance in the ⁇ X direction from the state of FIG. 73 (A), the heads 74a and 74b are opposed to the scale 2072b, and the head 74d is directed to the scale 2072e. It shows a state in which only the head 74c is opposed to any scale.
- the heads 74a and 74b face the scale 2072b, and the heads 74c and 74d go through the fifth state facing the scale 2072e. To do.
- 73 (C) shows a state in which the substrate holder 32 has moved a predetermined distance in the ⁇ X direction from the state of FIG. 73 (B) and only the head 74a is no longer opposed to any scale.
- the heads 74a and 74b face the scale 2072b
- the head 74c faces the scale 2072d
- the head 74d faces the scale 2072e. Go through the fifth state.
- 73 (D) shows a state where the substrate holder 32 has moved a predetermined distance in the ⁇ X direction from the state shown in FIG. 73 (C), and only the head 74d is no longer opposed to any scale.
- the head 74a faces the scale 2072a
- the head 74b faces the scale 2072b
- the head 74c faces the scale 2072d.
- the head 74d goes through the fifth state in which it faces the scale 2072e.
- the head 74a faces the scale 2072a
- the head 74b faces the scale 2072b
- the heads 74c and 74d move to the scale 2072d.
- the head 74a faces the scale 2072a
- the heads 74c and 74d face the scale 2072d
- only the head 74b enters the first state that does not face any scale. .
- the two X heads 74x that is, the heads 74a and 74d
- the two Y heads 74y that is, the heads 74b and 74c
- At least three out of the total of four always face one of the scales 2072 (two-dimensional grating RG).
- the width of the lattice region of the scale 2072 is set so that the measurement beams do not deviate from the scale 2072 (two-dimensional grating RG) in the Y-axis direction for all four heads.
- main controller 100 can always manage position information of substrate holder 32 in the X-axis direction, Y-axis direction, and ⁇ z direction using three of heads 74a to 74d. Hereinafter, this point will be further described.
- C X (p i ⁇ X) cos ⁇ z + (q i ⁇ Y) sin ⁇ z (1a)
- C Y ⁇ (p i ⁇ X) sin ⁇ z + (q i ⁇ Y) cos ⁇ z (1b)
- X, Y, and ⁇ z indicate the positions of the substrate holder 32 in the X-axis direction, the Y-axis direction, and the ⁇ z direction, respectively.
- P i and q i are the X position (X coordinate value) and Y position (Y coordinate value) of each of the heads 74a to 74d.
- the substrate holder 32 and the pair of head bases 88 are in a positional relationship as shown in FIG. 72A.
- the positions of the substrate holder 32 in the three-degree-of-freedom direction in the XY plane are (X, Y, ⁇ z)
- the measured values of the three heads 74a, 74c, and 74d can theoretically be expressed by the following equations (2a) to (2c) (also referred to as affine transformation relationships).
- C 1 (p 1 ⁇ X) cos ⁇ z + (q 1 ⁇ Y) sin ⁇ z (2a)
- C 3 ⁇ (p 3 ⁇ X) sin ⁇ z + (q 3 ⁇ Y) cos ⁇ z (2b)
- C 4 (p 4 ⁇ X) cos ⁇ z + (q 4 ⁇ Y) sin ⁇ z (2c)
- C 4 p 4
- the reference state is a state where, for example, the center of the substrate holder 32 (substantially coincides with the center of the substrate P) coincides with the center of the projection area by the projection optical system 16 and the ⁇ z rotation is zero. Therefore, in the reference state, measurement of the Y position of the substrate holder 32 by the head 74b has also become possible, the measurement value C 2 by the head 74
- the measurement values of the three heads 74a, 74c, and 74d are initially set as p 1 , q 3 , and p 4 , respectively, the displacement (X, Y, ⁇ z) of the substrate holder 32 is thereafter performed.
- the three heads 74a, 74c, and 74d present the theoretical values given by the equations (2a) to (2c).
- the three heads 74a, 74b, and 74d have the theoretical values given by the equations (2a), (2c), and (2d) with respect to the displacement (X, Y, ⁇ z) of the substrate holder 32 thereafter. Will be presented.
- the dependent variables C 1 , C 3 , C 4 in the simultaneous equations (2a) to (2c) or the dependent variables C 1 , C 4 , C in the simultaneous equations (2a), (2c), (2d) If 2 is given, the variables X, Y, and ⁇ z can be obtained.
- the equation can be easily solved by applying the approximation sin ⁇ z ⁇ z or applying higher-order approximation. Accordingly, the positions (X, Y, and C) of the substrate holder 32 from the measured values C 1 , C 3 , and C 4 (or C 1 , C 2 , and C 4 ) of the heads 74a, 74c, and 74d (or the heads 74a, 74b, and 74d). ⁇ z) can be calculated.
- connection process at the time of switching the head of the substrate measurement system 2070 that is, the initial setting of the measurement value, which is performed by the liquid crystal exposure apparatus according to the twentieth embodiment, is performed.
- the operation of the control device 100 will be mainly described.
- each of the four heads 74a to 74d faces one of the scales 2072, and the position of the substrate holder 32 can be measured.
- State the above-mentioned fifth state.
- the substrate holder 32 moves in the ⁇ X direction from the state where the position of the substrate holder 32 is measured by the heads 74a, 74b and 74d.
- FIG. 74C shows a state in which the three heads used for measuring the position information of the substrate holder 32 are being switched from the heads 74a, 74b, and 74d to the heads 74b, 74c, and 74d.
- FIG. 74B As shown in FIG. 74B, at the moment when the switching process (connection) of the head (encoder) used for position control (measurement of position information) in the XY plane of the substrate holder 32 is performed, as shown in FIG. 74b, 74c, and 74d are opposed to the scales 2072b, 2072b, 2072d, and 2072e, respectively.
- FIG. 74 (A) to FIG. 74 (C) it seems that the head 74a is going to be switched to the head 74c in FIG. 74 (B), but the measurement direction is different between the head 74a and the head 74c. As is apparent, it is meaningless to give the measured value (count value) of the head 74a as it is as the initial value of the measured value of the head 74c at the timing of connection.
- the main controller 100 uses the three heads 74b, 74c, and 74d to measure the position information of the substrate holder 32 that uses the three heads 74a, 74b, and 74d (and the position control). Switching to 32 position information measurement (and position control). In other words, this method is different from the concept of normal encoder connection, not from one head to another, but from a combination of three heads (encoders) to another three heads (encoders). It is.
- main controller 100 solves simultaneous equations (2a), (2c), and (2d) based on measured values C 1 , C 4 , and C 2 of heads 74a, 74d, and 74b, and obtains an XY plane of the substrate holder.
- the position information (X, Y, ⁇ z) is calculated.
- main controller 100 substitutes X and ⁇ z calculated above for the affine transformation formula of the following formula (3), and the initial value of the measured value of head 74c (the value to be measured by head 74c). Ask for.
- the above explanation is an example of the switching of the heads 74a to 74d.
- the above-described switching is possible even when switching from any three heads to another three heads or switching from any head to another head.
- the head is switched in the same procedure as described.
- the grating portion when configured with a plurality of scales (two-dimensional grating RG), the scales irradiated with the measurement beams are formed on each scale more strictly.
- the grating two-dimensional grating RG
- a measurement error of the encoder system occurs.
- At least two scales 2072 irradiated with measurement beams of at least three heads used for position information measurement and position control of the substrate holder 32 are used. It can be considered that there is a coordinate system for each combination of at least two scales. For example, a relative position variation of at least two scales causes a shift (grid error) between these coordinate systems. Measurement error of the encoder system occurs. In addition, since the relative positional relationship between at least two scales changes over a long period, the grid error, that is, the measurement error also varies.
- the position information of the substrate holder 32 can be measured with all four heads, but only three heads are required for measuring the position coordinates (X, Y, ⁇ z) of the substrate holder.
- main controller 100 uses the measurement value of the redundant head to correct correction information (grid correction information or grid correction information) of the measurement error of the encoder system due to a shift between the coordinate systems (grid error). Acquisition and driving (position control) of the substrate holder 32 are performed so that the measurement error of the encoder system due to the grid error is compensated.
- the position coordinates (X, Y, ⁇ z) of the substrate holder are measured by two sets of three heads. Specifically, the difference between the positions (X, Y, ⁇ z) obtained by solving the simultaneous equations using the above-described affine transformation formula, that is, the offsets ⁇ x, ⁇ y, ⁇ z, obtained by the measurement, is calculated.
- This offset is determined as a coordinate system offset consisting of a combination of at least two scales at which the four heads 74a to 74d face each other.
- This offset is used in measurement of position information of the substrate holder 32 and control of the position of the substrate holder 32 by three of the four heads facing the at least two scales.
- a combination of at least two scales facing the three heads used for measuring the position information of the substrate holder 32 and controlling the position before switching Since the combination of at least two scales facing the three heads used for measuring the position information and controlling the position of the substrate holder 32 after the switching is naturally different, it is different before and after the head switching.
- the offset is used as grid or lattice correction information in measurement of position information of the substrate holder 32 and control of the position.
- the following fifth state (referred to as the state of case 1) that appears immediately before the state of FIG. 74 (A) in the process of moving the substrate holder 32 in the ⁇ X direction is as follows.
- the heads 74a and 74b are opposed to the scale 2072b, and the heads 74c and 74d are opposed to the scale 2072e.
- the offset can be obtained by using two sets of heads 74a to 74d, which are combinations of any three heads.
- the head 74c cannot be measured, and in order to restore the measurement of the head 74c, in the fifth state shown in FIG.
- the three heads 74a, 74b, The position coordinates (X, Y, ⁇ z) of the substrate holder calculated from the measured value of 74d are used. Further, in the process in which the substrate holder 32 is moving in the ⁇ X direction, the head 74b that has been in a measurement impossible state is returned prior to the case 1 state. For returning the head 74b, the position coordinates (X, Y, ⁇ z) of the substrate holder calculated from the measured values of the three heads 74a, 74c, 74d are used.
- a set of three heads excluding a set of three heads 74a, 74b, and 74d and a set of three heads 74a, 74c, and 74d, that is, a set of three heads 74a, 74b, and 74c. Further, it is assumed that lattice correction information of a coordinate system composed of a combination of scales 2072b and 2072e is acquired using the three heads 74b, 74c, and 74d.
- the head used for position control of the substrate holder 32 is switched from the head 74a to the head 74c, and at that time, the three heads 74a, 74b, The position coordinate of the substrate holder 32 is calculated by the above-described affine transformation formula using the measurement value of 74d.
- the main control device 100 calculates the position coordinates, sets the three heads 74a, 74b, 74d used for calculating the position coordinates of the substrate holder 32 for switching the head, and the next head.
- a set of three heads 74a, 74b and 74c and a set of three heads 74a and 74b are excluded from the set of three heads 74b, 74c and 74d used for setting the measurement value of the head after switching.
- 74d, and the three scales facing the heads 74b, 74c, 74d used for position measurement and position control of the substrate holder 32 after the head switching, as in the combination of the scales 2072b, 2072e.
- the lattice correction information (offset) of the coordinate system consisting of a combination of 2072b, 2072d and 2072e Give to.
- the main controller 100 moves the substrate holder 32 in the ⁇ X direction or the + X direction from the first position shown in FIG. 72A to the second position shown in FIG. 72B.
- the offsets ⁇ X, ⁇ Y, ⁇ z are set in the above-described procedure with respect to a plurality of coordinate systems corresponding to all combinations of at least two scales 2072 that are sequentially switched and used to control the position of the substrate holder 32. It is obtained and stored in the storage device as lattice correction information.
- main controller 100 causes heads 74a and 74b to face scale 2072b.
- the measured values of the three heads 74a, 74b, and 74d including the head 74b that has returned after performing the above-described head switching and joining process In the position control, while the substrate holder 32 is moved until the head 74c cannot be measured, the lattice correction information of the coordinate system composed of the scale 2072b and the scale 2072e is obtained at each of the plurality of positions by the above-described procedure.
- Offset may be acquired. That is, a plurality of pieces of lattice correction information may be acquired instead of one piece of lattice correction information for each combination of at least two scales 2072 facing three heads used for position measurement and position control of the substrate holder 32. Further, the above method is used while four heads including three heads used for position measurement and position control of the substrate holder 32 and one redundant head are opposed to at least two scales 2072 of the same combination.
- the lattice correction information may be acquired substantially continuously. In this case, lattice correction information can be acquired over the entire period (section) in which the four heads face each other on at least two scales 2072 having the same combination.
- the lattice correction information acquired for each combination of at least two scales 2072 facing the three heads used for position measurement and position control of the substrate holder 32 need not be the same.
- the lattice correction acquired by a combination of scales The number of information may be different.
- lattice correction is performed using a combination of at least two scales 2072 facing three heads in an exposure operation and a combination of at least two scales 2072 facing three heads other than the exposure operation (alignment operation, substrate replacement operation, etc.).
- the number of information may be different.
- the position measurement and position control of the substrate holder 32 are performed before or after loading the substrate onto the substrate holder 32 and before the substrate processing operation (including exposure operation and alignment operation).
- Lattice correction information is acquired and stored in a storage device for all combinations of at least two scales 2072 facing three heads to be used, and the lattice correction information is updated periodically or as needed.
- the lattice correction information may be updated at an arbitrary timing including during the substrate processing operation as long as the substrate processing operation can be performed.
- the offsets ⁇ X, ⁇ Y, ⁇ z may be updated each time the head is switched. However, it is not always necessary to do this, and the offsets ⁇ X, ⁇ Y, and ⁇ z may be updated at predetermined intervals, such as every time the head is switched a predetermined number of times, or every time a predetermined number of substrates are exposed. good.
- the offset may be acquired and updated during a period when the head is not switched. Further, the offset update described above may be performed before the exposure operation, or may be performed during the exposure operation if necessary.
- a measurement error occurs due to a relative movement between the scale or the head or a direction other than the measurement direction (non-measurement direction).
- a measurement error due to the scale hereinafter referred to as a scale-induced error
- a measurement error due to deformation, displacement, flatness, or formation error of the lattice region formed on the scale there is a measurement error due to deformation, displacement, flatness, or formation error of the lattice region formed on the scale.
- head-induced errors there are measurement errors caused by displacement of the head (including displacement in the measurement direction as well as rotation and tilting) or optical characteristics.
- Abbe-induced errors also occur.
- correction information is used to compensate for the measurement error of the encoder system as described above.
- the measurement error of the encoder if the measurement error of the encoder is obtained, the measurement error can be used as correction information as it is.
- an encoder system composed of two heads 74a, 74b, 74c, 74d provided on the lower end side of the pair of head bases 88 and a scale 2072 facing each other (hereinafter referred to as a holder encoder system). The measurement error will be described.
- the scale lattice surface is uneven, the scale lattice surface is displaced in the Z-axis direction (moves up and down) or tilts with respect to the head even when the substrate holder 32 moves parallel to the XY plane. It will be. As a result, as described above, the relative motion in the non-measurement direction is caused between the head and the scale as a result, and such relative motion causes measurement errors.
- the main controller 100 maintains the substrate holder 32 in a state in which the pitching amount, rolling amount and yawing amount are all kept at zero.
- a necessary number of reflecting members having a reflecting surface with a high flatness and a predetermined area are attached to the substrate holder 32 during maintenance or the like.
- a reflective surface having a predetermined area with high flatness may be formed in advance at a predetermined position on each end surface of the substrate holder 32.
- the main controller 100 measures the Z position of the surface of the scale 2072 using a sensor having a high measurement resolution, and the measured value of the sensor and the measured value of the interferometer system. Are stored at a predetermined sampling interval and stored in a storage device. Here, it is desirable that the substrate holder 32 is moved at a low speed such that measurement errors caused by air fluctuations in the interferometer system can be ignored. Then, main controller 100 obtains the relationship between the measured value of the sensor and the measured value of the interferometer based on the acquired measured values.
- x is the X position of the substrate holder 32 measured by the interferometer.
- the substrate holder 32 is moved and positioned in the Y axis direction at a predetermined pitch.
- the measurement value of the interferometer and the measurement value of the sensor may be taken simultaneously for each positioning position while moving the substrate holder 32 in the X-axis direction.
- i is a number for identifying a plurality of scales 2072.
- any encoder head of the holder encoder system has no sensitivity to the tilting operation of the substrate holder 32 by the method disclosed in the above-mentioned US patent specification, that is, with respect to the XY plane of the substrate holder 32.
- the unevenness information on the scale lattice plane is not limited to a function, and may be stored in a map format.
- the above-mentioned “singular point where the measurement error of the encoder becomes zero regardless of the inclination angle of the substrate holder 32 with respect to the XY plane” is the intersection (black dot) of many straight lines in the graph of FIG. is there. That is, obtaining the Z position (Z coordinate value) of this singular point for the entire surface of the scale lattice surface is nothing other than obtaining the irregularities of the scale lattice surface.
- the scale of the encoder lacks mechanical long-term stability such that the diffraction grating deforms due to thermal expansion or the like with the passage of time of use, or the pitch of the diffraction grating changes partially or entirely. For this reason, the error included in the measured value increases with the passage of time of use, and it is necessary to correct this.
- main controller 100 measures the X position of substrate holder 32 with the above-described interferometer system, for example, while maintaining substrate holder 32 with all of its pitching amount, rolling amount and yawing amount being zero.
- the holder 32 is moved in the + X direction or the ⁇ X direction.
- the movement of the substrate holder 32 is also desirably performed at a low speed such that measurement errors due to air fluctuations in the interferometer system can be ignored.
- the corrected measurement value and the interferometer measurement value are captured at a predetermined sampling interval, and the measured value of the X linear encoder (based on each captured measurement value ( The relationship between the output of the X encoder—the measured value corresponding to the function f i (x)) and the measured value of the interferometer is obtained. That is, in this way, the main controller 100 causes the diffraction grating (X diffraction) to have a periodic direction in the X-axis direction of the two-dimensional grating RG of the scale 2072 that is sequentially opposed to the head 74a as the substrate holder 32 moves. (Lattice) lattice pitch (interval between adjacent lattice lines) and correction information of the lattice pitch.
- the lattice pitch correction information for example, the relationship between the horizontal axis is the measured value of the interferometer and the vertical axis is the measured value of the encoder (measured value corrected for errors due to irregularities on the scale surface). It is possible to obtain a correction map or the like that represents a curve.
- the measurement beam from the head 74a does not hit the first scale 2072, and then the adjacent The initial value of the measured value of the X linear encoder constituted by the head 74a and the scale 2072 to be acquired at the time when the output of the detection signal from the head is resumed, and the measured value of the interferometer at that time And the measurement for the adjacent scale 2072 is started. In this way, measurement is performed on the columns of the scale 2072 constituting the first lattice group.
- the lattice pitch and the correction information of the lattice pitch are obtained in the same manner as described above (however, using the head 74d instead of the head 74a).
- the measurement value of the head 74b and the measurement value of the interferometer are captured at a predetermined sampling interval, and the measurement value of the head 74b is calculated based on each of the acquired measurement values. You may obtain
- an initial value of a Y linear encoder (hereinafter, appropriately abbreviated as Y encoder) composed of a head 74b (a scale 2072 facing the head 74b) is set to a predetermined value, for example, zero.
- lattice line bending of a diffraction grating having a periodic direction in the Y-axis direction of the two-dimensional grating RG of the scale 2072 facing the head 74b and correction information thereof can be obtained.
- the correction information of the lattice line bending for example, a correction map in which the horizontal axis is the measurement value of the interferometer and the vertical axis is the measurement value of the head 74b, a curve indicating the relationship between the two can be obtained.
- the head After the measurement beam from 4b stops hitting the first scale 2072, the initial value of the measurement value of the head 74b is set to a predetermined value, for example, zero when the output of the detection signal from the head starts to hit an adjacent scale. Then restart the measurement.
- the correction information of the lattice line bending is acquired in the same manner as described above (however, using the head 74c instead of the head 74b).
- the correction information may be acquired based on lattice information (pitch, deformation, etc.) obtained by imaging the two-dimensional grating RG for each scale.
- the substrate holder 32 moves in a direction different from the measurement direction, for example, the X-axis direction (or Y-axis direction), and the relative movement (non-measurement) other than the direction to be measured between the head 74x (or the head 74y) and the scale 2072. In most cases, this causes a measurement error in the X encoder (or Y encoder).
- correction information for correcting the measurement error of each encoder caused by the relative movement of the head and the scale in the non-measurement direction described above is set, for example, when the exposure apparatus is started up or during maintenance. Like that.
- main controller 100 drives substrate holder 32 via substrate drive system 60 while monitoring measurement values of a measurement system different from the encoder system from which correction information is acquired, for example, the interferometer system described above.
- the head 74a is opposed to an arbitrary region (referred to as a calibration region for convenience) of an arbitrary scale 2072 of the first lattice group.
- the measurement beam is irradiated from the head 74a to the calibration area of the scale 2072, and the reflected light is received from the head 74a.
- the measured value corresponding to the signal is stored in the internal memory.
- 32 is driven in the Z-axis direction within a predetermined range, for example, in the range of ⁇ 100 ⁇ m to +100 ⁇ m, and the detection light is irradiated from the head 74a to the calibration area of the scale 2072 during the driving, at a predetermined sampling interval. Measurement values corresponding to the photoelectric conversion signals from the head 74a receiving the reflected light are sequentially taken and stored in the internal memory.
- the Z / tilt position measuring system 98 can also measure the positions of the substrate holder 32 in the Z-axis direction, ⁇ x direction, and ⁇ y direction.
- the measured value of the head 74a within the Z drive range is captured at intervals of ⁇ (rad), for example, 40 ⁇ rad, for a range where the pitching amount ⁇ y is ⁇ 200 ⁇ rad ⁇ x ⁇ +200 ⁇ rad.
- main controller 100 determines the measurement error as a function of Z position z and pitching amount ⁇ y, for example, by calculating an undetermined coefficient by the least square method, and uses that function as holder position-induced error correction information. Store in the storage device.
- main controller 100 drives substrate holder 32 via substrate drive system 60 while monitoring the measurement value of the interferometer system, and moves head 74d (another X head 74x) to the second grating group.
- head 74d another X head 74x
- main controller 100 drives substrate holder 32 via substrate drive system 60 while monitoring the measurement value of the interferometer system, and moves head 74d (another X head 74x) to the second grating group.
- head 74d another X head 74x
- main controller 100 performs the same processing as described above for head 74d, and stores correction information of the X encoder constituted by head 74d and the X diffraction grating of scale 2072 in the storage device.
- the head 74b and a Y diffraction grating of an arbitrary scale 2072 of the first grating group, and a head 74c and a Y diffraction grating of an arbitrary scale 2072 of the second grating group are configured.
- the Y encoder correction information is obtained and stored in the storage device.
- main controller 100 performs the same procedure as when the pitching amount is changed as described above, while maintaining both the pitching amount and rolling amount of substrate holder 32 at zero, and yawing amount ⁇ z of substrate holder 32 is ⁇ 200 ⁇ rad ⁇ z ⁇ +200 ⁇ rad is sequentially changed, and at each position, the substrate holder 32 is driven in the Z axis direction within a predetermined range, for example, within a range of ⁇ 100 ⁇ m to +100 ⁇ m, and at a predetermined sampling interval during the driving, The head measurement values are sequentially captured and stored in the internal memory.
- Such measurement is performed for all the heads 74a to 74d, and each data in the internal memory is plotted on a two-dimensional coordinate having the horizontal axis as the Z position and the vertical axis as the encoder count value in the same procedure as described above. Then, plot points when the yawing amount is the same are connected in sequence, and the horizontal axis is shifted so that the line with the yawing amount of zero (the horizontal line in the center) passes through the origin. obtain. Then, main controller 100 uses the yawing amount ⁇ z, Z position z, and measurement error of each point on the obtained graph similar to FIG. 77 as table data, and stores the table data as correction information in the storage device. Alternatively, main controller 100 determines the measurement error as a function of Z position z and yawing amount ⁇ z, for example, by calculating an undetermined coefficient by the least square method, and stores the function as correction information in the storage device. To do.
- the measurement error of each encoder at the Z position z of the substrate holder 32 when the pitching amount of the substrate holder 32 is not zero and the yawing amount is not zero is the above-described error at the Z position z. It can be considered that this is a simple sum (linear sum) of the measurement error corresponding to the pitching amount and the measurement error corresponding to the yawing amount.
- the pitching amount ⁇ y and yawing amount of the substrate holder representing the measurement error ⁇ x as indicated by the following equation (4) for the X heads (heads 74a and 74d) of the respective X encoders. It is assumed that functions of ⁇ z and Z position z are obtained and stored in the storage device.
- functions of the rolling amount ⁇ x, the yawing amount ⁇ z, and the Z position z of the substrate holder 32 representing the measurement error ⁇ y as represented by the following equation (5). Is obtained and stored in the storage device.
- a intersects each straight line connecting plot points when the pitching amount is the same in the graph of FIG. 77 when the pitching amount is changed in order to obtain correction information of the X encoder.
- Z is the Z coordinate of the point
- b is a straight line connecting plot points when the yawing amount is the same in the graph similar to FIG. 77 when the yawing amount is changed to obtain correction information of the X encoder.
- c is connected to plot points when the rolling amount is the same in the graph similar to FIG. 77 when the rolling amount is changed to obtain correction information of the Y encoder.
- the Z coordinate of the point where each straight line intersects, and d is the plot point when the yawing amount is the same in the graph similar to FIG. 77 when the yawing amount is changed to obtain correction information of the Y encoder. This is the Z coordinate of the point where the connected straight lines intersect.
- ⁇ x and ⁇ y indicate that the position of the substrate holder 32 in the non-measurement direction of the X encoder or Y encoder (for example, the ⁇ y direction, the ⁇ x direction, the ⁇ z direction, and the Z axis direction) is the measurement value of the X encoder or Y encoder. Since this indicates the degree of influence, in this specification, it is referred to as a holder position-induced error, and this holder-position-derived error can be used as correction information as it is, so this correction information is referred to as holder position-induced error correction information. Shall.
- the head-induced error typically includes an encoder measurement error caused by head tilt. That is, when the substrate P is arranged in parallel to the horizontal plane, the optical axis of the head is inclined with respect to the normal (vertical axis) of the surface of the substrate P. The head is parallel to the vertical axis (optical axis). The substrate P is inclined with respect to the horizontal plane. Therefore, a measurement error occurs in the encoder measurement value.
- a photoelectric conversion signal obtained by irradiating two measurement beams to one point on the substrate from two directions symmetric with respect to the optical axis and interfering the two return light beams returning to each other is obtained.
- the measured value is obtained.
- the intensity I of the interference light is proportional to 1 + cos ⁇ ( ⁇ means the phase difference between the two return light beams).
- the measurement error is set to be zero when the two measurement beams return through the symmetric optical path. For this reason, when the optical axis of the head is tilted, the difference between the optical path lengths of the two light beams does not become zero (therefore, the phase ⁇ of the light beams of the two return lights changes).
- the phase difference ⁇ also changes when the above-described optical path symmetry is broken.
- the characteristic information of the head unit that causes the measurement error of the encoder system includes not only the head tilt but also its optical characteristics.
- the head base 88 is inclined in the ⁇ x direction and the ⁇ y direction.
- the reference surface is a surface that serves as a reference for controlling the position of the substrate holder 32 in the Z-axis direction (a surface that serves as a reference for displacement of the substrate holder 32 in the Z-axis direction), or a substrate in the exposure operation of the substrate P.
- P corresponds to the image plane of the projection optical system 16.
- the main controller 100 performs calibration for obtaining the Abbe removal amount in the following procedure, for example, when the exposure apparatus is started up.
- the main controller 100 drives the substrate holder 32 to position one scale 2072 of the first lattice group below the head 74a and at the same time, 1 of the second lattice group.
- One scale 2072 is positioned below the head 74d.
- the scale 2072b is positioned below the head 74a and the scale 2072e is positioned below the head 74d.
- main controller 100 determines the measurement result of the interferometer system when the displacement (pitching amount) ⁇ y in the ⁇ y direction with respect to the XY plane of substrate holder 32 is not zero. Based on this, the substrate holder 32 is tilted about an axis parallel to the Y axis that passes through the exposure center so that the pitching amount ⁇ y becomes zero. At this time, since the interferometer system has completed all necessary corrections for each interferometer (each measurement axis), such pitching control of the substrate holder 32 is possible.
- the measurement values x b0 and x e0 of the two X encoders respectively constituted by the heads 74a and 74d and the scales 2072b and 2072e facing each other are acquired. .
- main controller 100 tilts substrate holder 32 about an axis parallel to the Y axis passing through the exposure center by an angle ⁇ based on the measurement result of the interferometer system. Then, the measurement values x b1 and x e1 of the measurement values of the two X encoders are acquired.
- main controller 100 determines the so-called Abbe removal amount h b of scales 2072b and 2072e based on the measured values x b0 and x e0 and x b1 and x e1 of the two encoders obtained above and angle ⁇ . to calculate the h e.
- ⁇ is a small angle
- Main controller 100 sets one scale 2072 of the first lattice group and one scale 2072 of the second lattice group substantially opposed to this in the Y-axis direction in the same procedure as described above, and the remaining scales. Also, the Abbe removal amount is acquired for each. Note that it is not always necessary to simultaneously measure the Abbe removal amount for one scale 2072 of the first lattice group and one scale 2072 of the second lattice group, and the Abbe removal amount is measured separately for each scale 2072. You may do it.
- h is an Abbe removal amount of the scale 2072 facing the X head constituting the X encoder.
- h is an Abbe removal amount of the scale 2072 facing the Y head constituting the Y encoder.
- Main controller 100 stores the Abbe removal amount h of each scale 2072 obtained as described above in the storage device. As a result, the main controller 100 controls the Abbe error included in the position information of the substrate holder 32 in the XY plane (moving plane) measured by the holder encoder system when the position of the actual substrate holder 32 is controlled during lot processing or the like.
- the measurement error of each X encoder according to the pitching amount of the substrate holder 32 caused by the Abbe removal amount h of the scale 2072 grating surface (the surface of the two-dimensional grating RG) with respect to the above-described reference surface, or the scale 2072 grating surface 2
- the measurement error of each Y encoder according to the rolling amount of the substrate holder 32 caused by the Abbe removal amount h of the dimensional grating RG surface) with respect to the aforementioned reference surface is corrected based on the equation (8) or the equation (9).
- the substrate holder 32 is driven (position control) with high accuracy in any direction in the XY plane. It becomes possible.
- the position information of the holder position information based on the optical surface plate (projection optical system)
- the position information of the holder can be obtained with higher accuracy, and the controllability of the position of the holder can be further improved.
- the main controller 100 causes the heads 74a to 74 of the holder encoder system to change in accordance with the change in the position of the substrate holder 32 in the X-axis direction.
- 74 d of the substrate measurement system generated due to at least one of the heads 74 a to 74 d, at least two scales facing each of the heads 74 a to 74 d, and at least one of the movements of the substrate holder 32, while switching 74 d.
- the substrate drive system 60 is controlled based on correction information for compensating for measurement errors (referred to as first correction information for convenience) and position information measured by the substrate measurement system.
- the position information measured by the substrate measurement system includes measurement information of the position (Z, ⁇ x, ⁇ y) of the fine movement stage 32 by the Z / tilt position measurement system 98, and the position of the substrate holder 32 by the holder encoder system ( X, Y, ⁇ z) measurement information is included.
- the first correction information includes various measurement errors of the above-described holder encoder system (scale-induced error, measurement error due to relative movement between the head and the scale in the non-measurement direction (holder position-induced error), head-induced error, and Abbe error) correction information is included.
- position information in a direction different from the X axis direction of the substrate holder 32 including tilt information, for example, rotation information in the ⁇ y direction) and characteristic information of the scale 2072 facing the X head.
- the flatness of the grating surface of the two-dimensional grating RG and / or the grating formation error and the correction information of the Abbe error due to the Abbe removal amount of the scale 2072 (the grating surface of the two-dimensional grating RG)
- the position coordinates (X, Y, ⁇ z) of the substrate holder 32 are calculated. Used to do.
- position information in a direction (non-measurement direction) different from the X-axis direction of the substrate holder 32 by the main controller 100 for example, the ⁇ y direction of the substrate holder 32 measured by the Z / tilt position measurement system 98.
- correction information that takes into account the unevenness (flatness) of the scale grating surface (the surface of the two-dimensional grating RG)) and the bending of the grating lines of the X diffraction grating of the two-dimensional grating RG (errors during formation and On the X-axis direction on the basis of the correction information on the change in time) and the correction information on the Abbe error caused by the Abbe removal amount of the scale 2072 (lattice surface of the two-dimensional grating RG).
- the measured values of the X encoders (heads 74a and 74d) that measure the position information of the substrate holder 32 to be corrected are corrected, and the corrected measured values C 1 and C 4 are the position coordinates (X, Y) of the substrate holder 32 described above. , ⁇ z).
- position information of the substrate holder 32 in a direction different from the Y-axis direction including tilt information, for example, rotation information in the ⁇ x direction
- characteristic information of the scale 2072 facing the Y head for example, the two-dimensional grating RG
- the measured values C 2 and C 3 of the Y encoder (heads 74b and 74c) that measure the Y position of 32 are used to calculate the position coordinates (X, Y, ⁇ z) of the substrate holder 32 described above.
- the main controller 100 measures position information in a direction (non-measurement direction) different from the Y-axis direction of the substrate holder 32, for example, the Z / tilt position measurement system 98, and the ⁇ x direction of the substrate holder 32.
- correction information that takes into account the unevenness (flatness) of the scale grating surface (the surface of the two-dimensional grating RG)) and the bending of the grating lines of the Y diffraction grating of the two-dimensional grating RG (errors during formation and On the Y-axis direction based on the correction information of the Abbe error due to the Abbe removal amount of the scale 2072 (lattice surface of the two-dimensional grating RG).
- the measurement values of the Y encoder (heads 74b and 74c) that measure the position information of the substrate holder 32 to be corrected are corrected, and the corrected measurement values C 2 and C 3 are the position coordinates (X, Y) of the substrate holder 32 described above. , ⁇ z).
- the substrate holder 32 is driven (position control) so as to compensate for all the caused errors and Abbe errors.
- C 3 obtained by the above-described affine transformation equation (3) is: Since the measurement values of the corrected encoders in which the measurement errors of the various encoders described above are corrected, the main control device 100 determines the above-described holder position-induced error correction information, scale lattice pitch correction information (and lattice deformation). correction information) by using a weight off Abbe (Abbe error correction information), inversely corrects the measurement values C 3, 'is calculated, the raw value C 3' raw value C 3 before correction encoder (head 74c) as an initial value of the measured value.
- Abbe error correction information Abbe error correction information
- the reverse correction means that the measured value C 3 ′ of the encoder that does not perform any correction is used for the above-described holder position-induced error correction information and scale-derived error correction information (for example, correction information on the grid pitch of the scale (and grid deformation). correction information), etc.), and Abbe remove weight (Abbe error correction information) under the measurement value of the encoder after the correction that has been corrected by using a the assumption that it is C 3, the measured value based on the measurement values C 3 This means processing for calculating C 3 ′.
- scale-derived error correction information for example, correction information on the grid pitch of the scale (and grid deformation). correction information), etc.
- Abbe remove weight Abbe error correction information
- the liquid crystal exposure apparatus exhibits the same operational effects as those of the first embodiment described above.
- the X head 74x (X linear encoder) and the Y head 74y (Y linear encoder) of the substrate measurement system 2070 are driven while the substrate holder 32 is being driven.
- Position information (including ⁇ z rotation) of the substrate holder 32 in the XY plane is measured by three heads (encoders) including at least one each.
- the head (encoder) used for measuring the position information of the substrate holder 32 in the XY plane is switched by the main controller 100 so that the position of the substrate holder 32 in the XY plane is maintained before and after switching.
- one of the three heads (encoders) used for position measurement and position control of the substrate holder 32 is switched to another head (encoder). For this reason, although the encoder used for controlling the position of the substrate holder 32 is switched, the position of the substrate holder 32 in the XY plane is maintained before and after the switching, and accurate connection becomes possible. Therefore, the substrate holder 32 (substrate P) is accurately moved along the XY plane along a predetermined path while performing head switching and connection (measurement value connection processing) among a plurality of heads (encoders). Is possible.
- the main controller 100 uses the three heads used for measuring the position information of the substrate holder 32 and measuring the position information.
- the substrate holder 32 is driven in the XY plane based on the position information ((X, Y) coordinate value) in the XY plane.
- main controller 100 drives substrate holder 32 in the XY plane while calculating position information of substrate holder 32 in the XY plane using the relationship of affine transformation.
- the substrate holder 32 (substrate P) is moved while switching the head (encoder) used for control during the movement of the substrate holder 32 using the encoder system having each of the plurality of Y heads 74y or the plurality of X heads 74x. It becomes possible to control with high accuracy.
- the liquid crystal exposure apparatus for each combination of scales facing the head used for position information measurement and position control of the substrate holder 32, which differs depending on the X position of the substrate holder 32, The aforementioned offsets ⁇ X, ⁇ Y, ⁇ z (lattice correction information) are acquired and updated as necessary. Therefore, the grid error (X, Y position error and rotation error) between coordinate systems for each combination of scales facing the heads used for position information measurement and position control of the substrate holder 32, which differs depending on the X position of the substrate holder 32.
- the substrate holder 32 can be driven (position control) so that the encoder measurement error or the position error of the substrate holder 32 due to the above can be compensated. Accordingly, also in this respect, the position of the substrate holder (substrate P) can be accurately controlled.
- the main controller 100 controls the heads 74a to 74d of the holder encoder system and the heads 74a to 74d.
- Correction information (first correction information described above) for compensating for measurement errors of the substrate measurement system caused by the movement of the substrate holder 32, at least two scales of three of 74d facing each other;
- the substrate drive system 60 is controlled based on the position information measured by the substrate measurement system. Therefore, it is possible to control the drive of the substrate holder 32 so as to compensate for the above-described various measurement errors of the respective X encoders and Y encoders constituting the holder encoder system. Also in this respect, the position of the substrate holder (substrate P) can be accurately controlled.
- correction information for correcting measurement errors of the substrate measurement system caused by the heads 74a to 74d of the holder encoder system (correction information for head-derived errors) is added to the first correction information. )
- All of the correction information for compensating for the measurement error (holder position-induced error) of the substrate measurement system caused by the movement of 32 is included.
- the present invention is not limited thereto, and the holder encoder system may use correction information that compensates for at least one of a head-induced error, a scale-induced error, and a holder position-induced error.
- the Abbe error (Abbe-derived error) is included in either or both of the scale-induced error and the holder position-induced error.
- correction information for scale-induced errors all of measurement error correction information, scale lattice pitch correction information, and lattice deformation correction information due to scale irregularities are used for position control of the substrate holder 32. However, at least one correction information of these scale-induced errors may be used.
- measurement errors due to head displacement (including tilt and rotation) and measurement errors due to optical characteristics of the head have been taken up as head-induced errors. At least one correction of these head-induced errors has been made. Only information may be used for position control of the substrate holder 32.
- each head (encoder) of the mask encoder system also faces each head in a direction different from the measurement direction of each encoder. Correction information of the measurement error of the head (encoder) due to relative movement with the scale may be obtained in the same manner as described above, and the measurement error of the head (encoder) may be corrected using the correction information.
- An interferometer system may be provided in the apparatus.
- the correction information is acquired using a measurement device (interferometer or the like) different from the encoder system.
- the correction information may be acquired.
- the correction for controlling the movement of the substrate holder using a head (corresponding to the other head) in which the measurement beam is switched from one of a pair of adjacent scales to the other scale is obtained.
- Information (initial value of another head described above) is obtained based on position information measured by at least three heads facing one scale 2072.
- This correction information is obtained by measuring another head. It may be acquired after the beam is switched to the other scale and before one of the three heads facing at least one scale 2072 is out of the two-dimensional grating RG. Further, when the position measurement or the position control of the substrate holder is performed by switching three heads facing at least one scale 2072 to three different heads including the other head, the correction information is acquired for the switching. Thereafter, it may be performed before at least one of the three heads facing the scale 2072 is removed from the two-dimensional grating RG. Note that acquisition and switching of correction information may be performed substantially simultaneously.
- the region without the two-dimensional grating RG of the first lattice group is the region without the two-dimensional grating RG of the second lattice group.
- the five scales of the first grating group and the second grating group are arranged so that the non-measurement period in which the measurement beam deviates from the two-dimensional grating RG does not overlap with the four heads. 2072 is disposed on the substrate holder 32.
- the heads 74a and 74b included in the head base 88 on the + Y side are arranged at a distance wider than the width of the region without the two-dimensional grating RG of the first lattice group in the X-axis direction, and the head base 88 on the ⁇ Y side.
- the heads 74c, 74d included in the are disposed at a distance wider than the width of the region without the two-dimensional grating RG of the second grating group in the X-axis direction.
- the combination of a grating portion including a plurality of two-dimensional gratings and a plurality of heads that can face the grating portion is not limited to this.
- the head 74a is arranged so that the non-measurement period in which the measurement beam is deviated (unmeasurable) from the two-dimensional grating RG does not overlap with the four heads 74a, 74b, 74c, 74d. 74b and heads 74c and 74d, positions, positions, lengths and lengths of the lattice portions of the first and second lattice groups, lattice intervals and positions thereof may be set.
- the first lattice group faces the at least one scale 2072 (two-dimensional grating RG) of the first lattice group.
- two heads facing at least one scale 2072 (two-dimensional grating RG) of the second grating group may be shifted by a distance wider than the width of the non-grating area in the X-axis direction.
- the distance between the head disposed on the + X side of the two heads facing the first lattice group and the head disposed on the ⁇ X side of the two heads facing the second lattice group is set to a non-interval.
- the interval may be wider than the width of the lattice region, or two heads facing the first lattice group and two heads facing the second lattice group are alternately arranged in the X-axis direction and adjacent pairs.
- the head interval may be set wider than the width of the non-lattice region.
- the case where the first lattice group is disposed in the + Y side region of the substrate holder 32 and the second lattice group is disposed in the ⁇ Y side region of the substrate holder 32 has been described.
- a single scale member in which a two-dimensional lattice extending in the X-axis direction may be used instead of one of the first lattice group and the second lattice group, for example, the first lattice group.
- one head may always face the single scale member.
- three heads are provided so as to face the second grating group, and the distance between the three heads in the X-axis direction (the distance between the irradiation positions of the measurement beams) is set as a two-dimensional grating on the adjacent scale 2072.
- the distance between the three heads in the X-axis direction is set as a two-dimensional grating on the adjacent scale 2072.
- a configuration in which at least two heads can always face the single scale member regardless of the position of the substrate holder 32 in the X-axis direction is adopted, and at least one two-dimensional grating of the second grating group is also used.
- a configuration may be adopted in which at least two heads can face the RG. In this case, each of the at least two heads moves away from one of the plurality of scales 2072 (two-dimensional grating RG) during movement of the substrate holder 32 in the X-axis direction, and one scale 2072. Transfer to another scale 2072 (two-dimensional grating RG) adjacent to (two-dimensional grating RG).
- the non-measurement periods do not overlap with each other, that is, always with at least one head.
- a measurement beam is irradiated on the scale 2072.
- at least three heads always face at least one scale 2072 and can measure position information in three degrees of freedom.
- the number of scales and the interval between adjacent scales may be different between the first lattice group and the second lattice group.
- at least two heads facing the first grating group and at least two heads facing the second grating group may have different head (measurement beam) intervals, positions, and the like.
- a plurality of scales 2072 each having a single two-dimensional grating RG are used.
- a scale 2072 formed apart in the X-axis direction may be included in at least one of the first lattice group or the second lattice group.
- the first lattice group including the five scales 2072 of the same configuration and the first lattice group
- the present invention is not limited to this, and the first lattice group and the second lattice group are not shifted in the X-axis direction (almost completely mutually).
- a row of scales 2072 is arranged opposite the head base 88), and the position measurement heads (heads 74x, 74y) of the substrate holder 32 are different in the X-axis direction between one head base 88 and the other head base 88. May be allowed. Also in this case, the position (X, Y, ⁇ z) of the substrate holder 32 can always be measured and controlled by the three heads.
- the present invention is not limited to this, and five or more heads may be used. That is, at least one redundant head may be added to at least one of the two heads facing the first lattice group and the second lattice group. This configuration will be described in the following twenty-first embodiment.
- ⁇ 21st embodiment a twenty-first embodiment will be described with reference to FIG.
- the configuration of the liquid crystal exposure apparatus according to the twenty-first embodiment is the same as the first and twentieth embodiments described above except for a part of the configuration of the substrate measurement system 2170. Therefore, only the differences will be described below. Elements having the same configurations and functions as those of the first and twentieth embodiments are denoted by the same reference numerals as those of the first and twentieth embodiments, and description thereof is omitted.
- a pair of head bases 88 of the substrate holder 32 and the substrate measurement system 2170 according to the twenty-first embodiment are shown in a plan view together with the projection optical system 16.
- the Y coarse movement stage 24 and the like are not shown for easy understanding.
- the head base 88 is shown by dotted lines, and the illustration of the X head 80x and the Y head 80y provided on the upper surface of the head base 88 is also omitted.
- scales 2072 are respectively disposed in the + Y side and ⁇ Y side regions across the substrate placement region of the substrate holder 32 in the X-axis direction. For example, five are arranged at predetermined intervals. In the five scales 2072 arranged on the + Y side of the substrate placement area and the five scales 2072 arranged on the ⁇ Y side area, the interval between the adjacent scales 2072 is the same, and the substrate placement area The five scales 2072 on the + Y side and the ⁇ Y side of each of the two are opposed to each other and arranged at the same X position. Accordingly, the position of the gap between the adjacent scales 2072 is located on a straight line having a predetermined line width in the substantially same Y-axis direction.
- a total of three heads, the Y head 74y, the X head 74x, and the Y head 74y, are in a state of facing the scale 2072, respectively. In order from the side, they are fixed at a predetermined interval (a distance larger than the interval between adjacent scales 2072) in the X-axis direction.
- the Y head 74y and the X head 74x are fixed to the lower surface (the surface on the ⁇ Z side) of the other head base 88 positioned on the ⁇ Y side with a predetermined distance therebetween in the X axis direction, facing the scale 2072. ing.
- the three heads included in one head base 88 are referred to as the head 74e, the head 74a, and the head 74b in this order from the ⁇ X side, and the Y head 74y and the X head 74x included in the other head base 88.
- the head 74c and a head 74d are also referred to as a head 74c and a head 74d, respectively.
- the head 74a and the head 74c are arranged at the same X position (on the same straight line in the Y-axis direction), and the head 74b and the head 74d are arranged at the same X position (on the same straight line in the Y-axis direction).
- a pair of X linear encoders are configured by the two-dimensional gratings RG facing the heads 74a and 74d, and three Y linear encoders are configured by the two-dimensional gratings RG facing the heads 74b, 74c, and 74e. Yes.
- the configuration of other parts is the same as that of the liquid crystal exposure apparatus according to the twentieth embodiment.
- the pair of head bases 88 are synchronized with the substrate holder 32 in the Y axis, although the arrangement of the scales 2072 on the + Y side and the ⁇ Y side is not shifted in the X axis direction.
- the head holder 88 is moved in the direction (or the Y position of the substrate holder 32 is maintained at a position where the pair of head bases 88 and the row of scales 2072 face each other), three of the heads 74a to 74e are Regardless of the X position of 32, it always faces the scale 2072 (two-dimensional grating RG).
- the liquid crystal exposure apparatus according to the twenty-first embodiment described above exhibits the same operational effects as the liquid crystal exposure apparatus according to the twentieth embodiment described above.
- the plurality of heads for measuring positional information of the substrate holder 32 are four heads necessary for switching the heads, for example, the heads 74e, 74b, 74c, and 74d, and the four heads. It can also be understood that one of the heads 74c and one head 74a whose non-measurement period partially overlaps is included.
- the twenty-first embodiment in measuring the positional information (X, Y, ⁇ z) of the substrate holder 32, five heads including four heads 74e, 74b, 74c, 74d and one head 74c. Among them, measurement information of at least three heads that is irradiated with at least one of a plurality of grating regions (two-dimensional grating RG) is used.
- the two heads are simultaneously removed from the scale 2072 (lattice region, for example, the two-dimensional grating RG) and simultaneously
- This is an example in the case of switching to an adjacent scale 2072 (lattice region, for example, a two-dimensional grating RG).
- at least three heads need to face the grating region (two-dimensional grating) of the grating part in order to continue the measurement.
- the at least three heads cannot be measured until one or more of the at least two heads that have been measured are switched to the adjacent lattice region. That is, even if there are at least two heads that overlap in the non-measurement period and there are at least three heads in addition to that, the measurement can be continued even if the lattice regions are arranged at intervals.
- an X head 74x (hereinafter referred to as a head 74e as appropriate) is provided adjacent to the ⁇ Y side of the Y head 74y (head 74c).
- a Y head 74y (hereinafter referred to as a head 74f as appropriate) is provided adjacent to the ⁇ Y side of the X head 74x (head 74d).
- the Y position of the substrate holder 32 is in a state where the pair of head bases 88 are moving in the Y-axis direction (or the position where the pair of head bases 88 and the row of scales 2072 face each other.
- the three heads 74a, 74c, 74e (referred to as the first group head) and the three heads 74b, 74d, 74f (second group).
- One of the heads of the first group and the second group of heads is always connected to the scale 2072 (two-dimensional grating RG). Opposite to.
- the arrangement of the + Y-side and ⁇ Y-side scales 2072 in the X-axis direction is not shifted in relation to the X-axis direction.
- the three heads included in at least one of the first group head and the second group head can measure the position (X, Y, ⁇ z) of the substrate holder 32 regardless of the X position of the substrate holder 32. ing.
- heads of the first group heads 74a, 74c, 74e
- those heads 74a, 74c. , 74e are restored (measurement is resumed).
- the position of the substrate holder 32 by the second group heads heads 74b, 74d, 74f) (X, Measurement and control of Y, ⁇ z) are continued. Therefore, as shown in FIG.
- main controller 100 has a pair of head bases 88 straddling two adjacent scales 2072 arranged on the + Y side and the ⁇ Y side, respectively,
- the second group of heads heads 74b, 74d, 74f
- the position (X, Y, ⁇ z) of the substrate holder is calculated on the basis of the measured value, and the calculated position (X, Y, ⁇ z) of the substrate holder is substituted into the above-described affine transformation formula
- the initial values of the heads of one group (heads 74a, 74c, 74e) are calculated and set simultaneously. Thereby, the heads of the first group can be easily returned, and the measurement and control of the position of the substrate holder 32 by these heads can be resumed.
- the liquid crystal exposure apparatus according to the twenty-second embodiment described above has the same effects as the liquid crystal exposure apparatus according to the twenty-first embodiment described above.
- This modification is a liquid crystal exposure apparatus according to the twenty-second embodiment, wherein the other head base 88 located on the + Y side has the same configuration as the one head base 88 (or a configuration that is symmetrical with respect to the vertical direction on the paper surface). Is used.
- the eight heads are grouped into the first group head and the second group head to which each of the four heads arranged in a straight line in the same Y-axis direction belongs.
- main controller 100 has a pair of head bases 88 straddling two adjacent scales 2072 arranged on the + Y side and the ⁇ Y side, respectively, and the first group head and the second group head. At the time when one of the two adjacent scales 2072 faces the other, the initial value of the measured value of each head of the first group is calculated. In this case, all the four heads of the first group The initial value cannot be calculated simultaneously.
- the reason is that if there are three heads to be returned to the measurement (the total number of X heads and Y heads), when the initial values of the measurement values of these three heads are set in the same procedure as described above, By solving the simultaneous equations using the initial values as the measured values C 1 , C 2 , C 3, etc., the position (X, Y, ⁇ ) of the substrate holder is uniquely determined, so there is no particular problem. . However, it is because the simultaneous equations using the relationship of affine transformation using the measurement values of the four heads that can uniquely determine the position (X, Y, ⁇ ) of the substrate holder cannot be considered.
- the first group to be returned is grouped into two groups to which three heads each including another head belong, and each group is initialized for the three heads by the same method as described above. Calculate and set the value at the same time. After the initial values are set, the measurement values of the three heads in any group may be used for position control of the substrate holder 32. The position measurement of the substrate holder 32 by the head of the group not used for position control may be executed in parallel with the position control of the substrate holder 32. It should be noted that the initial value of each head of the first group to be restored can be calculated individually by the above-described method.
- the encoder switching (encoder output linking) processing according to the twentieth to twenty-second embodiments described above is based on the coarse movement stage or the measurement table in the second to nineteenth embodiments.
- the present invention can also be applied to an encoder system to be performed.
- the switching of the encoders according to the twentieth to twenty-second embodiments described above is performed in the first to fifth, eighth to fifteenth, eighteenth, and nineteenth embodiments.
- the substrate measurement system (substrate measurement systems 70, 270, etc.) in each of the above embodiments is used to measure the position of a moving body that holds an object (substrate P in each of the above embodiments) regardless of the configuration of the substrate stage apparatus.
- the substrate according to the sixth embodiment is different from the substrate stage apparatus including the substrate holder of the type that holds and holds almost the entire surface of the substrate P, such as the substrate holder 32 according to the first to fifth embodiments.
- a measurement system such as the measurement system 670 that obtains the position information of the substrate holder with reference to the optical surface plate 18a via the measurement table 624.
- a measurement system having the same configuration as the measurement system according to each of the above embodiments may be applied to a measurement object other than the substrate P.
- the substrate A measurement system having the same configuration as the measurement system 70 or the like may be used.
- the measurement system according to each of the embodiments described above is suitable for a measurement system of a mask stage apparatus that is disclosed in International Publication No. 2010/131485, in which a mask is stepped with a long stroke in a direction orthogonal to the scan direction. Can be used.
- the arrangement of the encoder head and the scale may be reversed. That is, in the X linear encoder and the Y linear encoder for obtaining the position information of the substrate holder, a scale may be attached to the substrate holder, and an encoder head may be attached to the coarse movement stage or the measurement table. In that case, it is preferable that a plurality of scales attached to the coarse movement stage or the measurement table are arranged, for example, along the X-axis direction and can be switched to each other.
- a scale may be attached to the measurement table, and an encoder head may be attached to the optical surface plate 18a.
- an encoder head may be attached to the optical surface plate 18a.
- a plurality of encoder heads attached to the optical surface plate 18a are arranged, for example, along the Y-axis direction and can be switched to each other.
- one or more scales extending in the X-axis direction are fixed on the substrate stage apparatus side, and one or more scales extending in the Y-axis direction are fixed on the apparatus main body 18 side.
- the present invention is not limited to this, and one or more scales extending in the Y-axis direction may be fixed to the substrate stage apparatus side, and one or more scales extending in the X-axis direction may be fixed to the apparatus main body 18 side.
- the coarse movement stage or the measurement table is driven in the X-axis direction during the movement of the substrate holder in the exposure operation of the substrate P or the like.
- the number of scales is not particularly limited, and can be appropriately changed according to the size of the substrate P or the movement stroke of the substrate P, for example.
- a plurality of scales having different lengths may be used, and if each of the lattice parts includes a plurality of lattice regions arranged side by side in the X-axis direction or the Y-axis direction, the scales constituting the lattice part
- the number of is not particularly limited.
- the measurement table and its drive system are configured to be provided on the lower surface of the upper base 18a of the apparatus body 18, but may be provided on the lower base 18c and the middle base 18b.
- the present invention is not limited to this, and an X scale and a Y scale may be independently formed on the surface of each scale. In this case, the lengths of the X scale and the Y scale may be different from each other in the scale. Moreover, you may make it arrange
- the diffraction interference type encoder system is used has been described. However, the present invention is not limited to this, and other encoders such as a so-called pickup type and magnetic type can also be used, for example, US Pat. No. 6,639,686. A so-called scan encoder disclosed in the above can also be used.
- the heads are arranged in the first direction.
- the number of scales 2072 constituting the lattice portion is not particularly limited as long as the lattice portion includes a plurality of arranged lattice regions.
- the plurality of lattice regions need not be disposed on both one side and the other side in the Y-axis direction across the substrate P of the substrate holder 32, and may be disposed on only one side.
- the position (X, Y, ⁇ z) of the substrate holder 32 at least during the exposure operation of the substrate P the following conditions must be satisfied.
- At least one of the four heads has a measurement beam deviating from a plurality of grating regions (for example, the above-described two-dimensional grating RG), the remaining at least three heads have a measurement beam having a plurality of grating regions.
- At least one of the above-described at least four heads is separated from the plurality of grating regions by the movement of the substrate holder 32 in the X-axis direction (first direction). Change.
- at least four heads include at least two heads having different measurement beam positions (irradiation positions) in the X-axis direction (first direction) and at least two heads in the Y-axis direction (second direction).
- the two heads having different measurement beam positions (irradiation positions) with respect to the X-axis direction, the two heads having a plurality of grating regions in the X-axis direction.
- the measurement beam is irradiated at an interval wider than the interval between a pair of adjacent lattice regions.
- three or more rows of lattice regions (for example, a two-dimensional grating RG) arranged in the X-axis direction may be arranged in the Y-axis direction.
- ten lattice regions each having an area that is obtained by dividing each of the five scales 2072 into two equal parts in the Y-axis direction (
- two rows of lattice regions (for example, a two-dimensional grating RG) adjacent to each other in the Y-axis direction are provided, and the heads 74e and 74f can be opposed to the two-dimensional grating RG in one row, and the other A configuration may be adopted in which the heads 74c and 74d can face the two-dimensional grating RG in this row.
- the five scales 2072 on the + Y side also include two lattice regions adjacent to each other in the Y-axis direction (for example, a two-dimensional grating).
- RG two lattice regions adjacent to each other in the Y-axis direction
- a pair of heads can be opposed to the two-dimensional grating RG in one row, and the remaining pair of heads can be opposed to the two-dimensional grating RG in the other row. Also good.
- the measurement beam in the movement of the substrate holder 32 in the X-axis direction (first direction), the measurement beam is not observed in any two heads between at least four heads.
- the position or interval or position of at least one of the scale and the head does not overlap so that none of the two-dimensional gratings RG is irradiated (out of the lattice area), that is, the measurement with the head becomes impossible (non-measurement section). It is important to set the interval and the like.
- the initial value of another head that changes the measurement beam from one scale and switches to another scale is set.
- Correction information for controlling the movement of the substrate holder such as measurement value correction information, may be acquired using another head.
- the correction information for controlling the movement of the substrate holder using another head includes, of course, the initial value, but is not limited to this, and any information that allows the other head to resume measurement may be used. An offset value from a value to be measured after the measurement is resumed may be used.
- encoder heads whose measurement directions are the X-axis direction and the Z-axis direction are used instead of the X heads 74x that measure the position information of the substrate holder 32.
- an encoder head whose measurement directions are the Y-axis direction and the Z-axis direction may be used instead of each Y head 74y.
- sensor heads having the same configuration as the displacement measurement sensor head disclosed in US Pat. No. 7,561,280 can be used. In such a case, the main controller 100 performs a predetermined calculation using the measurement values of the three heads used for position control of the substrate holder 32 before switching at the time of the above-described head switching and joining processing.
- the main controller 100 will be specifically described by taking the twentieth embodiment as a representative example.
- the main controller 100 includes a four-dimensional head RG (grating region) from which the measurement beam is one of the four heads 74a, 74b, 74c, and 74d.
- the measurement error of the encoder system due to the height and inclination deviation between the plurality of scale plates 2072 may be corrected.
- main controller 100 uses the measurement value of the redundant head in the fifth state to calibrate the deviation between the coordinate systems due to the deviation between the height and the inclination between the plurality of scale plates 2072 (calibration). ) It is also good to do.
- the position (Z, ⁇ x, ⁇ y) of the substrate holder 32 is measured by two sets of three heads.
- the difference between the measurement values obtained by the measurement, that is, the offsets ⁇ Z, ⁇ x, ⁇ y are obtained, and the offsets are used to measure the position information of the substrate holder 32 before and after the head switching and to control the position. It can be used for calibration of deviations in the Z-axis direction, ⁇ x, and ⁇ y directions between coordinate systems respectively determined by a combination of at least two scales facing the head.
- the Z / tilt position measurement system and the encoder system constitute the substrate measurement system.
- the substrate measurement system may be configured only by the encoder system.
- At least one head arranged away from the measurement table 1782 in the X-axis direction may be provided apart from the pair of measurement tables 1782.
- the same movable head unit as the measurement table 1782 is provided on the ⁇ Y side with respect to a mark detection system (alignment system) that is arranged away from the projection optical system 16 in the X-axis direction and detects an alignment mark on the substrate P.
- the positional information of the Y coarse movement stage 24 may be measured using a pair of head units arranged on the ⁇ Y side of the mark detection system in the detection operation of the substrate mark.
- the positional information of the Y coarse movement stage 24 by the substrate measurement system can be continued, and the degree of freedom in designing the exposure apparatus, such as the position of the mark detection system, can be increased.
- the position information of the Y coarse movement stage 24 by the substrate measurement system is also used in the detection operation of the Z position of the substrate. Can be measured.
- the substrate measurement system may be arranged in the vicinity of the projection optical system 16 and the position information of the Y coarse movement stage 24 may be measured by the pair of measurement tables 1782 in the detection operation of the Z position of the substrate. Further, in this embodiment, when the Y coarse movement stage 24 is arranged at the substrate exchange position set apart from the projection optical system 16, the measurement beams are scaled by the scales 1788 (or 684) at all the heads of the pair of measurement tables 1782. ).
- At least one head facing at least one of the plurality of scales 1788 (or 684) of the Y coarse movement stage 24 arranged at the substrate exchange position is provided, and the substrate Even in the exchange operation, the position information of the Y coarse movement stage 24 may be measured by the substrate measurement system.
- the pair of measurement tables 1782 When the measurement beams are deviated from the scale 1788 (or 684) in all the heads, at least one head is additionally arranged in the middle of the movement path of the Y coarse movement stage 24, and the position information of the substrate holder 32 by the substrate measurement system is displayed. Measurement may be continued. Note that when at least one head provided separately from the pair of measurement tables 1782 is used, the above-described connection processing may be performed using the measurement information of the pair of measurement tables 1782.
- the XZ head described above may be used instead of each X head 74x, and the YZ head described above may be used instead of each Y head 74y.
- a pair of XZ heads, a pair of YZ heads, and an encoder system in which these can face each other relate to at least one of rotation ( ⁇ z) and inclination (at least one of ⁇ x and ⁇ y) of the plurality of heads 74x and 74y.
- the position information may be measured.
- a lattice is formed on the surface (the surface is a lattice surface).
- a cover member glass or thin film covering the lattice is provided, and the lattice surface is the scale surface. It may be inside.
- each pair of the X head 80x and the Y head 80y is provided on the measurement table 1782 together with the head for measuring the position of the Y coarse movement stage 24 has been described.
- the pair of X head 80x and Y head 80y may be provided in a head for measuring the position of the Y coarse movement stage 24 without using the measurement table 1782.
- the measurement direction in the XY plane of each head included in the substrate encoder system is the X-axis direction or the Y-axis direction
- a two-dimensional lattice having a periodic direction in two directions (referred to as ⁇ direction and ⁇ direction for convenience) intersecting the X axis direction and the Y axis direction and orthogonal to each other may be used.
- a head having the ⁇ direction (and the Z axis direction) or the ⁇ direction (and the Z axis direction) as the respective measurement directions may be used as each of the heads described above.
- each X scale and Y scale for example, a one-dimensional grating having a periodic direction in the ⁇ direction and the ⁇ direction is used, and correspondingly, as each head described above, It is also possible to use a head whose respective measurement directions are the ⁇ direction (and the Z axis direction) or the ⁇ direction (and the Z axis direction).
- the first lattice group is composed of the aforementioned X-scale column
- the second lattice group is composed of the aforementioned Y-scale column.
- a plurality of X heads (or XZ heads) are arranged at a predetermined interval (an interval larger than the interval between adjacent X scales) so as to be able to face the scale row, and a plurality of Y heads (being able to face the Y scale row)
- YZ heads may be arranged at a predetermined interval (interval larger than the interval between adjacent Y scales).
- a plurality of scales having different lengths may be used as the scales arranged side by side in the X-axis direction or the Y-axis direction.
- the center of the scales arranged near the both ends in the X-axis direction (the scales arranged at the respective ends in the scale row) is longer than the length in the X-axis direction.
- the scale arranged in the part may be physically longer.
- the measurement table encoder may measure at least position information in the movement direction of the measurement table (in the above embodiment, the Y-axis direction). Position information in at least one direction (at least one of X, Z, ⁇ x, ⁇ y, and ⁇ z) different from the moving direction may also be measured. For example, position information in the X-axis direction of a head (X head) whose measurement direction is the X-axis direction may also be measured, and position information in the X-axis direction may be obtained from this X information and measurement information of the X head.
- position information in the X-axis direction orthogonal to the measurement direction may not be used.
- position information in the Y-axis direction orthogonal to the measurement direction may not be used.
- position information in at least one direction different from the measurement direction of the head may be measured, and position information of the substrate holder 622 and the like related to the measurement direction may be obtained from this measurement information and the measurement information of the head.
- position information (rotation information) in the ⁇ z direction of the movable head is measured using two measurement beams having different positions in the X-axis direction, and the rotation information and measurement information of the X head and the Y head are used.
- the position information of the substrate holder 622 and the like in the X-axis and Y-axis directions may be obtained.
- two X heads and one Y head, one other, and two heads having the same measurement direction are arranged so as not to be in the same position with respect to the direction orthogonal to the measurement direction.
- Position information in the ⁇ z direction can be measured.
- the other head is preferably irradiated with a measurement beam at a position different from the two heads.
- the head of the movable head encoder is an XZ head or a YZ head, for example, by arranging one of the XZ head and the YZ head and one of the other so as not to be on the same straight line, only Z information can be obtained.
- position information (tilt information) in the ⁇ x and ⁇ y directions can also be measured.
- Position information in the X-axis and Y-axis directions may be obtained from at least one of position information in the ⁇ x and ⁇ y directions and measurement information of the X head and the Y head.
- position information of the movable head in a direction different from the Z-axis direction may be measured, and the position information in the Z-axis direction may be obtained from the measurement information and the head measurement information.
- the scale of the encoder that measures the position information of the movable head is a single scale (lattice area)
- XY ⁇ z and Z ⁇ x ⁇ y can be measured with three heads, but a plurality of scales (lattice areas) are arranged separately.
- two X heads and two Y heads or two XZ heads and two YZ heads are arranged, and the interval in the X-axis direction is set so that the non-measurement periods do not overlap with the four heads. good.
- This description is based on a scale in which the lattice area is arranged in parallel with the XY plane, but can be similarly applied to a scale in which the lattice area is arranged in parallel with the YZ plane.
- an encoder is used as a measurement device that measures position information of a measurement table.
- an interferometer may be used. good.
- a reflecting surface may be provided on the movable head (or its holding portion), and the reflecting surface may be irradiated with the measurement beam in parallel with the Y-axis direction.
- the movable head is moved only in the Y-axis direction, it is not necessary to increase the reflecting surface, and local air conditioning of the optical path of the interferometer beam for reducing air fluctuation is facilitated.
- one movable head that irradiates the measurement beam onto the scale of the Y coarse movement stage 24 is provided on each side of the projection system in the Y-axis direction. It may be provided. For example, if adjacent movable heads (measurement beams) are arranged so that the measurement periods partially overlap with each other in the Y-axis direction, even if the Y coarse movement stage 24 moves in the Y-axis direction, the plurality of movable heads are movable. Position measurement can be continued with the head. In this case, a connecting process is required with a plurality of movable heads.
- the correction information about another head where the measurement beam enters the scale is obtained by using measurement information of a plurality of heads that are arranged only on one side of the projection system on the ⁇ Y side and are irradiated with the measurement beam on at least one scale.
- measurement information of at least one head arranged on the other side as well as one of the ⁇ Y sides may be used.
- a plurality of scales are arranged apart from each other in the scanning direction (X-axis direction) in which the substrate P is moved in scanning exposure, and a plurality of scales are arranged.
- the head can be moved in the step direction (Y-axis direction) of the substrate P.
- a plurality of scales are arranged apart from each other in the step direction (Y-axis direction), and the plurality of heads are moved in the scanning direction. It may be movable in the (X-axis direction).
- the head of the encoder system does not need to have all of the optical system that irradiates the scale with the beam from the light source, but only a part of the optical system, for example, the emission unit. It is good also as what has.
- the heads of the pair of head bases 88 are arranged as shown in FIG. 71 (the X head and the Y head are arranged on the ⁇ Y side, respectively,
- the arrangement of the X and Y heads is not limited to the opposite direction), for example, the X head and the Y head are arranged on the ⁇ Y side, respectively, and the X and Y directions on one side and the other on the ⁇ Y side
- the head arrangement may be the same. However, if the X positions of the two Y heads are the same, it is preferable to make the X positions of the two Y heads different because the ⁇ z information cannot be measured if the measurement of one of the two X heads is interrupted.
- the projection optical system 16 when the scale (scale member, grating portion) irradiated with the measurement beam from the head of the encoder system is provided on the projection optical system 16 side, the projection optical system 16 is supported. You may provide in the lens-barrel part of the projection optical system 16 not only in a part of apparatus main body 18 (frame member).
- the case in which the movement direction (scanning direction) of the mask M and the substrate P during scanning exposure is the X-axis direction, but the scanning direction may be the Y-axis direction.
- the long stroke direction of the mask stage it is necessary to set the long stroke direction of the mask stage to a direction rotated 90 degrees around the Z axis, and the direction of the projection optical system 16 also needs to be rotated 90 degrees around the Z axis.
- a scale group in which a plurality of scales are arranged in series in the X-axis direction with a gap of a predetermined interval on the Y coarse movement stage 24.
- a plurality of rows are arranged at different positions separated from each other in the Y-axis direction (for example, a position on one side (+ Y side) and a position on the other side ( ⁇ Y side) with respect to the projection optical system 16)
- You may comprise so that a scale group (a several scale row
- the lengths of the plurality of scale rows as a whole are different from each other between the scale rows, different shot maps can be handled, and shot areas formed on the substrate in the case of four-sided and six-sided chamfers, etc. It can respond to changes in the number of
- the positions of the gaps of the scale rows are made different from each other in the X-axis direction, the heads corresponding to the plurality of scale rows will not be out of the measurement range at the same time. It is possible to reduce the number of sensors having an indeterminate value in FIG.
- one scale in a scale group (scale array) in which a plurality of scales are arranged in series in the X-axis direction via a gap of a predetermined interval on the Y coarse movement stage 24.
- the length in the X-axis direction is the length of one shot region (the length formed on the substrate by irradiation of the device pattern when performing scanning exposure while moving the substrate on the substrate holder in the X-axis direction) ), The length may be measured continuously. In this way, it is not necessary to perform head transfer control for a plurality of scales during scan exposure of a one-shot area, so that position measurement (position control) of the substrate P (substrate holder) during scan exposure can be easily performed. it can.
- the substrate measuring system obtains positional information while the substrate stage device moves to the substrate exchange position with the substrate loader, or the substrate stage device or another stage device. It is also possible to provide a scale for exchanging the substrate and obtain the position information of the substrate stage apparatus using a downward head. Alternatively, the substrate stage apparatus or another stage apparatus may be provided with a substrate replacement head, and the position information of the substrate stage apparatus may be acquired by measuring the scale or the substrate replacement scale.
- a position measurement system for example, a mark on the stage and an observation system for observing it
- a position measurement system may be provided separately from the encoder system to perform stage exchange position control (management).
- the substrate stage apparatus only needs to be able to drive at least the substrate P along a horizontal plane with a long stroke, and in some cases, the substrate stage device may not be able to perform fine positioning in the direction of six degrees of freedom.
- the substrate encoder system according to the first to twenty-second embodiments can also be suitably applied to such a two-dimensional stage apparatus.
- the illumination light may be ultraviolet light such as ArF excimer laser light (wavelength 193 nm), KrF excimer laser light (wavelength 248 nm), or vacuum ultraviolet light such as F 2 laser light (wavelength 157 nm).
- the single wavelength laser beam of the infrared region or visible region oscillated from the DFB semiconductor laser or fiber laser is amplified by a fiber amplifier doped with erbium (or both erbium and ytterbium), You may use the harmonic which wavelength-converted into ultraviolet light using the nonlinear optical crystal.
- a solid laser (wavelength: 355 nm, 266 nm) or the like may be used.
- the projection optical system 16 is a multi-lens projection optical system including a plurality of optical systems has been described, but the number of projection optical systems is not limited to this, and one or more projection optical systems may be used.
- the projection optical system is not limited to a multi-lens projection optical system, and may be a projection optical system using an Offner type large mirror. Further, the projection optical system 16 may be an enlargement system or a reduction system.
- the use of the exposure apparatus is not limited to the exposure apparatus for liquid crystal that transfers the liquid crystal display element pattern to the square glass plate, but is used for the exposure apparatus for manufacturing an organic EL (Electro-Luminescence) panel, for semiconductor manufacturing.
- the present invention can be widely applied to an exposure apparatus for manufacturing an exposure apparatus, a thin film magnetic head, a micromachine, a DNA chip, and the like.
- microdevices such as semiconductor elements but also masks or reticles used in light exposure apparatuses, EUV exposure apparatuses, X-ray exposure apparatuses, electron beam exposure apparatuses, etc., glass substrates, silicon wafers, etc.
- the present invention can also be applied to an exposure apparatus that transfers a circuit pattern.
- the object to be exposed is not limited to the glass plate, but may be another object such as a wafer, a ceramic substrate, a film member, or a mask blank.
- the thickness of the substrate is not particularly limited, and includes a film-like (flexible sheet-like member).
- the exposure apparatus of the present embodiment is particularly effective when a substrate having a side length or diagonal length of 500 mm or more is an exposure target.
- the step of designing the function and performance of the device the step of producing a mask (or reticle) based on this design step, and the step of producing a glass substrate (or wafer)
- the above-described exposure method is executed using the exposure apparatus of the above embodiment, and a device pattern is formed on the glass substrate. Therefore, a highly integrated device can be manufactured with high productivity. .
- the mobile device and the moving method of the present invention are suitable for moving an object.
- the exposure apparatus of the present invention is suitable for exposing an object.
- the manufacturing method of the flat panel display of this invention is suitable for manufacture of a flat panel display.
- the device manufacturing method of the present invention is suitable for manufacturing micro devices.
- DESCRIPTION OF SYMBOLS 10 Liquid crystal exposure apparatus, 20 ... Substrate stage apparatus, 24 ... Y coarse movement stage, 32 ... Substrate holder, 70 ... Substrate measurement system, 72 ... Upward scale, 74x ... Downward X head, 74y ... Downward Y head, 78 ... Downward Scale, 80x ... Upward X head, 80y ... Upward Y head, 100 ... Main controller, P ... Substrate.
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Abstract
Description
前記第1格子領域と前記複数の第1ヘッドとの他方に設けられた第2移動体により、前記第1移動体を前記第2方向へ移動させることと、第2計測系により、前記第1および第2方向の計測成分を含む第2格子領域と、前記第2格子領域に対して前記第2方向へ移動しながら計測ビームを照射する第2ヘッドとの一方が前記第2移動体に設けられ、第2格子領域と前記第2格子領域との他方が前記第2移動体に対向するように設けられ、前記第2方向に関する前記第2移動体の位置情報を計測することと、前記第1および第2計測系で計測される前記位置情報と、前記第1格子部材、前記複数の第1ヘッド、および前記第1移動体の移動の少なくもと1つに起因して生じる前記計測系の計測誤差を補償するための補正情報とに基づいて、前記第1および第2方向を含む所定平面内の3自由度方向に関する前記第1移動体の移動制御を行うことと、を含む移動方法が、提供される。
以下、第1の実施形態について、図1~図6を用いて説明する。
次に第2の実施形態に係る液晶露光装置について、図7~図10を用いて説明する。第2の実施形態に係る液晶露光装置の構成は、基板ステージ装置220(計測系を含む)の構成が異なる点を除き、上記第1の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第1の実施形態と同じ構成又は機能を有する要素については、上記第1の実施形態と同じ符号を付して適宜その説明を省略する。
次に第3の実施形態に係る液晶露光装置について、図11~図14を用いて説明する。第3の実施形態に係る液晶露光装置の構成は、基板ステージ装置320(計測系を含む)の構成が異なる点を除き、上記第2の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第2の実施形態と同じ構成又は機能を有する要素については、上記第2の実施形態と同じ符号を付して適宜その説明を省略する。
次に第4の実施形態に係る液晶露光装置について、図15~図18を用いて説明する。第4の実施形態に係る液晶露光装置の構成は、基板ステージ装置420(計測系を含む)の構成が異なる点を除き、上記第2の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第2の実施形態と同じ構成又は機能を有する要素については、上記第2の実施形態と同じ符号を付して適宜その説明を省略する。
次に第5の実施形態に係る液晶露光装置について、図19~図22を用いて説明する。第5の実施形態に係る液晶露光装置の構成は、基板計測系550の構成が異なる点を除き、上記第4の実施形態と概ね同じである。また、基板計測系550の構成は、上記第3の実施形態の基板計測系350(図11など参照)と概ね同じである。以下、相違点についてのみ説明し、上記第3又は第4の実施形態と同じ構成又は機能を有する要素については、上記第3又は第4の実施形態と同じ符号を付して適宜その説明を省略する。
次に第6の実施形態に係る液晶露光装置について、図23~図27を用いて説明する。第6の実施形態に係る液晶露光装置の構成は、基板ステージ装置620、及びその計測系の構成が異なる点を除き、上記第1の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第1の実施形態と同じ構成又は機能を有する要素については、上記第1の実施形態と同じ符号を付して適宜その説明を省略する。
次に第7の実施形態に係る液晶露光装置について、図28~図31を用いて説明する。第7の実施形態に係る液晶露光装置の構成は、基板ステージ装置720、及びその計測系の構成が異なる点を除き、上記第6の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第6の実施形態と同じ構成又は機能を有する要素については、上記第6の実施形態と同じ符号を付して適宜その説明を省略する。
次に第8の実施形態に係る液晶露光装置について、図32~図35を用いて説明する。第8の実施形態に係る液晶露光装置の構成は、基板ステージ装置820、及びその計測系の構成が異なる点を除き、上記第6の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第6の実施形態と同じ構成又は機能を有する要素については、上記第6の実施形態と同じ符号を付して適宜その説明を省略する。
次に第9の実施形態に係る液晶露光装置について、図36~図38を用いて説明する。第9の実施形態に係る液晶露光装置の構成は、基板ステージ装置920(図38参照)、及びその計測系の構成が異なる点を除き、上記第8の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第8の実施形態と同じ構成又は機能を有する要素については、上記第8の実施形態と同じ符号を付して適宜その説明を省略する。
次に第10の実施形態に係る液晶露光装置について、図39~図43を用いて説明する。第10の実施形態に係る液晶露光装置の構成は、基板ステージ装置1020(図41など参照)、及びその計測系の構成が異なる点を除き、上記第9の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第9の実施形態と同じ構成又は機能を有する要素については、上記第9の実施形態と同じ符号を付して適宜その説明を省略する。
次に第11の実施形態に係る液晶露光装置について、図44~図47を用いて説明する。第11の実施形態に係る液晶露光装置の構成は、基板ステージ装置1120、及びその計測系の構成が異なる点を除き、上記第10の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第10の実施形態と同じ構成又は機能を有する要素については、上記第10の実施形態と同じ符号を付して適宜その説明を省略する。
次に第12の実施形態に係る液晶露光装置について、図48~図54を用いて説明する。第12の実施形態に係る液晶露光装置の構成は、基板ステージ装置1220、及びその計測系の構成が異なる点を除き、上記第7の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第7の実施形態と同じ構成又は機能を有する要素については、上記第7の実施形態と同じ符号を付して適宜その説明を省略する。
次に第13の実施形態に係る液晶露光装置について、図55~図58を用いて説明する。第13の実施形態に係る液晶露光装置の構成は、基板ステージ装置1320、及びその計測系の構成が異なる点を除き、上記第12の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第12の実施形態と同じ構成又は機能を有する要素については、上記第12の実施形態と同じ符号を付して適宜その説明を省略する。
次に第14の実施形態に係る液晶露光装置について、図59を用いて説明する。第14の実施形態に係る液晶露光装置の構成は、基板ステージ装置1420、及びその計測系の構成が異なる点を除き、上記第13の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第13の実施形態と同じ構成又は機能を有する要素については、上記第13の実施形態と同じ符号を付して適宜その説明を省略する。
次に第15の実施形態に係る液晶露光装置について、図60~図63を用いて説明する。第15の実施形態に係る液晶露光装置の構成は、基板ステージ装置1520の構成が異なる点を除き、上記第1又は第6の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第1又は第6の実施形態と同じ構成又は機能を有する要素については、上記第1又は第6の実施形態と同じ符号を付して適宜その説明を省略する。
次に第16の実施形態に係る液晶露光装置について、図64を用いて説明する。第16の実施形態に係る液晶露光装置の構成は、基板ステージ装置1620、及びその計測系の構成が異なる点を除き、上記第6又は第15の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第6又は第15の実施形態と同じ構成又は機能を有する要素については、上記第6又は第15の実施形態と同じ符号を付して適宜その説明を省略する。
次に第17の実施形態に係る液晶露光装置について、図65を用いて説明する。第17の実施形態に係る液晶露光装置の構成は、基板ステージ装置1720、及びその計測系の構成が異なる点を除き、上記第15又は第16の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第15又は第16の実施形態と同じ構成又は機能を有する要素については、上記第15又は第16の実施形態と同じ符号を付して適宜その説明を省略する。
次に第18の実施形態に係る液晶露光装置について、図66~図68用いて説明する。第18の実施形態に係る液晶露光装置の構成は、基板ステージ装置1820、及びその計測系の構成が異なる点を除き、上記第1の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第1の実施形態と同じ構成又は機能を有する要素については、上記第1の実施形態と同じ符号を付して適宜その説明を省略する。
次に第19の実施形態に係る液晶露光装置について、図69、図70用いて説明する。第19の実施形態に係る液晶露光装置の構成は、装置本体1918、及び基板計測系1970(図70参照)の構成が異なる点を除き、上記第18の実施形態と概ね同じであるので、以下、相違点についてのみ説明し、上記第18の実施形態と同じ構成又は機能を有する要素については、上記第18の実施形態と同じ符号を付して適宜その説明を省略する。
次に、第20の実施形態について図71~図74(C)に基づいて説明する。本第20の実施形態に係る液晶露光装置の構成は、基板計測系2070の一部の構成を除き、前述の第1の実施形態と同じなので、以下、相違点についてのみ説明し、第1の実施形態と同じ構成及び機能を有する要素については、第1の実施形態と同じ符号を付してその説明を省略する。
CY=-(pi-X)sinθz+(qi-Y)cosθz ……(1b)
ここで、X、Y、θzは、それぞれ基板ホルダ32のX軸方向、Y軸方向及びθz方向の位置を示す。また、pi、qiは、ヘッド74a~74dそれぞれのX位置(X座標値)、Y位置(Y座標値)である。本実施形態では、ヘッド74a、74b、74c、74dそれぞれのX座標値pi及びY座標値qi(i=1、2、3、4)は、各一対のXヘッド80x及びYヘッド80yとそれに対向するスケール78から出力される計測結果、及び、ヘッドベース1996とスケール72との相対位置関係により算出される。
C3=-(p3-X)sinθz+(q3-Y)cosθz ……(2b)
C4= (p4-X)cosθz+(q4-Y)sinθz ……(2c)
基板ホルダ32が座標原点(X,Y、θz)=(0,0,0)にある基準状態では、連立方程式(2a)~(2c)より、C1=p1,C3=q3,C4=p4となる。基準状態は、例えば投影光学系16による投影領域の中心に、基板ホルダ32中心(基板Pの中心にほぼ一致)が一致し、θz回転がゼロの状態である。したがって、基準状態では、ヘッド74bによる基板ホルダ32のY位置の計測も可能となっており、ヘッド74bによる計測値C2は、式(1b)に従い、C2=q2となる。
C4= (p4-X)cosθz+(q4-Y)sinθz ……(2c)
C2=-(p2-X)sinθz+(q2-Y)cosθz ……(2d)
連立方程式(2a)~(2c)及び連立方程式(2a)、(2c)、(2d)では、変数が3つ(X,Y,θz)に対して3つの式が与えられている。従って、逆に、連立方程式(2a)~(2c)における従属変数C1,C3,C4、あるいは連立方程式(2a)、(2c)、(2d)における従属変数C1,C4,C2が与えられれば、変数X,Y,θzを求めることができる。ここで、近似sinθz≒θzを適用すると、あるいはより高次の近似を適用しても、容易に方程式を解くことができる。従って、ヘッド74a、74c、74d(又はヘッド74a、74b、74d)の計測値C1,C3,C4(又はC1,C2,C4)より基板ホルダ32の位置(X,Y,θz)を算出することができる。
上式(3)において、p3,q3は、ヘッド74cの計測点のX座標値、Y座標値である。
C4= (p4-X)cosθz+(q4-Y)sinθz ……(2c)
C2=-(p2-X)sinθz+(q2-Y)cosθz ……(2d)
なお、上では、3つのヘッドから、この3つのヘッドと異なる別のヘッドを1つ含む異なる3つのヘッドへの切り換えについて説明したが、これは切り換え前の3つのヘッドの計測値から求まる基板ホルダ32の位置(X、Y、θz)を用いて、切り換え後に用いられる別のヘッドで計測すべき値を、アフィン変換の原理に基づいて、算出し、その算出した値を、切り換え後に用いられる別のヘッドの初期値として設定しているため、このように説明した。しかしながら、切り換え後に用いられる別のヘッドで計測すべき値の算出等の手順には触れず、切り換え及びつなぎ処理の直接の対象である2つのヘッドにのみ注目すれば、切り換え前に使用している3つのヘッドのうちの1つのヘッドを別の1つのヘッドに切り換えているとも言える。いずれにしても、ヘッドの切り換えは、切り換え前に基板ホルダの位置情報の計測及び位置制御に用いられているヘッドと、切り換え後に用いられるヘッドとが、ともに、いずれかのスケール2072に同時に対向している状態で行われる。
〈スケールの凹凸(平坦性)に起因する計測誤差の補正情報〉
ホルダエンコーダシステムの各ヘッドの光軸がZ軸にほぼ一致しており、かつ基板ホルダ32のピッチング量、ローリング量及びヨーイング量が、全てゼロの場合には、基板ホルダ32の姿勢に起因する各エンコーダの計測誤差は生じない筈である。しかし、実際には、このような場合であっても各エンコーダの計測誤差はゼロとはならいない。これは、スケール2072の格子面(例えば表面)が理想的な平面ではなく、多少の凹凸が存在するからである。スケールの格子面に凹凸があると、基板ホルダ32がXY平面と平行に動いた場合でも、ヘッドに対してスケール格子面はZ軸方向に変位したり(上下動したり)、傾斜したりすることになる。これは、結果的にヘッドとスケールとに非計測方向に関する相対運動が生じることに他ならず、このような相対運動は、計測誤差の要因となることは、前述したとおりである。
エンコーダのスケールは、使用時間の経過と共に熱膨張その他により回折格子が変形したり、回折格子のピッチが部分的は又は全体的に変化したりする等、機械的な長期安定性に欠ける。このため、その計測値に含まれる誤差が使用時間の経過と共に大きくなるので、これを補正する必要がある。
ところで基板ホルダ32が計測方向、例えばX軸方向(又はY軸方向)とは異なる方向に移動し、ヘッド74x(又はヘッド74y)とスケール2072との間に計測したい方向以外の相対運動(非計測方向の相対運動)が生じると、殆どの場合、それによってXエンコーダ(又はYエンコーダ)に計測誤差が生じる。
f. その後、上記d.とeとの動作を交互に繰り返して、ピッチング量θyが例えば-200μrad<θx<+200μradの範囲について、Δα(rad)、例えば40μrad間隔で上記Z駆動範囲内のヘッド74aの計測値を取り込む。
Δy=g(z,θx,θz)=θx(z-c)+θz(z-d) ……(5)
上式(4)において、aは、Xエンコーダの補正情報の取得のためにピッチング量を変化させた場合の図77のグラフの、ピッチング量が同じときのプロット点をそれぞれ結んだ各直線が交わる点のZ座標であり、bは、Xエンコーダの補正情報の取得のためにヨーイング量を変化させた場合の図77と同様のグラフの、ヨーイング量が同じときのプロット点をそれぞれ結んだ各直線が交わる点のZ座標である。また、上式(5)において、cは、Yエンコーダの補正情報の取得のためにローリング量を変化させた場合の図77と同様のグラフの、ローリング量が同じときのプロット点をそれぞれ結んだ各直線が交わる点のZ座標であり、dは、Yエンコーダの補正情報の取得のためにヨーイング量を変化させた場合の図77と同様のグラフの、ヨーイング量が同じときのプロット点をそれぞれ結んだ各直線が交わる点のZ座標である。
ヘッド起因誤差としては、代表的にヘッドの倒れに起因するエンコーダの計測誤差が挙げられる。すなわち、基板Pが水平面に平行に配置されている場合に、基板Pの面の法線(鉛直軸)に対してヘッドの光軸が傾いていることは、ヘッドが鉛直軸に平行(光軸に倒れがない)である場合に基板Pが水平面に対して傾斜している場合に他ならない。したがって、エンコーダ計測値に計測誤差が生じる。そして、回折干渉方式のエンコーダヘッドでは、光軸に対称な2方向から基板上の1点に2本の計測ビームを照射し、戻ってくる2つの戻り光束を干渉させて得られる光電変換信号に基づいて、計測値を求めている。このとき、干渉光の強度Iは、1+cosφに比例する(φは、2つの戻り光束の位相の差を意味する)。また、回折干渉方式のエンコーダヘッドでは、2本の計測ビームが、対称な光路を通って戻るときに、計測誤差がゼロとなるように予め設定されている。このため、ヘッドの光軸が倒れると、2つの光束の光路長が差がゼロにならない(したがって、2つの戻り光の光束の位相のさφが変化する)。また、上述した光路の対称性がくずれた場合にも、位相の差φが変化する。すなわち、エンコーダシステムの計測誤差の発生要因となるヘッドユニットの特性情報はヘッドの倒れだけでなくその光学特性なども含む。
ところで、スケールベース84上の各スケール格子面(2次元グレーティング表面)の高さ(Z位置)と、露光中心(前述の露光領域の中心)を含む基準面の高さとに誤差(又はギャップ)があると、基板ホルダ32のXY平面と平行な軸(Y軸又はX軸)回りの回転(ピッチング又はローリング)の際にエンコーダの計測値にいわゆるアッベ誤差が生じるので、この誤差を補正することが必要である。ここで、基準面とは、基板ホルダ32のZ軸方向の位置制御のための基準となる面(基板ホルダ32のZ軸方向の変位の基準となる面)、あるいは基板Pの露光動作において基板Pが一致する面であって、本実施形態では、投影光学系16の像面に一致しているものとする。
he=(xe1-xe0)/φ ……(7)
主制御装置100は、上述と同様の手順で、第1格子群の1つのスケール2072と、これにY軸方向でほぼ対向する第2格子群の1つのスケール2072とを組として、残りのスケールについても、アッベ外し量を、それぞれ取得する。なお、第1格子群の1つのスケール2072と、第2格子群の1つのスケール2072とについて、必ずしも同時にアッベ外し量の計測を行う必要はなく、各スケール2072について、別々にアッベ外し量を計測しても良い。
式(8)において、hは、Xエンコーダを構成するXヘッドが対向するスケール2072のアッベ外し量である。
式(9)において、hは、Yエンコーダを構成するYヘッドが対向するスケール2072のアッベ外し量である。
次に、第21の実施形態について図75に基づいて説明する。本第21の実施形態に係る液晶露光装置の構成は、基板計測系2170の一部の構成を除き、前述の第1及び第20の実施形態と同じなので、以下、相違点についてのみ説明し、第1及び第20の実施形態と同じ構成及び機能を有する要素については、第1及び第20の実施形態と同じ符号を付してその説明を省略する。
次に、第22の実施形態について図76に基づいて説明する。本第22の実施形態に係る液晶露光装置の構成は、図76に示されるように、基板ホルダ32の基板載置領域の+Y側と-Y側にそれぞれ配置されたスケール2072の列が、第21の実施形態と同様に対向配置され、且つ-Y側に位置する一方のヘッドベース88が、前述の第20の実施形態と同様に各2つのXヘッド74x、Yヘッド74yを有している点が、前述の第21の実施形態に係る液晶露光装置の構成と相違するが、その他の部分の構成は第21の実施形態に係る液晶露光装置と同様になっている。
この変形例は、第22の実施形態に係る液晶露光装置において、+Y側に位置する他方のヘッドベース88として、一方のヘッドベース88と同じ構成(又は紙面上下方向に関して対称な構成)のヘッドユニットが用いられる場合である。
Claims (48)
- 物体を保持し、互いに交差する第1方向と第2方向へ移動可能な第1移動体と、
前記第1方向に関して複数の格子領域が互いに離れて配置され、前記第1および第2方向の計測成分を含む第1格子領域と、前記第1格子領域に対して前記第1方向へ移動しながら計測ビームを照射する複数の第1ヘッドとの一方が前記第1移動体に設けられ、前記複数の第1ヘッドのうち、前記計測ビームが前記複数の格子領域の少なくとも1つに照射される少なくとも3つの第1ヘッドにより計測される前記第1方向に関する前記第1移動体の位置情報を計測する第1計測系と、
前記第1格子領域と前記複数の第1ヘッドとの他方に設けられ、前記第2方向へ移動可能な第2移動体と、
前記第1および第2方向の計測成分を含む第2格子領域と、前記第2格子領域に対して前記第2方向へ移動しながら計測ビームを照射する第2ヘッドとの一方が前記第2移動体に設けられ、第2格子領域と前記第2格子領域との他方が前記第2移動体に対向するように設けられ、前記第2方向に関する前記第2移動体の位置情報を計測する第2計測系と、
前記第1および第2計測系で計測される前記位置情報と、前記第1格子部材、前記複数の第1ヘッド、および前記第1移動体の移動の少なくもと1つに起因して生じる前記計測系の計測誤差を補償するための補正情報とに基づいて、前記第1および第2方向を含む所定平面内の3自由度方向に関する前記第1移動体の移動制御を行う制御系と、を備える移動体装置。 - 請求項1に記載の移動体装置において、
前記補正情報は、前記複数の格子領域の少なくとも1つにおける変形、変位、平坦性、および形成誤差の少なくもと1つに起因して生じる前記計測系の計測誤差を補償する移動体装置。 - 請求項1又は2に記載の移動体装置において、
前記補正情報は、前記複数の第1ヘッドの少なくとも1つの光学特性、および前記第2方向と異なる方向に関する変位の少なくとも一方に起因して生じる前記計測系の計測誤差を補償する移動体装置。 - 請求項1~3のいずれか一項に記載の移動体装置において、
前記補正情報は、前記移動体の位置制御のための基準面、あるいは前記物体の露光動作において前記基板が一致する基準面と、前記格子部の格子面との、前記所定平面と直交する第3方向に関する位置の差に起因して生じる前記計測系の計測誤差を補償する移動体装置。 - 請求項4に記載の移動体装置において、
前記基準面は、前記光学系の像面を含む移動体装置。 - 光学系を介して照明光で基板を露光する移動体装置であって、
前記光学系の下方に配置され、前記基板を保持する移動体と、
前記光学系の光軸と直交する所定平面内で互いに直交する第1、第2方向に関して前記移動体を移動可能な駆動系と、
前記第1方向に関して複数の格子領域が互いに離れて配置される格子部材と、前記格子部材に対してそれぞれ計測ビームを照射しかつ前記第2方向に関して移動可能な複数の第1ヘッドとの一方が前記移動体に設けられるとともに、前記格子部材と前記複数の第1ヘッドとの他方が前記移動体と対向するように設けられる計測系であって、前記計測系は、前記複数の第1ヘッドにスケール部材と第2ヘッドとの一方が設けられるとともに、前記スケール部材と前記第2ヘッドとの他方が前記複数の第1ヘッドに対向するように設けられ、前記第2ヘッドを介して前記スケール部材に計測ビームを照射し、前記第2方向に関する前記複数の第1ヘッドの位置情報を計測する計測装置を有し、前記複数の第1ヘッドのうち、前記計測ビームが前記複数の格子領域の少なくとも1つに照射される少なくとも3つの第1ヘッドの計測情報と、前記計測装置の計測情報と、に基づき、少なくとも前記所定平面内の3自由度方向に関する前記移動体の位置情報を計測し、
前記スケール部材と前記第2ヘッドとの少なくとも一方に起因して生じる前記計測装置の計測誤差を補償するための補正情報と、前記計測系で計測される位置情報と、に基づいて、前記駆動系を制御する制御系と、備え、
前記複数の第1ヘッドはそれぞれ、前記第1方向への前記移動体の移動中、前記計測ビームが前記複数の格子領域の1つから外れるととともに、前記1つの格子領域に隣接する別の格子領域に乗り換える移動体装置。 - 請求項5に記載の移動体装置において、
前記光学系を支持するフレーム部材を、さらに備え、
前記計測装置は、前記スケール部材と前記第2ヘッドとの一方が前記複数の第1ヘッドに設けられ、前記スケール部材と前記第2ヘッドとの他方が前記光学系または前記フレーム部材に設けられる移動体装置。 - 請求項6又は7に記載の移動体装置において、
前記スケール部材は、前記第2方向に関して互いに離れて配置される複数の格子部を有し、
前記計測装置は、前記第2方向に関して前記計測ビームの位置が異なる少なくとも2つの前記第2ヘッドを含む複数の前記第2ヘッドを有し、
前記少なくとも2つの第2ヘッドは、前記第2方向に関して、前記複数の格子部のうち隣接する一対の格子部の間隔よりも広い間隔で配置される移動体装置。 - 請求項8に記載の移動体装置において、
前記複数の第2ヘッドは、前記第1方向と、前記所定平面と直交する第3方向との一方に関して、前記少なくとも2つの第2ヘッドの少なくとも1つと前記計測ビームの位置が異なる少なくとも1つの第2ヘッドを含む移動体装置。 - 請求項6~9のいずれか一項に記載の移動体装置において、
前記計測装置は、前記スケール部材に対して互いに異なる位置に複数の前記計測ビームを照射し、前記第2方向と異なる方向に関する前記複数の第1ヘッドの位置情報を計測する移動体装置。 - 請求項6~10のいずれか一項に記載の移動体装置において、
前記計測装置は、前記複数の第1ヘッドの回転と傾斜との少なくとも一方に関する位置情報を計測する移動体装置。 - 請求項6~11のいずれか一項に記載の移動体装置において、
前記スケール部材は、反射型の2次元格子あるいは互いに配列方向が異なる2つの1次元格子の少なくとも一方を有する移動体装置。 - 請求項6~12のいずれか一項に記載の移動体装置において、
前記補正情報は、前記スケール部材の変形、変位、平坦性、および形成誤差の少なくもと1つに起因して生じる前記計測装置の計測誤差を補償する移動体装置。 - 請求項1~13のいずれか一項に記載の移動体装置において、
前記複数の第1ヘッドはそれぞれ、前記所定平面内で互いに交差する2方向の一方を計測方向とし、
前記計測系で計測に用いられる前記少なくとも3つの第1ヘッドは、前記2方向の一方を計測方向とする少なくとも1つの第1ヘッドと、前記2方向の他方を計測方向とする少なくとも2つの第1ヘッドと、を含む移動体装置。 - 請求項1~14のいずれか一項に記載の移動体装置において、
前記複数の第1ヘッドは、前記所定平面内で前記第1方向と異なる方向を計測方向とする第1ヘッドを含み、
前記計測系は、前記計測方向が前記第1方向と異なる第1ヘッドを用いて前記移動体の位置情報を計測するために前記計測装置の計測情報を用いる移動体装置。 - 請求項14又は15に記載の移動体装置において、
前記複数の第1ヘッドは、前記第1方向を計測方向とする少なくとも2つの第1ヘッドと、前記第2方向を計測方向とする少なくとも2つの第1ヘッドと、を含む移動体装置。 - 請求項1~16のいずれか一項に記載の移動体装置において、
前記複数の第1ヘッドは、前記第2方向に関して前記第1移動体と相対移動可能である移動体装置。 - 請求項1~17のいずれか一項に記載の移動体装置において、
前記複数の第1ヘッドは、前記第1方向に関して、前記複数の格子領域のうち隣接する一対の格子領域の間隔よりも広い間隔で前記計測ビームを照射する2つの第1ヘッドと、前記第2方向に関して前記2つの第1ヘッドの少なくとも一方と前記計測ビームの位置が異なる少なくとも1つの第1ヘッドと、を含む移動体装置。 - 請求項1~18のいずれか一項に記載の移動体装置において、
前記複数の格子領域はそれぞれ、反射型の2次元格子あるいは互いに配列方向が異なる2つの1次元格子を有する移動体装置。 - 請求項1~19のいずれか一項に記載の移動体装置において、
前記格子部材は、前記複数の格子領域がそれぞれ形成される複数のスケールを有する移動体装置。 - 請求項1~20のいずれか一項に記載の移動体装置において、
前記計測系は、前記複数の第1ヘッドを前記第2方向に移動可能な駆動部を有し、
前記制御系は、前記移動体の移動中、前記計測系で計測に用いられる前記少なくとも3つの第1ヘッドでそれぞれ、前記第2方向に関して前記計測ビームが前記複数の格子領域から外れないように、前記駆動部を制御する移動体装置。 - 請求項1~21のいずれか一項に記載の移動体装置において、
前記計測系は、前記複数の第1ヘッドのうち1つ又は複数の第1ヘッドをそれぞれ保持して移動可能な複数の可動部を有し、前記計測装置によって前記複数の可動部でそれぞれ前記第1ヘッドの位置情報を計測する移動体装置。 - 請求項1~22のいずれか一項に記載の移動体装置において、
前記複数の第1ヘッドはそれぞれ、前記所定平面内で互いに交差する2方向の一方と、前記所定平面と直交する第3方向との2方向を計測方向とし、
前記計測系は、前記少なくとも3つの第1ヘッドを用いて、前記第3方向を含む、前記3自由度方向と異なる3自由度方向に関する前記移動体の位置情報を計測可能である移動体装置。 - 請求項1~23のいずれか一項に記載の移動体装置において、
前記複数の第1ヘッドは少なくとも4つの第1ヘッドを有し、
前記少なくとも4つの第1ヘッドのうち1つの第1ヘッドで前記計測ビームが前記複数の格子領域から外れている間、残りの少なくとも3つの第1ヘッドは前記計測ビームが前記複数の格子領域の少なくとも1つに照射されるとともに、前記第1方向への前記移動体の移動によって、前記少なくとも4つの第1ヘッドの中で前記計測ビームが前記複数の格子領域から外れる前記1つの第1ヘッドが切り換わる移動体装置。 - 請求項24に記載の移動体装置において、
前記少なくとも4つの第1ヘッドは、前記第1方向に関して互いに前記計測ビームの位置が異なる2つの第1ヘッドと、前記第2方向に関して前記2つの第1ヘッドの少なくとも一方と前記計測ビームの位置が異なるととともに、前記第1方向に関して互いに前記計測ビームの位置が異なる2つの第1ヘッドと、を含み、
前記2つの第1ヘッドは、前記第1方向に関して、前記複数の格子領域のうち隣接する一対の格子領域の間隔よりも広い間隔で前記計測ビームを照射する移動体装置。 - 請求項24又は25に記載の移動体装置において、
前記格子部材は、前記第2方向に関して互いに離れて配置される少なくとも2つの前記複数の格子領域を有し、
前記少なくとも4つの第1ヘッドは、前記少なくとも2つの前記複数の格子領域にそれぞれ、前記第1方向に関して互いに前記計測ビームの位置が異なる少なくとも2つの第1ヘッドを介して前記計測ビームを照射し、
前記少なくとも2つの第1ヘッドは、前記第1方向に関して、前記複数の格子領域のうち隣接する一対の格子領域の間隔よりも広い間隔で前記計測ビームを照射する移動体装置。 - 請求項26に記載の移動体装置において、
前記格子部材は、前記移動体に設けられ、前記複数の第1ヘッドは、前記移動体の上方に設けられ、
前記少なくとも2つの前記複数の格子領域は、前記第2方向に関して前記移動体の基板載置領域の両側に配置される一対の前記複数の格子領域を含む移動体装置。 - 請求項24~27のいずれか一項に記載の移動体装置において、
前記第1方向への前記移動体の移動において、前記少なくとも4つの第1ヘッドで前記計測ビームが前記複数の格子領域から外れる非計測区間が重ならない移動体装置。 - 請求項28に記載の移動体装置において、
前記複数の第1ヘッドは、前記少なくとも4つの第1ヘッドの少なくとも1つと前記非計測区間が少なくとも一部重なる少なくとも1つの第1ヘッドを含み、
前記移動体の位置情報の計測において、前記少なくとも4つの第1ヘッドと、前記少なくとも1つの第1ヘッドと、を含む少なくとも5つの第1ヘッドのうち、前記計測ビームが前記複数の格子領域の少なくとも1つに照射される少なくとも3つの第1ヘッドが用いられる移動体装置。 - 請求項24~29のいずれか一項に記載の移動体装置において、
前記制御系は、前記少なくとも4つの第1ヘッドのうち、前記計測ビームが前記1つの格子領域から外れて前記別の格子領域に乗り換える1つの第1ヘッドを用いて前記移動体の移動を制御するための補正情報を、残りの少なくとも3つの第1ヘッドの計測情報、あるいは前記残りの少なくとも3つの第1ヘッドを用いて計測される前記移動体の位置情報に基づいて取得する移動体装置。 - 請求項30に記載の移動体装置において、
前記補正情報は、前記少なくとも4つの第1ヘッドでそれぞれ前記計測ビームが前記複数の格子領域の少なくとも1つに照射されている間に取得される移動体装置。 - 請求項30又は31に記載の移動体装置において、
前記残りの少なくとも3つの第1ヘッドの1つで前記計測ビームが前記複数の格子領域の1つから外れる前に、前記残りの少なくとも3つの第1ヘッドの1つの代わりに、前記補正情報が取得された前記1つの第1ヘッドを含む少なくとも3つの第1ヘッドを用いて前記移動体の位置情報が計測される移動体装置。 - 請求項30~32のいずれか一項に記載の移動体装置において、
前記複数の第1ヘッドはそれぞれ、前記所定平面内で互いに交差する2方向の一方と、前記所定平面と直交する第3方向との2方向を計測方向とし、
前記計測系は、前記少なくとも3つの第1ヘッドを用いて、前記第3方向を含む、前記3自由度方向と異なる3自由度方向に関する前記移動体の位置情報を計測し、
前記制御系は、前記少なくとも4つの第1ヘッドのうち、前記計測ビームが前記1つの格子領域から外れて前記別の格子領域に乗り換える1つの第1ヘッドを用いて前記異なる3自由度方向に関する前記移動体の移動を制御するための補正情報を、残りの少なくとも3つの第1ヘッドの前記第3方向の計測情報、あるいは前記残りの少なくとも3つの第1ヘッドを用いて計測される前記第3方向に関する前記移動体の位置情報に基づいて取得する移動体装置。 - 請求項1~33の何れか一項に記載の移動体装置と、
前記物体に対してエネルギビームを照射し、前記物体を露光する光学系と、を備える露光装置。 - 請求項34に記載の露光装置において、
前記光学系を支持するフレーム部材を、さらに備え、
前記格子部材と前記複数の第1ヘッドとの他方は、前記フレーム部材に設けられる露光装置。 - 請求項35に記載の露光装置において、
前記計測系は、前記格子部材が前記移動体に設けられるとともに、前記複数の第1ヘッドが前記フレーム部材に設けられ、
前記計測装置は、前記第2ヘッドが前記複数の第1ヘッドに設けられるとともに、前記ケール部材が前記フレーム部材に設けられる露光装置。 - 請求項34~36のいずれか一項に記載の露光装置において、
前記基板は、前記移動体の開口内で保持され、
前記移動体および前記基板を浮上支持する支持部を有し、前記駆動系によって、前記浮上支持される基板を少なくとも前記3自由度方向に移動するステージシステムを、さらに備える露光装置。 - 請求項34~37のいずれか一項に記載の露光装置において、
照明光でマスクを照明する照明光学系を、さらに備え、
前記光学系は、それぞれ前記マスクのパターンの部分像を投影する複数の光学系を有する露光装置。 - 請求項38に記載の露光装置において、
前記基板は、前記光学系を介して前記照明光で走査露光され、
前記複数の光学系は、前記走査露光において前記基板が移動される走査方向と直交する方向に関して互いに位置が異なる複数の投影領域にそれぞれ前記部分像を投影する露光装置。 - 請求項34~39のいずれか一項に記載の露光装置において、
前記基板は、前記光学系を介して前記照明光で走査露光され、前記走査露光において前記第1方向に移動される露光装置。 - 請求項34~39のいずれか一項に記載の露光装置において、
前記基板は、前記光学系を介して前記照明光で走査露光され、前記走査露光において前記第2方向に移動される露光装置。 - 請求項34~41のいずれか一項に記載の露光装置において、
前記基板は、少なくとも一辺の長さ、または対角長が500mm以上であり、フラットパネルディスプレイ用である露光装置。 - フラットパネルディスプレイ製造方法であって、
請求項34~42のいずれか一項に記載の露光装置を用いて基板を露光することと、
前記露光された基板を現像することと、を含むフラットパネルディスプレイ製造方法。 - デバイス製造方法であって、
請求項34~43のいずれか一項に記載の露光装置を用いて基板を露光することと、
前記露光された基板を現像することと、を含むデバイス製造方法。 - 物体を保持する第1移動体を、互いに交差する第1方向と第2方向へ移動させることと、
第1計測系により、前記第1方向に関して複数の格子領域が互いに離れて配置され、前記第1および第2方向の計測成分を含む第1格子領域と、前記第1格子領域に対して前記第1方向へ移動しながら計測ビームを照射する複数の第1ヘッドとの一方が前記第1移動体に設けられ、前記複数の第1ヘッドのうち、前記計測ビームが前記複数の格子領域の少なくとも1つに照射される少なくとも3つの第1ヘッドにより計測される前記第1方向に関する前記第1移動体の位置情報を計測することと、
前記第1格子領域と前記複数の第1ヘッドとの他方に設けられた第2移動体により、前記第1移動体を前記第2方向へ移動させることと、
第2計測系により、前記第1および第2方向の計測成分を含む第2格子領域と、前記第2格子領域に対して前記第2方向へ移動しながら計測ビームを照射する第2ヘッドとの一方が前記第2移動体に設けられ、第2格子領域と前記第2格子領域との他方が前記第2移動体に対向するように設けられ、前記第2方向に関する前記第2移動体の位置情報を計測することと、
前記第1および第2計測系で計測される前記位置情報と、前記第1格子部材、前記複数の第1ヘッド、および前記第1移動体の移動の少なくもと1つに起因して生じる前記計測系の計測誤差を補償するための補正情報とに基づいて、前記第1および第2方向を含む所定平面内の3自由度方向に関する前記第1移動体の移動制御を行うことと、を含む移動方法。 - 請求項45に記載の移動方法により、前記物体を前記第1方向へ移動させることと、
前記第1方向へ移動された前記物体に対してエネルギビームを照射し、前記物体を露光することと、を含む露光方法。 - フラットパネルディスプレイ製造方法であって、
請求項46に記載の露光方法を用いて基板を露光することと、
前記露光された基板を現像することと、を含むフラットパネルディスプレイ製造方法。 - デバイス製造方法であって、
請求項46に記載の露光方法を用いて基板を露光することと、
前記露光された基板を現像することと、を含むデバイス製造方法。
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