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TWI600898B - Data correcting apparatus, drawing apparatus, inspection apparatus, data correcting method, drawing method, inspection method and recording medium carrying program - Google Patents

Data correcting apparatus, drawing apparatus, inspection apparatus, data correcting method, drawing method, inspection method and recording medium carrying program Download PDF

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Publication number
TWI600898B
TWI600898B TW105119609A TW105119609A TWI600898B TW I600898 B TWI600898 B TW I600898B TW 105119609 A TW105119609 A TW 105119609A TW 105119609 A TW105119609 A TW 105119609A TW I600898 B TWI600898 B TW I600898B
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Prior art keywords
etching
characteristic
data
pattern
abnormal
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TW105119609A
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Chinese (zh)
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TW201710673A (en
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清水嘉泰
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思可林集團股份有限公司
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    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03FPHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
    • G03F1/00Originals for photomechanical production of textured or patterned surfaces, e.g., masks, photo-masks, reticles; Mask blanks or pellicles therefor; Containers specially adapted therefor; Preparation thereof
    • G03F1/36Masks having proximity correction features; Preparation thereof, e.g. optical proximity correction [OPC] design processes
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03FPHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
    • G03F1/00Originals for photomechanical production of textured or patterned surfaces, e.g., masks, photo-masks, reticles; Mask blanks or pellicles therefor; Containers specially adapted therefor; Preparation thereof
    • G03F1/38Masks having auxiliary features, e.g. special coatings or marks for alignment or testing; Preparation thereof
    • G03F1/44Testing or measuring features, e.g. grid patterns, focus monitors, sawtooth scales or notched scales
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03FPHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
    • G03F1/00Originals for photomechanical production of textured or patterned surfaces, e.g., masks, photo-masks, reticles; Mask blanks or pellicles therefor; Containers specially adapted therefor; Preparation thereof
    • G03F1/68Preparation processes not covered by groups G03F1/20 - G03F1/50
    • G03F1/80Etching
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03FPHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
    • G03F7/00Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
    • G03F7/70Microphotolithographic exposure; Apparatus therefor
    • G03F7/70483Information management; Active and passive control; Testing; Wafer monitoring, e.g. pattern monitoring
    • G03F7/70605Workpiece metrology
    • G03F7/70616Monitoring the printed patterns
    • G03F7/7065Defects, e.g. optical inspection of patterned layer for defects
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03FPHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
    • G03F7/00Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
    • G03F7/70Microphotolithographic exposure; Apparatus therefor
    • G03F7/70483Information management; Active and passive control; Testing; Wafer monitoring, e.g. pattern monitoring
    • G03F7/70605Workpiece metrology
    • G03F7/706835Metrology information management or control
    • G03F7/706837Data analysis, e.g. filtering, weighting, flyer removal, fingerprints or root cause analysis
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03FPHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
    • G03F7/00Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
    • G03F7/70Microphotolithographic exposure; Apparatus therefor
    • G03F7/708Construction of apparatus, e.g. environment aspects, hygiene aspects or materials
    • G03F7/70808Construction details, e.g. housing, load-lock, seals or windows for passing light in or out of apparatus
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/02Manufacture or treatment of semiconductor devices or of parts thereof
    • H01L21/027Making masks on semiconductor bodies for further photolithographic processing not provided for in group H01L21/18 or H01L21/34
    • H01L21/0271Making masks on semiconductor bodies for further photolithographic processing not provided for in group H01L21/18 or H01L21/34 comprising organic layers
    • H01L21/0273Making masks on semiconductor bodies for further photolithographic processing not provided for in group H01L21/18 or H01L21/34 comprising organic layers characterised by the treatment of photoresist layers
    • H01L21/0274Photolithographic processes

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Public Health (AREA)
  • Epidemiology (AREA)
  • Environmental & Geological Engineering (AREA)
  • Condensed Matter Physics & Semiconductors (AREA)
  • Health & Medical Sciences (AREA)
  • Computer Hardware Design (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Power Engineering (AREA)
  • Data Mining & Analysis (AREA)
  • Exposure And Positioning Against Photoresist Photosensitive Materials (AREA)
  • Length Measuring Devices By Optical Means (AREA)
  • Investigating Materials By The Use Of Optical Means Adapted For Particular Applications (AREA)

Description

資料修正裝置、描繪裝置、檢查裝置、資料修正方法、描繪方法、檢查方法及記錄有程式之記錄媒體 Data correction device, drawing device, inspection device, data correction method, drawing method, inspection method, and recording medium on which the program is recorded

本發明係關於一種修正藉由蝕刻而於對象物上形成之圖案之設計資料之技術。 The present invention relates to a technique for correcting design information of a pattern formed on an object by etching.

過去以來,於印刷基板之製造步驟中,對以樹脂等絕緣材料形成之基板施加各種處理。例如,藉由於基板之表面上形成銅等之膜,且於該膜上形成抗蝕劑之圖案,進而施加蝕刻,而於基板上形成配線圖案。於蝕刻中,有時因圖案配置之疏密或圖案之大小等,而使形成於基板上之圖案之形狀與設計資料不同。 In the past, in the manufacturing process of a printed circuit board, various processes have been applied to a substrate formed of an insulating material such as a resin. For example, a wiring pattern is formed on a substrate by forming a film of copper or the like on the surface of the substrate, forming a pattern of a resist on the film, and further applying etching. In the etching, the shape of the pattern formed on the substrate may be different from the design data due to the density of the pattern arrangement or the size of the pattern.

於日本專利第3074675號公報中,揭示藉由以電子束直描裝置於基板上形成抗蝕劑圖案,並以電漿蝕刻裝置進行蝕刻而形成圖案之技術。又,提出有於根據圖案之設計資料產生電子束直描用資料之處理中,包含修正微負載效應所引起之蝕刻後之圖案尺寸變化之處理。 Japanese Patent No. 3074675 discloses a technique of forming a pattern by forming a resist pattern on a substrate by an electron beam direct drawing device and etching it by a plasma etching apparatus. Further, in the process of generating the electron beam direct drawing data based on the design data of the pattern, the process of correcting the pattern size change after etching caused by the micro load effect is proposed.

於日本專利第4274784號公報中,提出有使用蝕刻後之基板之圖像資料與設計資料以獲得所需之蝕刻後基板時,產生顯示需要如何修正設計資料之縮放規則(resizing rule)。 In Japanese Patent No. 4274784, it is proposed to use a picture material and design data of an etched substrate to obtain a desired etched substrate, and a resizing rule for displaying how to modify the design data is generated.

於日本專利特開2008-134512號公報中,揭示於製作光罩時,針對圖案間之每一空間(距離),指定用以修正過度蝕刻之修正值之方法。又,提出於直線圖案與圓弧圖案對向之情形時,對該對向之部位加以進一步之修正。 In Japanese Laid-Open Patent Publication No. 2008-134512, it is disclosed that a method for correcting the correction value of over-etching is specified for each space (distance) between the patterns when the photomask is produced. Further, when the straight line pattern and the circular arc pattern are opposed to each other, the opposing portion is further corrected.

於日本專利特開2013-12562號公報中,揭示於根據導體圖案之設計資料一面考慮側面蝕刻一面製成輪廓形狀(導體圖案之外形形狀)時,基於鄰接之輪廓形狀間之距離而設定修正值之技術。 In Japanese Patent Laid-Open Publication No. 2013-12562, it is disclosed that a correction value is set based on the distance between adjacent contour shapes when a contour shape (a conductor pattern outer shape) is formed in consideration of side etching according to design data of a conductor pattern. Technology.

日本專利特開2013-250101號公報係關於藉由蝕刻形成之配線圖案之缺陷檢查者。於該缺陷檢查中,藉由根據形成於基板之表面之測定用圖案測定蝕刻資訊(蝕刻曲線),並使用該蝕刻曲線對設計資料進行蝕刻模擬而產生檢查資料。然後,藉由對照基板上之配線圖案之圖像資料與檢查資料,而檢測配線圖案之缺陷。 Japanese Patent Laid-Open Publication No. 2013-250101 is a defect inspector regarding a wiring pattern formed by etching. In the defect inspection, the inspection information is generated by measuring the etching information (etching curve) based on the measurement pattern formed on the surface of the substrate, and etching the design data using the etching curve. Then, the defect of the wiring pattern is detected by comparing the image data of the wiring pattern on the substrate with the inspection data.

近幾年來,於進行對基板之蝕刻之裝置中,為提高生產性,而對配置有多個相同塊(圖案)之大型基板進行蝕刻。因此,依基板上之位置而蝕刻特性不同,從而即使為對相同塊之蝕刻,亦有蝕刻結果不同之情況。因此,考慮取得對於基板上之複數個位置之複數種蝕刻特性,並基於該等複數種蝕刻特性而修正設計資料。然而,不限於適當地取得所有蝕刻特性,亦有取得異常蝕刻特性之情況。於該情形時,設計資料之修正精度下降。 In recent years, in an apparatus for etching a substrate, in order to improve productivity, a large substrate in which a plurality of identical blocks (patterns) are arranged is etched. Therefore, depending on the position on the substrate, the etching characteristics are different, and even if the etching is performed on the same block, the etching result may be different. Therefore, it is considered to obtain a plurality of etching characteristics for a plurality of positions on the substrate, and to modify the design data based on the plurality of etching characteristics. However, it is not limited to obtaining all the etching characteristics properly, and it is also possible to obtain abnormal etching characteristics. In this case, the accuracy of the correction of the design data is degraded.

本發明有關於修正藉由蝕刻而於對象物上形成之圖案之設計資料之資料修正裝置,其目的在於更確實且精度良好地修正設計資料。 The present invention relates to a data correction device for correcting design data of a pattern formed on an object by etching, and an object thereof is to correct design data more reliably and accurately.

本發明之資料修正裝置包含:設計資料記憶部,其記憶藉由蝕刻而於對象物上形成之圖案之設計資料;蝕刻特性記憶部,其記憶對於上述對象物上之複數個對象位置之複數種蝕刻特性;異常特性檢測部,其藉由對各對象位置之蝕刻特性、與位於上述各對象位置的周圍 之對象位置群之蝕刻特性進行比較之檢測處理,而檢測特異之蝕刻特性作為異常蝕刻特性;特性置換部,其使用位於上述異常蝕刻特性之對象位置的周圍之對象位置群之蝕刻特性求出新的蝕刻特性,將上述異常蝕刻特性置換為上述新的蝕刻特性;及資料修正部,其基於對於上述複數個對象位置之複數種蝕刻特性而修正上述設計資料。 The data correction device of the present invention comprises: a design data storage unit that memorizes design data of a pattern formed on the object by etching; and an etching characteristic memory unit that memorizes a plurality of types of object positions on the object Etching characteristics; an abnormality detecting unit that is formed by etching characteristics of each object position and around each of the object positions The etching characteristics of the target position group are compared, and the specific etching characteristics are detected as abnormal etching characteristics. The characteristic replacing unit obtains new etching characteristics using the target position group located around the target position of the abnormal etching characteristics. The etching characteristic replaces the abnormal etching characteristic with the new etching characteristic; and the data correcting unit corrects the design data based on a plurality of etching characteristics of the plurality of object positions.

根據本發明,可藉由將異常蝕刻特性置換為新的蝕刻特性,而更確實且精度良好地修正設計資料。 According to the present invention, it is possible to correct the design data more reliably and accurately by replacing the abnormal etching characteristics with the new etching characteristics.

於本發明之一較佳形態中,於上述檢測處理中,求出基於使用位於上述各對象位置的周圍之對象位置群之蝕刻特性而取得之一蝕刻特性、與上述各對象位置之蝕刻特性之間之距離之判定值。 According to a preferred aspect of the present invention, in the detecting process, an etching characteristic obtained by using a target position group located around each of the target positions is obtained, and an etching characteristic and an etching characteristic of each of the target positions are obtained. The value of the distance between the two.

於該情形時,較佳為上述一蝕刻特性係藉由使用上述對象位置群之蝕刻特性之內插運算而對上述各對象位置取得。 In this case, it is preferable that the etching characteristic is obtained by the interpolation operation using the etching characteristics of the target position group.

於本發明之另一較佳形態中,上述異常特性檢測部係每當檢測出一異常蝕刻特性時,排除上述一異常蝕刻特性,且再次進行上述檢測處理,而檢測另一異常蝕刻特性。 In another preferred embodiment of the present invention, the abnormal characteristic detecting unit detects the abnormal etching characteristic, excludes the abnormal etching characteristic, and performs the detection processing again to detect another abnormal etching characteristic.

本發明亦有關在對象物上描繪圖案之描繪裝置。本發明之描繪裝置包含:上述之資料修正裝置;光源;光調變部,其基於藉由上述資料修正裝置修正後之設計資料而對來自上述光源之光進行調變;及掃描機構,其於對象物上掃描由上述光調變部調變後之光。 The present invention also relates to a drawing device for drawing a pattern on an object. The drawing device of the present invention comprises: the above-mentioned data correction device; a light source; a light modulation unit that modulates light from the light source based on design data corrected by the data correction device; and a scanning mechanism The object is scanned for light modulated by the light modulation unit.

本發明亦有關於檢查藉由蝕刻而於對象物上形成之圖案之檢查裝置。本發明之檢查裝置包含:上述之資料修正裝置;實際圖像記憶部,其記憶藉由蝕刻而於對象物上形成之圖案之圖像資料即檢查圖像資料;及缺陷檢測部,其藉由對利用上述資料修正裝置修正後之設計資料與上述檢查圖像資料進行比較,而檢測形成於上述對象物上之上述圖案之缺陷。 The present invention also relates to an inspection apparatus for inspecting a pattern formed on an object by etching. The inspection apparatus of the present invention includes: the above-described data correction device; an actual image storage unit that stores image data of a pattern formed on an object by etching, that is, inspection image data; and a defect detection unit by The design data corrected by the data correction device is compared with the inspection image data to detect a defect of the pattern formed on the object.

本發明亦有關於修正藉由蝕刻而於對象物上形成之圖案之設計 資料之資料修正方法、於對象物上描繪圖案之描繪方法、檢查藉由蝕刻而於對象物上形成之圖案之檢查方法、及記錄有程式之記錄媒體。 The invention also relates to a design for correcting a pattern formed on an object by etching. The data correction method of the data, the drawing method of drawing the pattern on the object, the inspection method of inspecting the pattern formed on the object by etching, and the recording medium on which the program is recorded.

上述之目的及其他目的、特徵、態樣及優點當可藉由參照附加圖式於以下進行之該發明之詳細說明而明瞭。 The above and other objects, features, aspects and advantages of the invention will be apparent from the accompanying drawings.

1‧‧‧描繪裝置 1‧‧‧Drawing device

1a‧‧‧檢查裝置 1a‧‧‧Inspection device

2‧‧‧資料處理裝置 2‧‧‧ data processing device

3‧‧‧曝光裝置 3‧‧‧Exposure device

8‧‧‧記錄媒體 8‧‧‧Recording media

9‧‧‧基板 9‧‧‧Substrate

9a‧‧‧測試基板 9a‧‧‧Test substrate

21‧‧‧資料修正裝置 21‧‧‧Data correction device

21a‧‧‧資料修正裝置 21a‧‧‧Data correction device

22‧‧‧資料轉換部 22‧‧‧Data Conversion Department

25‧‧‧實際圖像記憶部 25‧‧‧ Actual Image Memory Department

26‧‧‧缺陷檢測部 26‧‧‧Defect Detection Department

31‧‧‧描繪控制器 31‧‧‧Drawing controller

32‧‧‧載台 32‧‧‧ stage

33‧‧‧光出射部 33‧‧‧Lighting Department

35‧‧‧掃描機構 35‧‧‧Scanning agency

80‧‧‧程式 80‧‧‧ program

83‧‧‧設計圖案 83‧‧‧ design pattern

84‧‧‧塊圖案 84‧‧‧block pattern

93‧‧‧測試圖案 93‧‧‧ test pattern

95‧‧‧特性取得用圖案 95‧‧‧Characteristic acquisition pattern

96‧‧‧測定圖案 96‧‧‧Measurement pattern

201‧‧‧CPU 201‧‧‧CPU

202‧‧‧ROM 202‧‧‧ROM

203‧‧‧RAM 203‧‧‧RAM

204‧‧‧硬碟 204‧‧‧ Hard disk

205‧‧‧顯示器 205‧‧‧ display

206a‧‧‧鍵盤 206a‧‧‧ keyboard

206b‧‧‧滑鼠 206b‧‧‧mouse

207‧‧‧讀取/寫入裝置 207‧‧‧Read/write device

208‧‧‧通信部 208‧‧‧Communication Department

211‧‧‧設計資料記憶部 211‧‧‧Design Data Memory Department

212‧‧‧蝕刻特性記憶部 212‧‧‧ Etching Characteristics Memory

213‧‧‧異常特性檢測部 213‧‧‧Abnormal characteristic detection department

214‧‧‧特性置換部 214‧‧‧Characteristic Replacement Department

215‧‧‧特性組取得部 215‧‧‧ Characteristic Group Acquisition Department

217‧‧‧資料修正部 217‧‧‧ Data Correction Department

331‧‧‧光源 331‧‧‧Light source

332‧‧‧光調變部 332‧‧‧Light Modulation Department

951‧‧‧第1圖形要素群 951‧‧‧1st graphic element group

952‧‧‧第1圖形要素 952‧‧‧1st graphic element

953‧‧‧第2圖形要素群 953‧‧‧2nd graphic element group

954‧‧‧第2圖形要素 954‧‧‧2nd graphical element

A1‧‧‧矩形 A1‧‧‧Rectangle

D1‧‧‧距離 D1‧‧‧ distance

E‧‧‧蝕刻量 E‧‧‧etching amount

G‧‧‧間隙寬度 G‧‧‧ gap width

L‧‧‧蝕刻曲線 L‧‧‧etching curve

La‧‧‧蝕刻曲線 La‧‧‧etching curve

Lb‧‧‧參照蝕刻曲線 Lb‧‧‧ reference etching curve

P‧‧‧對象位置 P‧‧‧Target location

S11~S22‧‧‧步驟 S11~S22‧‧‧Steps

x‧‧‧方向 X‧‧‧ directions

y‧‧‧方向 Y‧‧‧ direction

圖1係顯示第1實施形態之描繪裝置之構成之圖。 Fig. 1 is a view showing the configuration of a drawing device according to the first embodiment.

圖2係顯示資料處理裝置之構成之圖。 Fig. 2 is a view showing the configuration of a data processing device.

圖3係顯示資料處理裝置之功能之方塊圖。 Figure 3 is a block diagram showing the function of the data processing apparatus.

圖4係顯示描繪裝置之描繪流程之圖。 Figure 4 is a diagram showing the depiction flow of the depiction device.

圖5係測試基板之俯視圖。 Figure 5 is a plan view of the test substrate.

圖6係放大顯示特性取得用圖案之一部分之圖。 Fig. 6 is a view showing a part of a pattern for obtaining characteristics.

圖7係放大顯示測定圖案之一部分之圖。 Fig. 7 is a view showing an enlarged portion of a measurement pattern.

圖8係顯示蝕刻曲線之圖。 Figure 8 is a diagram showing an etching curve.

圖9係顯示各特性組所包含之對象位置之圖。 Fig. 9 is a view showing the position of an object included in each characteristic group.

圖10係顯示設計圖案之圖。 Figure 10 is a diagram showing a design pattern.

圖11係顯示第2實施形態之檢查裝置之功能之方塊圖。 Fig. 11 is a block diagram showing the function of the inspection apparatus of the second embodiment.

圖12係顯示檢查裝置之檢查流程之一部分之圖。 Figure 12 is a diagram showing a part of the inspection flow of the inspection device.

圖1係顯示本發明之第1實施形態之描繪裝置1之構成之圖。描繪裝置1係藉由對設置於基板9表面之感光材料即抗蝕劑膜照射光,而於抗蝕劑膜上直接描繪電路圖案等圖像之直描裝置。基板9係例如由絕緣性材料形成,且於表面設置有銅等導電性材料之膜。基板9係用於製造印刷基板。對藉由描繪裝置1描繪圖案後之基板9,於基板處理裝置等(省略圖示)中實施顯影、蝕刻。藉此,在基板9上形成圖案。對基板9之蝕刻係例如藉由對基板9賦予蝕刻液而進行之濕蝕刻。另,作為對基板9之蝕刻,亦可進行例如利用電漿等之乾蝕刻。 Fig. 1 is a view showing the configuration of the drawing device 1 according to the first embodiment of the present invention. The drawing device 1 is a direct drawing device that directly draws an image such as a circuit pattern on a resist film by irradiating light onto a resist film which is a photosensitive material provided on the surface of the substrate 9. The substrate 9 is formed of, for example, an insulating material, and a film of a conductive material such as copper is provided on the surface. The substrate 9 is used to manufacture a printed substrate. The substrate 9 which has been patterned by the drawing device 1 is subjected to development and etching in a substrate processing apparatus or the like (not shown). Thereby, a pattern is formed on the substrate 9. The etching of the substrate 9 is wet etching by, for example, applying an etching liquid to the substrate 9. Further, as the etching of the substrate 9, dry etching using, for example, plasma may be performed.

描繪裝置1包含資料處理裝置2及曝光裝置3。資料處理裝置2修正於基板9上描繪之圖案之設計資料,而產生描繪資料。曝光裝置3基於自資料處理裝置2傳送來之描繪資料而進行對基板9之描繪(即曝光)。資料處理裝置2與曝光裝置3只要可進行兩裝置間之資料之授受,則亦可實體上分開,當然,亦可一體地設置。 The drawing device 1 includes a data processing device 2 and an exposure device 3. The data processing device 2 corrects the design data of the pattern drawn on the substrate 9 to generate the drawing material. The exposure device 3 performs drawing (i.e., exposure) of the substrate 9 based on the drawing data transmitted from the material processing device 2. The data processing device 2 and the exposure device 3 may be physically separated as long as the data between the two devices can be transferred, and of course, may be integrally provided.

圖2係顯示資料處理裝置2之構成之圖。資料處理裝置2係成為包含進行各種運算處理之CPU(Central Processing Unit:中央處理單元)201、記憶基本程式之ROM(Read Only Memory:唯讀記憶體)202、及記憶各種資訊之RAM(Random Access Memory:隨機存取記憶體)203之一般電腦系統之構成。資料處理裝置2進而包含:硬碟204,其進行資訊記憶;顯示器205,其進行圖像等各種資訊之顯示;鍵盤206a及滑鼠206b,其等接收來自操作者之輸入;讀取/寫入裝置207,其進行自光碟、磁碟、磁光碟等電腦可讀取之記錄媒體8之資訊之讀取及寫入;及通信部208,其於與描繪裝置1之其他構成等之間收發信號。 FIG. 2 is a view showing the configuration of the data processing device 2. The data processing device 2 includes a CPU (Central Processing Unit) 201 that performs various types of arithmetic processing, a ROM (Read Only Memory) 202 that stores a basic program, and a RAM that stores various kinds of information (Random Access). Memory: Random access memory) 203 is a general computer system. The data processing device 2 further includes: a hard disk 204 for performing information storage; a display 205 for displaying various information such as images; a keyboard 206a and a mouse 206b for receiving input from an operator; reading/writing The device 207 reads and writes information from a computer readable recording medium 8 such as a CD, a magnetic disk, or a magneto-optical disk; and the communication unit 208 transmits and receives signals between the other components of the drawing device 1 and the like. .

於資料處理裝置2中,於事前經由讀取/寫入裝置207自記錄媒體8讀出程式80並記憶至硬碟204。CPU201藉由按照程式80一面利用RAM203或硬碟204一面執行運算處理(即,藉由電腦執行程式),而實現後述之功能。 In the material processing device 2, the program 80 is read from the recording medium 8 via the reading/writing device 207 and memorized to the hard disk 204. The CPU 201 realizes a function to be described later by performing arithmetic processing (that is, executing a program by a computer) by using the RAM 203 or the hard disk 204 in accordance with the program 80.

圖3係顯示資料處理裝置2之功能之方塊圖。於圖3中,一併顯示連接於資料處理裝置2之曝光裝置3之構成之一部分(描繪控制器31)。資料處理裝置2包含資料修正裝置21與資料轉換部22。資料修正裝置21修正藉由蝕刻而於基板9上形成之圖案之設計資料。資料修正裝置21包含設計資料記憶部211、蝕刻特性記憶部212、異常特性檢測部213、特性置換部214、特性組取得部215、及資料修正部217。對資料轉換部22,輸入由資料修正裝置21修正後之設計資料(以下,稱為 「已修正資料」)。已修正資料通常為多邊形等矢量資料。資料轉換部22將為矢量資料即已修正資料轉換成為光柵資料即描繪資料。資料處理裝置2之功能既可藉由專用之電性電路實現,亦可部分使用專用之電性電路。 FIG. 3 is a block diagram showing the function of the data processing device 2. In Fig. 3, a part (the drawing controller 31) of the configuration of the exposure device 3 connected to the data processing device 2 is shown together. The data processing device 2 includes a material correction device 21 and a data conversion unit 22. The data correction device 21 corrects the design information of the pattern formed on the substrate 9 by etching. The data correction device 21 includes a design data storage unit 211, an etching characteristic storage unit 212, an abnormality characteristic detecting unit 213, a characteristic replacing unit 214, a characteristic group obtaining unit 215, and a material correcting unit 217. The data conversion unit 22 inputs design data corrected by the data correction device 21 (hereinafter referred to as "Fixed data"). The corrected data is usually vector data such as polygons. The data conversion unit 22 converts the corrected data, which is a vector data, into raster data, that is, rendering data. The function of the data processing device 2 can be realized by a dedicated electrical circuit, or a dedicated electrical circuit can be partially used.

如圖1所示,曝光裝置3包含描繪控制器31、載台32、光出射部33、及掃描機構35。描繪控制器31控制光出射部33及掃描機構35。載台32將基板9保持於光出射部33之下方。光出射部33具備光源331及光調變部332。光源331朝向光調變部332出射雷射光。光調變部332對來自光源331之光進行調變。將藉由光調變部332調變後之光照射於載台32上之基板9。作為光調變部332,例如使用將複數個光調變元件二維排列之DMD(Digital Mirror Device:數位鏡面器件)。光調變部332亦可為將複數個光調變元件一維排列之調變器等。 As shown in FIG. 1, the exposure device 3 includes a drawing controller 31, a stage 32, a light emitting portion 33, and a scanning mechanism 35. The drawing controller 31 controls the light emitting portion 33 and the scanning mechanism 35. The stage 32 holds the substrate 9 below the light exit portion 33. The light emitting portion 33 includes a light source 331 and a light modulation portion 332. The light source 331 emits laser light toward the light modulation portion 332. The light modulation unit 332 modulates the light from the light source 331. The light modulated by the light modulation unit 332 is irradiated onto the substrate 9 on the stage 32. As the optical modulation unit 332, for example, a DMD (Digital Mirror Device) in which a plurality of optical modulation elements are two-dimensionally arranged is used. The light modulation unit 332 may be a modulator or the like that arranges a plurality of optical modulation elements in one dimension.

掃描機構35使載台32於水平方向上移動。具體而言,藉由掃描機構35,使載台32於主掃描方向、及與主掃描方向垂直之副掃描方向移動,藉此,將藉由光調變部332調變後之光於基板9上沿主掃描方向及副掃描方向掃描。於曝光裝置3中,亦可設置使載台32水平地旋轉之旋轉機構。又,亦可設置使光出射部33於上下方向移動之升降機構。掃描機構35只要可於基板9上掃描來自光出射部33之光,則並非必須為使載台32移動之機構。例如,亦可藉由掃描機構35,使光出射部33於載台32之上方沿主掃描方向及副掃描方向移動。 The scanning mechanism 35 moves the stage 32 in the horizontal direction. Specifically, the scanning mechanism 35 moves the stage 32 in the main scanning direction and the sub-scanning direction perpendicular to the main scanning direction, thereby modulating the light modulated by the optical modulation unit 332 on the substrate 9. The upper side scans in the main scanning direction and the sub-scanning direction. In the exposure device 3, a rotation mechanism that rotates the stage 32 horizontally may be provided. Further, an elevating mechanism that moves the light emitting portion 33 in the vertical direction may be provided. The scanning mechanism 35 is not necessarily a mechanism for moving the stage 32 as long as it can scan the light from the light emitting portion 33 on the substrate 9. For example, the light emitting portion 33 may be moved above the stage 32 in the main scanning direction and the sub-scanning direction by the scanning mechanism 35.

其次,一面參照圖4,一面對描繪裝置1之描繪流程進行說明。首先,對於一主面上形成有抗蝕劑膜之測試用之基板(與後述之步驟S20中進行描繪之基板9相同形狀及大小,以下稱為「測試基板」),藉由曝光裝置3描繪特定之測試圖案。 Next, a description will be given of a drawing flow of the drawing device 1 with reference to FIG. First, a substrate for testing on which a resist film is formed on one main surface (the same shape and size as the substrate 9 drawn in step S20 to be described later, hereinafter referred to as "test substrate") is drawn by the exposure device 3. Specific test pattern.

圖5係顯示藉由曝光裝置3描繪測試圖案93後之測試基板9a之俯視圖。實際上,測試基板9a上之測試圖案93藉由施以顯影處理而可作為 抗蝕劑圖案被視認。此處,將圖5之測試圖案93之各圖形要素之位置、形狀、大小設為與測試圖案用之設計資料(但是,不進行使用資料修正裝置21之修正)所示之圖案嚴格一致者。即,圖5之測試圖案93係測試圖案用之設計資料所示之圖案本身。圖5之測試基板9a為矩形,且於圖5中,將於測試基板9a上沿著相互正交之2個邊之方向示為x方向及y方向。 FIG. 5 is a plan view showing the test substrate 9a after the test pattern 93 is drawn by the exposure device 3. In fact, the test pattern 93 on the test substrate 9a can be used as a development process. The resist pattern is visually recognized. Here, the position, shape, and size of each of the graphic elements of the test pattern 93 of FIG. 5 are set to exactly match the pattern shown in the design data for the test pattern (however, the correction using the data correction device 21 is not performed). That is, the test pattern 93 of Fig. 5 is the pattern itself shown in the design data for the test pattern. The test substrate 9a of FIG. 5 has a rectangular shape, and in FIG. 5, the direction of the two sides orthogonal to each other on the test substrate 9a is shown as the x direction and the y direction.

測試圖案93包含複數個特性取得用圖案95。於圖5中,以矩形顯示特性取得用圖案95。複數個特性取得用圖案95之各者係用以藉由顯影、蝕刻、抗蝕劑剝離等處理,而形成後述之測定圖案之描繪圖案。於圖5之例中,將複數個特性取得用圖案95於x方向及y方向按一定間距排列。將配置各特性取得用圖案95之位置(例如、該圖案之中央)P稱為「對象位置」,於測試基板9a上設定複數個對象位置P。測試基板9a上之對象位置P之個數為例如4個以上,較佳為9個以上。各特性取得用圖案95包含複數個圖形要素。於圖5中顯示特性取得用圖案95之矩形係包含該等複數個圖形要素全部之大致最小之矩形。 The test pattern 93 includes a plurality of patterns 95 for obtaining characteristics. In FIG. 5, the characteristic acquisition pattern 95 is shown in a rectangle. Each of the plurality of characteristic obtaining patterns 95 is used to form a drawing pattern of a measurement pattern to be described later by processing such as development, etching, and resist stripping. In the example of FIG. 5, a plurality of characteristic acquisition patterns 95 are arranged at a constant pitch in the x direction and the y direction. The position (for example, the center of the pattern) P at which each characteristic acquisition pattern 95 is placed is referred to as a "target position", and a plurality of object positions P are set on the test substrate 9a. The number of object positions P on the test substrate 9a is, for example, four or more, and preferably nine or more. Each of the characteristic acquisition patterns 95 includes a plurality of graphic elements. The rectangle in which the characteristic acquisition pattern 95 is shown in FIG. 5 includes a rectangle having substantially the smallest of all of the plurality of graphic elements.

圖6係放大顯示特性取得用圖案95之一部分之圖。於圖6所示之例中,特性取得用圖案95包含複數個第1圖形要素群951。各第1圖形要素群951包含相互平行地大致於y方向延伸之2條大致直線狀之第1圖形要素952。各第1圖形要素群951之2條第1圖形要素952間之間隙寬度G(即2條第1圖形要素952之與長度方向垂直之x方向之間隙之寬度)與其他第1圖形要素群951之2條第1圖形要素952間之間隙寬度G不同。 Fig. 6 is a view showing a part of the characteristic obtaining pattern 95 in an enlarged manner. In the example shown in FIG. 6, the characteristic acquisition pattern 95 includes a plurality of first graphic element groups 951. Each of the first pattern element groups 951 includes two first linear element elements 952 extending substantially parallel to each other in the y direction. The gap width G between the two first pattern elements 952 of each of the first pattern element groups 951 (that is, the width of the gap between the two first pattern elements 952 perpendicular to the longitudinal direction in the x direction) and the other first pattern element group 951 The gap width G between the two first graphic elements 952 is different.

藉由對測試基板9a之顯影處理,而於測試基板9a上形成顯示測試圖案93之抗蝕劑圖案。接著,藉由對測試基板9a,以該抗蝕劑圖案為遮罩實施蝕刻,進而實施抗蝕劑剝離等處理,而於測試基板9a之主面形成顯示複數個特性取得用圖案95之複數個測定圖案。 A resist pattern showing the test pattern 93 is formed on the test substrate 9a by development processing on the test substrate 9a. Then, by etching the resist pattern as a mask on the test substrate 9a, and performing a process such as resist peeling, a plurality of patterns for displaying a plurality of characteristics are formed on the main surface of the test substrate 9a. The pattern was measured.

圖7係放大顯示與特性取得用圖案95對應之測定圖案96之一部分 之圖。測定圖案96包含分別顯示複數個第1圖形要素群951之複數個第2圖形要素群953。於圖7中,放大顯示1個第2圖形要素群953。各第2圖形要素群953包含與2條第1圖形要素952對應之大致直線狀之2條第2圖形要素954。第2圖形要素954係利用抗蝕劑圖案之第1圖形要素952之部位藉由蝕刻形成者。於圖7中,以二點鏈線一併顯示第1圖形要素952之輪廓線。 FIG. 7 is an enlarged view showing a part of the measurement pattern 96 corresponding to the characteristic obtaining pattern 95. Picture. The measurement pattern 96 includes a plurality of second graphic element groups 953 that respectively display a plurality of first graphic element groups 951. In FIG. 7, one second graphic element group 953 is enlarged. Each of the second graphic element groups 953 includes two second graphic elements 954 that are substantially linear in shape corresponding to the two first graphic elements 952. The second pattern element 954 is formed by etching using a portion of the first pattern element 952 of the resist pattern. In FIG. 7, the outline of the first graphic element 952 is displayed together with a two-dot chain line.

此處,將各第2圖形要素群953之形成2條第2圖形要素954間之間隙之各第2圖形要素954之邊(輪廓線之部位)、與對應於該邊之第1圖形要素952之邊之間之距離(與形成該間隙之輪廓線之部位垂直之方向之距離)稱為蝕刻量E。蝕刻量E表示該2條第2圖形要素954間之間隙之第2圖形要素954之邊相對於各第1圖形要素952之邊之移動量(輪廓線之單側之變細量)。蝕刻量E依存於與該等2條第2圖像要素954對應之2條第1圖形要素952間之間隙寬度G而變化。間隙寬度G與蝕刻量E之關係係藉由拍攝測試基板9a而取得測定圖案96之圖像,並比較該圖像、與特性取得用圖案95之設計資料而取得。 Here, the side (the portion of the outline) of each of the second pattern elements 954 forming the gap between the two second pattern elements 954 in each of the second pattern element groups 953 and the first pattern element 952 corresponding to the side The distance between the sides (the distance in the direction perpendicular to the portion where the outline of the gap is formed) is referred to as the etching amount E. The etching amount E indicates the amount of movement of the side of the second pattern element 954 between the two second pattern elements 954 with respect to the side of each of the first pattern elements 952 (the amount of variation of one side of the contour line). The etching amount E changes depending on the gap width G between the two first pattern elements 952 corresponding to the two second image elements 954. The relationship between the gap width G and the etching amount E is obtained by taking an image of the measurement pattern 96 by photographing the test substrate 9a, and comparing the image with the design data of the characteristic acquisition pattern 95.

圖8係顯示表示間隙寬度G與蝕刻量E之關係之蝕刻曲線之圖。於圖8中,以實線顯示9個蝕刻曲線L(對以粗實線顯示之1條蝕刻曲線標註符號La)。於蝕刻曲線L中,作為整體之傾向係隨著間隙寬度G變小而蝕刻量E亦逐漸變小。又,雖於間隙寬度G某一程度大之範圍內,蝕刻量E與間隙寬度G大致成正比,但若間隙寬度G變小,則相對於間隙寬度G之減少而蝕刻量E急遽減少。換言之,若間隙寬度G變小,則蝕刻曲線L之斜率變大。 Fig. 8 is a view showing an etching curve showing the relationship between the gap width G and the etching amount E. In Fig. 8, nine etching curves L are shown in solid lines (the symbol La is indicated for one etching curve shown by a thick solid line). In the etching curve L, as a whole, the etching amount E gradually decreases as the gap width G becomes smaller. Further, although the etching amount E is substantially proportional to the gap width G within a certain range of the gap width G, when the gap width G is small, the etching amount E is drastically reduced with respect to the decrease in the gap width G. In other words, if the gap width G becomes small, the slope of the etching curve L becomes large.

於複數個特性取得用圖案95中,因於測試基板9a上之位置(即對象位置P)不同,故蝕刻曲線L之形狀或各間隙寬度G之蝕刻量E之大小相互不同。於本處理例中,自複數個特性取得用圖案95分別取得複數條蝕刻曲線。換言之,對於複數個對象位置P取得複數條蝕刻曲線。 另,於圖8中,藉由將各特性取得用圖案95所包含之複數個第1圖形要素群951之間隙寬度G之蝕刻量E以直線連結而顯示蝕刻曲線L。於本實施形態中,於複數個特性取得用圖案95中,測定蝕刻量E之間隙寬度G之大小或個數不同。 In the plurality of characteristic obtaining patterns 95, since the position on the test substrate 9a (that is, the target position P) is different, the shape of the etching curve L or the etching amount E of each gap width G is different from each other. In the present processing example, a plurality of etching patterns are obtained from the plurality of characteristic obtaining patterns 95, respectively. In other words, a plurality of etching curves are obtained for a plurality of object positions P. In addition, in FIG. 8, the etching curve L is displayed by connecting the etching amount E of the gap width G of the plurality of first pattern element groups 951 included in each of the characteristic obtaining patterns 95 by a straight line. In the present embodiment, the magnitude or the number of the gap widths G of the etching amount E is different in the plurality of characteristic obtaining patterns 95.

特性取得用圖案95亦可包含矩形以外之各種形狀之圖形要素及各種組合之圖形要素群。例如,亦可於特性取得用圖案95包含直徑不同之複數個圓形圖形要素,而取得表示圓形圖形要素之直徑與蝕刻量之關係之蝕刻曲線。針對此種蝕刻曲線之種類,亦可取得與複數個對象位置P分別對應之複數條蝕刻曲線。於以下之說明中,將對於測試基板9a及基板9上之各對象位置P之1條或複數條蝕刻曲線統稱為「蝕刻特性」。蝕刻特性典型而言,係表示於設計資料所示之圖案中相互鄰接之圖形要素間之間隙(設計間隙)之寬度、與藉由蝕刻形成之圖案之該圖形要素間之間隙(實際間隙)之寬度之關係。 The feature acquisition pattern 95 may also include graphic elements of various shapes other than a rectangle and a group of graphic elements of various combinations. For example, the characteristic acquisition pattern 95 may include a plurality of circular pattern elements having different diameters, and an etching curve indicating the relationship between the diameter of the circular pattern element and the etching amount may be obtained. For the type of the etching curve, a plurality of etching curves corresponding to the plurality of object positions P may be obtained. In the following description, one or a plurality of etching curves of the respective target positions P on the test substrate 9a and the substrate 9 are collectively referred to as "etching characteristics". The etching characteristics are typically represented by the width of the gap (design gap) between the pattern elements adjacent to each other in the pattern shown in the design data, and the gap (actual gap) between the pattern elements of the pattern formed by etching. The relationship between widths.

於描繪裝置1中,將對於各對象位置P之1或複數條蝕刻曲線記憶於蝕刻特性記憶部212。即,將對於複數個對象位置P之複數種蝕刻特性記憶於蝕刻特性記憶部212,而針對後述之處理進行準備(步驟S11)。另,複數種蝕刻特性既可於描繪裝置1以外之裝置中取得,亦可於描繪裝置1中取得。於描繪裝置1中進行蝕刻特性之取得之情形時,於描繪裝置1中,設置取得測定圖案96(參照圖7)之圖像的攝像部、及基於測定圖案96之圖像與特性取得用圖案95(參照圖6)之設計資料求出各對象位置P之蝕刻特性之蝕刻特性運算部(於第2實施形態之檢查裝置1a中相同)。 In the drawing device 1, one or a plurality of etching curves for each object position P are stored in the etching characteristic storage portion 212. In other words, a plurality of etching characteristics for a plurality of object positions P are stored in the etching characteristic storage unit 212, and preparation is performed for a process to be described later (step S11). Further, a plurality of etching characteristics may be obtained in a device other than the drawing device 1 or in the drawing device 1. When the drawing device 1 acquires the etching characteristics, the drawing device 1 is provided with an image capturing unit that acquires an image of the measurement pattern 96 (see FIG. 7), and an image and characteristic acquisition pattern based on the measurement pattern 96. The design data of 95 (see FIG. 6) is used to obtain an etching characteristic calculation unit for etching characteristics of each target position P (the same as in the inspection apparatus 1a of the second embodiment).

於異常特性檢測部213中,對於各對象位置P求出蝕刻特性之判定值(步驟S12)。例如,於以一對象位置P為注目對象位置P,對注目對象位置P之蝕刻特性之判定值之算出中,首先,特定出位於注目對象位置P的周圍之複數個對象位置P作為參照對象位置群。參照對象位 置群係例如距注目對象位置P之距離最近之特定數量(例如為8~20個,較其他對象位置P之總數足夠小之數量)之對象位置P之集合,且不包含注目對象位置P。參照對象位置群亦可為以注目對象位置P為中心之特定半徑之圓所包含之所有對象位置P之集合、或相對於注目對象位置P於(+x)側、(+y)側、(-x)側及(-y)側之各者相鄰之特定數量之對象位置P之集合等。 The abnormality detecting unit 213 obtains a determination value of the etching characteristic for each target position P (step S12). For example, in the calculation of the determination value of the etching characteristic of the target position P by the target position P, the first object position P located around the target position P is specified as the reference position. group. Reference object bit The group is, for example, a set of object positions P that are closest to the distance from the target position P (for example, 8 to 20, which is sufficiently smaller than the total number of other object positions P), and does not include the target position P. The reference object position group may be a set of all object positions P included in a circle having a specific radius centered on the target position P, or a (+x) side, (+y) side with respect to the target position P ( A set of a certain number of object positions P adjacent to each of the -x) side and the (-y) side.

接著,基於參照對象位置群之蝕刻特性,推定對於注目對象位置P之蝕刻特性。如已敘述般,雖亦於注目對象位置P由測定圖案96之測定取得蝕刻特性,但此處,對於注目對象位置P,取得僅基於位於注目對象位置P之周圍之參照對象位置群之蝕刻特性而推定之蝕刻特性(於後述之處理所參照之蝕刻特性,以下稱為「參照蝕刻特性」)。於以下之說明中,將參照對象位置群中所含之對象位置P稱為「參照對象位置P」。 Next, based on the etching characteristics of the reference target position group, the etching characteristics for the target position P are estimated. As described above, although the etching characteristics are obtained by the measurement of the measurement pattern 96 at the target position P, the etching characteristic of the reference target position group based only on the position of the target object P is obtained for the target position P. The estimated etching characteristics (etching characteristics referred to in the processing to be described later are hereinafter referred to as "reference etching characteristics"). In the following description, the target position P included in the reference target position group is referred to as "reference target position P".

參照蝕刻特性係基於注目對象位置P與參照對象位置群中所含之複數個參照對象位置P之位置關係,對於該等複數個參照對象位置P之複數種蝕刻特性進行加權,而基於經進行加權之複數種蝕刻特性求出。又,對該等複數種蝕刻特性之加權係例如將基於與各蝕刻特性對應之參照對象位置P與注目對象位置P之間之距離之加權係數乘以該蝕刻特性而進行。 The reference etching characteristic is based on the positional relationship between the target object position P and the plurality of reference object positions P included in the reference target position group, and weights the plurality of etching characteristics of the plurality of reference object positions P based on the weighting A plurality of etching characteristics are obtained. Further, the weighting of the plurality of etching characteristics is performed, for example, by multiplying the weighting coefficient based on the distance between the reference target position P and the target position P corresponding to each etching characteristic by the etching characteristic.

此處,藉由2維薄板樣條內插,一面進行對參照對象位置P之蝕刻特性之蝕刻曲線之加權,一面求出注目對象位置P之參照蝕刻特性之蝕刻曲線(以下,稱為「參照蝕刻曲線」)。於以下之說明中,為便於理解,對於注目對象位置P,特定出包圍注目對象位置P之4個參照對象位置P(形成於內部包含注目對象位置P之矩形之4個參照對象位置P),並將該等4個參照對象位置P設為分別位於以注目對象位置P為原點之xy座標平面內之第1至第4象限者。 Here, by performing the weighting of the etching curve of the etching characteristic of the reference target position P by the interpolation of the two-dimensional thin plate spline, the etching curve of the reference etching characteristic of the target position P is obtained (hereinafter referred to as "reference" Etching curve"). In the following description, for the purpose of understanding, the four reference object positions P (the four reference object positions P formed in the rectangle including the target position P) are specified for the target position P. The four reference object positions P are set to be in the first to fourth quadrants in the xy coordinate plane whose origin is the origin of the target position P.

參照蝕刻曲線之取得,首先,藉由基於注目對象位置P、與該等4個參照對象位置P中之(+y)側之2個參照對象位置P之間之x方向之距離,對(+y)側之2個參照對象位置P之蝕刻曲線進行線性內插,而求出第1內插蝕刻曲線。具體而言,若將上述2個參照對象位置P中之一參照對象位置P與注目對象位置P之間之x方向之距離設為d1,並將另一參照對象位置P與注目對象位置P之間之x方向之距離設為d2,則將(d2/(d1+d2))作為加權係數與該一參照對象位置P之蝕刻曲線(之蝕刻量)相乘。又,將(d1/(d1+d2))作為加權係數與該另一參照對象位置P之蝕刻曲線相乘。然後,藉由將對於2條蝕刻曲線之相乘結果相加,而求出第1內插蝕刻曲線。 With reference to the acquisition of the etching curve, first, by the distance between the target position P and the two reference object positions P on the (+y) side of the four reference object positions P, (+ The etch curve of the two reference object positions P on the y side is linearly interpolated to obtain a first interpolation etch curve. Specifically, the distance between the reference target position P and the target target position P in the x direction is set to d1, and the other reference target position P and the target position P are set. When the distance between the x directions is d2, (d2/(d1+d2)) is multiplied by the etching coefficient (the etching amount) of the reference object position P as a weighting coefficient. Further, (d1/(d1+d2)) is multiplied by the etching coefficient of the other reference object position P as a weighting coefficient. Then, the first interpolation etching curve is obtained by adding the multiplication results for the two etching curves.

同樣,藉由基於上述注目對象位置P、與上述4個參照對象位置P中之(-y)側之2個參照對象位置P之間之x方向之距離,對(-y)側之2個參照對象位置P之蝕刻曲線進行線性內插,而求出第2內插蝕刻曲線。具體而言,若將上述2個參照對象位置P中之一參照對象位置P與注目對象位置P之間之x方向之距離設為d3,並將另一參照對象位置P與注目對象位置P之間之x方向之距離設為d4,則將(d4/(d3+d4))作為加權係數與該一參照對象位置P之蝕刻曲線相乘。又,將(d3/(d3+d4))作為加權係數與該另一參照對象位置P之蝕刻曲線相乘。然後,藉由將對2條蝕刻曲線之相乘結果相加,而求出第2內插蝕刻曲線。 Similarly, by the distance between the above-mentioned target position P and the two reference object positions P on the (-y) side of the four reference target positions P, the two on the (-y) side are The second interpolation etch curve is obtained by linearly interpolating the etching curve of the reference object position P. Specifically, the distance between the reference target position P and the target target position P in the x direction is set to d3, and the other reference target position P and the target position P are set. When the distance between the x directions is d4, (d4/(d3+d4)) is multiplied by the etching curve of the reference object position P as a weighting coefficient. Further, (d3/(d3+d4)) is multiplied by the etching coefficient of the other reference object position P as a weighting coefficient. Then, the second interpolation etching curve is obtained by adding the multiplication results of the two etching curves.

隨後,藉由基於注目對象位置P、與上述4個參照對象位置P中之(-x)側或(+x)側之2個參照對象位置P之間之y方向之距離,對第1內插蝕刻曲線及第2內插蝕刻曲線進行線性內插,而取得參照蝕刻曲線。具體而言,若將上述2個參照對象位置P中之(+y)側之參照對象位置P與注目對象位置P之間之y方向之距離設為d5,並將(-y)側之參照對象位置P與注目對象位置P之間之y方向之距離設為d6,則將(d6/(d5+d6))作為加權係數與第1內插蝕刻曲線相乘。又,將(d5/(d5+d6))作為加權 係數與第2內插蝕刻曲線相乘。然後,藉由將對2條內插蝕刻曲線之相乘結果相加(即,基於經進行上述加權之複數條蝕刻曲線),而求出參照蝕刻曲線。另,參照蝕刻曲線亦可藉由其他內插運算求出。 Then, by the distance between the target position P and the y direction between the two reference object positions P on the (-x) side or the (+x) side of the four reference object positions P, the first inner The interpolation etch curve and the second interpolation etch curve are linearly interpolated to obtain a reference etch curve. Specifically, the distance between the reference target position P on the (+y) side of the two reference target positions P and the target target position P in the y direction is d5, and the reference to the (-y) side is used. When the distance between the object position P and the target position P in the y direction is d6, (d6/(d5+d6)) is multiplied by the first interpolation etching curve as a weighting coefficient. Also, (d5/(d5+d6)) is used as the weighting The coefficient is multiplied by the second interpolated etch curve. Then, the reference etching curve is obtained by adding the multiplication results of the two interpolation etching curves (that is, based on the plurality of etching curves subjected to the above-described weighting). In addition, the reference etching curve can also be obtained by other interpolation operations.

若已對注目對象位置P取得參照蝕刻曲線,則求出由對注目對象位置P之測定圖案96之測定所得之蝕刻曲線、與參照蝕刻曲線之間之離散度。例如,於預定之複數個間隙寬度G之各者中,求出由測定所得之蝕刻曲線與參照蝕刻曲線之蝕刻量E之差(絕對值)。然後,將複數個間隙寬度G之該差之最大值作為兩蝕刻曲線之離散度求出。 When the reference etching curve is acquired for the target position P, the dispersion between the etching curve obtained by measuring the measurement pattern 96 of the target position P and the reference etching curve is obtained. For example, the difference (absolute value) between the etching curve obtained by the measurement and the etching amount E of the reference etching curve is obtained for each of the predetermined plurality of gap widths G. Then, the maximum value of the difference of the plurality of gap widths G is obtained as the dispersion of the two etching curves.

於圖8之例中,以標註符號La之粗實線顯示之由測定所得之蝕刻曲線、與以標註符號Lb之虛線顯示之參照蝕刻曲線之間之離散度成為以標註符號D1之箭頭所示之距離。另,蝕刻曲線La與其他蝕刻曲線L相比成為歪扭形狀,其原因認為係例如於特性取得用圖案95之描繪時、或測定圖案96之蝕刻時、或測定時之誤差等。 In the example of FIG. 8, the dispersion between the measured etching curve indicated by the thick solid line of the symbol La and the reference etching curve indicated by the dotted line of the reference symbol Lb is indicated by the arrow indicated by the symbol D1. The distance. Further, the etching curve La has a twisted shape as compared with the other etching curve L, and is considered to be, for example, a drawing of the characteristic obtaining pattern 95, an etching of the measurement pattern 96, or an error in measurement.

如圖8之例,於由測定得出之蝕刻曲線La包含相對於參照蝕刻曲線Lb離散之蝕刻量E之情形時,上述離散度變大。參照蝕刻曲線Lb係基於參照對象位置群之蝕刻曲線,認為對注目對象位置P而言最合理之蝕刻曲線,包含相對於參照蝕刻曲線Lb離散之蝕刻量E之蝕刻曲線La可說是與參照對象位置群之蝕刻曲線相比而較特異之蝕刻曲線。特異之蝕刻曲線典型而言與參照對象位置群之蝕刻曲線相比具有異常之形狀。亦可將與參照對象位置群之蝕刻曲線相比,整體之蝕刻量E大為不同者設為特異之蝕刻曲線。另,於離散度之算出中,求出上述差之複數個間隙寬度G之個數(樣本數)及值可任意決定,並非必須與測試圖案93之第1圖形要素952間之間隙寬度G一致。於蝕刻曲線中,與第1圖形要素952間之間隙寬度G不同之間隙寬度之蝕刻量可藉由各種內插運算求出。 As an example of FIG. 8, when the etching curve La obtained by the measurement includes the etching amount E which is discrete with respect to the reference etching curve Lb, the dispersion becomes large. The reference etching curve Lb is based on the etching curve of the reference target position group, and it is considered that the etching curve which is the most reasonable for the target position P, and the etching curve La including the etching amount E which is discrete with respect to the reference etching curve Lb, can be said to be the reference object. The etching curve of the position group is more specific than the etching curve. The specific etching curve typically has an abnormal shape compared to the etching curve of the reference object position group. It is also possible to set a specific etching curve as compared with the etching curve of the reference target position group, in which the overall etching amount E is different. Further, in the calculation of the dispersion, the number (sample number) and the value of the plurality of gap widths G for which the difference is obtained can be arbitrarily determined, and it is not necessary to match the gap width G between the first pattern elements 952 of the test pattern 93. . In the etching curve, the etching amount of the gap width different from the gap width G between the first pattern elements 952 can be obtained by various interpolation calculations.

於蝕刻特性僅包含一種蝕刻曲線之情形時,該離散度成為對於 注目對象位置P之蝕刻特性之判定值。於蝕刻特性包含複數種蝕刻曲線之情形時,針對所有蝕刻曲線之種類,進行與上述相同之處理,而複數種蝕刻曲線之該離散度之和、平均值、最大值等成為上述判定值。 In the case where the etching characteristic contains only one etching curve, the dispersion becomes The judgment value of the etching characteristic of the target position P is noted. In the case where the etching characteristics include a plurality of etching curves, the same processing as described above is performed for the types of all the etching curves, and the sum of the dispersions, the average value, the maximum value, and the like of the plurality of etching curves become the above-described determination values.

於異常特性檢測部213中,以各對象位置P作為注目對象位置P,反復進行上述處理,而取得對於所有對象位置P之蝕刻特性之判定值。與各對象位置P之周圍之參照對象位置群之蝕刻特性相比,由該對象位置P之測定得出之蝕刻特性之特異性程度越高,該對象位置P之蝕刻特性之判定值越大。 In the abnormality detecting unit 213, the above-described processing is repeated with each target position P as the target position P, and the determination value of the etching characteristics for all the target positions P is obtained. The higher the specificity of the etching characteristic obtained by the measurement of the target position P, the higher the determination value of the etching characteristic of the target position P, as compared with the etching characteristic of the reference target position group around the target position P.

接著,將對於所有對象位置P之蝕刻特性之判定值之中之最大判定值與特定閾值進行比較。於最大判定值大於閾值之情形時(步驟S13),將最大判定值之蝕刻特性(由測定得出之蝕刻特性)檢測為異常蝕刻特性。如此,上述步驟S12、S13之處理係與參照對象位置群之蝕刻特性比較而檢測出特異之蝕刻特性作為異常蝕刻特性的檢測處理。如已敘述般,於上述步驟S12之處理中,基於與使用各對象位置P之蝕刻特性、與參照對象位置群之蝕刻特性而取得之參照蝕刻特性之差(比較)而取得判定值。因此,可以說於上述檢測處理中,實質上比較各對象位置P之蝕刻特性、與對應於該對象位置P之參照對象位置群之蝕刻特性。 Next, the largest determination value among the determination values of the etching characteristics of all the object positions P is compared with a specific threshold. When the maximum determination value is larger than the threshold value (step S13), the etching characteristic of the maximum determination value (the etching characteristic obtained by the measurement) is detected as the abnormal etching characteristic. As described above, in the processing of steps S12 and S13 described above, the specific etching characteristics are detected as the detection processing of the abnormal etching characteristics in comparison with the etching characteristics of the reference target position group. As described above, in the processing of the above-described step S12, the determination value is obtained based on the difference (comparison) with the reference etching characteristics obtained by using the etching characteristics of the respective target positions P and the etching characteristics of the reference target position group. Therefore, it can be said that in the above-described detection processing, the etching characteristics of the respective target positions P and the etching characteristics of the reference target position groups corresponding to the target position P are substantially compared.

若於異常特性檢測部213中,檢測出異常蝕刻特性,則自檢測處理之處理對象排除異常蝕刻特性(步驟S14)。接著,以與上述處理相同之方式求出當前之處理對象所包含之所有蝕刻特性、即除異常蝕刻特性以外之所有蝕刻特性之判定值(步驟S12)。然後,於最大判定值大於閾值之情形時(步驟S13),將最大判定值之蝕刻特性檢測為異常蝕刻特性,而自檢測處理之處理對象排除(步驟S14)。如此,於步驟S12~S14中,於檢測處理中,每當檢測出一異常蝕刻特性時,即自處 理對象排除該異常蝕刻特性,且再次進行檢測處理,而檢測另一異常蝕刻特性。 When the abnormality detecting unit 213 detects the abnormal etching characteristic, the abnormal etching characteristic is excluded from the processing target of the detection processing (step S14). Next, in the same manner as the above-described processing, all the etching characteristics included in the current processing target, that is, the determination values of all the etching characteristics except the abnormal etching characteristics are obtained (step S12). Then, when the maximum determination value is larger than the threshold value (step S13), the etching characteristic of the maximum determination value is detected as the abnormal etching characteristic, and the processing target of the self-detection processing is excluded (step S14). Thus, in steps S12 to S14, in the detection process, whenever an abnormal etching characteristic is detected, The object is excluded from the abnormal etching characteristic, and the detection process is performed again, and another abnormal etching characteristic is detected.

於步驟S13中,於最大判定值為閾值以下之情形時,藉由特性置換部214,對各異常蝕刻特性之對象位置P求出新的蝕刻特性。具體而言,使用位於各異常蝕刻特性之對象位置P周圍之對象位置群之蝕刻特性,藉由與上述參照蝕刻特性之取得相同之內插運算,求出新的蝕刻特性(如後述般,由於為異常蝕刻特性之替代蝕刻特性,故以下,亦稱為「替代蝕刻特性」)。此時,由於異常蝕刻特性之對象位置P未包含於該對象位置群,故於替代蝕刻特性之算出,不使用異常蝕刻特性。另,上述對象位置群之個數係較其他對象位置P之總數足夠小之數量,亦可與取得參照蝕刻特性時之參照對象位置群所包含之對象位置P之個數不同。 In the case where the maximum determination value is equal to or less than the threshold value in step S13, the characteristic replacing unit 214 obtains new etching characteristics for the target position P of each abnormal etching characteristic. Specifically, the etching characteristics of the target position group around the target position P of each abnormal etching characteristic are used, and the same etching operation is obtained by the same interpolation as the above-mentioned reference etching characteristic (as will be described later) It is an alternative etching characteristic for the abnormal etching property, and is hereinafter also referred to as "alternative etching property"). At this time, since the target position P of the abnormal etching characteristics is not included in the target position group, the abnormal etching characteristics are not used in place of the calculation of the etching characteristics. Further, the number of the target position groups is sufficiently smaller than the total number of other object positions P, and may be different from the number of object positions P included in the reference target position group when the reference etching characteristic is obtained.

若對各異常蝕刻特性之對象位置P求出替代蝕刻特性,則將該異常蝕刻特性置換為該替代蝕刻特性(步驟S15)。如此,將各異常蝕刻特性基於位於該異常蝕刻特性之對象位置P之周圍之對象位置群之蝕刻特性而置換為認為最合理之新的蝕刻特性。於以下之特性組取得部215之處理中,亦將替代蝕刻特性簡稱為「蝕刻特性」。 When an alternative etching characteristic is obtained for the target position P of each abnormal etching characteristic, the abnormal etching characteristic is replaced with the alternative etching characteristic (step S15). In this manner, each abnormal etching characteristic is replaced with a new etching characteristic which is considered to be most reasonable based on the etching characteristics of the target position group located around the target position P of the abnormal etching characteristic. In the processing of the following characteristic group acquisition unit 215, the alternative etching characteristics are also simply referred to as "etching characteristics".

接著,藉由特性組取得部215,取得複數個特性組(步驟S16)。特性組係僅包含與相互類似之蝕刻特性對應之對象位置P之集合。於特性組之取得處理中,首先,決定特性組之個數(以下,稱為「設定組數」)。設定組數係由操作者藉由輸入等而決定。設定組數亦可預先決定。 Next, the characteristic group acquisition unit 215 acquires a plurality of characteristic groups (step S16). The feature set only contains a set of object positions P corresponding to mutually similar etch characteristics. In the acquisition processing of the characteristic group, first, the number of characteristic groups (hereinafter referred to as "the number of setting groups") is determined. The number of set groups is determined by the operator by input or the like. The number of sets can also be determined in advance.

接著,隨機地特定出設定組數量之對象位置P,並分別分配給設定組數之特性組。分配給各特性組之對象位置P之蝕刻特性係作為與該特性組相關聯之蝕刻特性(以下,稱為「組蝕刻特性」)處理。然後,求出表示各對象位置P之蝕刻特性與各特性組之組蝕刻特性之類 似度之值(此處,兩者之類似度越高為越小之值,以下,稱為「類似度評估值」)。 Next, the object positions P of the set number of groups are randomly specified and assigned to the characteristic groups of the set number of groups. The etching characteristics of the object position P assigned to each characteristic group are treated as etching characteristics (hereinafter referred to as "group etching characteristics") associated with the characteristic group. Then, an etching characteristic indicating the position P of each object and a group etching characteristic of each characteristic group are obtained. The value of the degree of similarity (here, the higher the similarity between the two is the smaller value, the following is called the "similarity evaluation value").

例如,於一對象位置P之蝕刻特性與一特性組之組蝕刻特性之類似度評估值之算出中,於兩蝕刻特性分別包含之2條蝕刻曲線中,求出預定之複數個間隙寬度之各者之蝕刻量之差(絕對值)。接著,求出複數個間隙寬度之該差之和作為該等2條蝕刻曲線之間之距離。2條蝕刻曲線間之距離相當於該等2條蝕刻曲線所夾隔之區域之面積。於蝕刻特性僅包含一種蝕刻曲線之情形時,該距離成為上述類似度評估值。於蝕刻特性包含複數種蝕刻曲線之情形時,複數種蝕刻曲線之該距離之和等成為上述類似度評估值。 For example, in the calculation of the similarity evaluation values of the etching characteristics of a target position P and the group etching characteristics of a characteristic group, each of the predetermined plurality of gap widths is obtained from the two etching curves respectively included in the two etching characteristics. The difference in the amount of etching (absolute value). Next, the sum of the differences of the plurality of gap widths is obtained as the distance between the two etching curves. The distance between the two etching curves corresponds to the area of the area between the two etching curves. In the case where the etching characteristics include only one etching curve, the distance becomes the above-described similarity evaluation value. In the case where the etching characteristics include a plurality of etching curves, the sum of the distances of the plurality of etching curves and the like becomes the above-described similarity evaluation value.

若對各對象位置P,求出與設定組數之特性組之各者之類似度評估值,則將該對象位置P分配給類似度評估值成為最小之特性組。如此,基於各蝕刻特性與各特性組之組蝕刻特性之類似度評估值,進行將與該蝕刻特性對應之對象位置P包含於設定組數之特性組之任一者之組化處理。藉由組化處理,而於各特性組至少包含1個對象位置P。 When the similarity evaluation value of each of the characteristic groups of the set number of groups is obtained for each target position P, the target position P is assigned to the characteristic group in which the similarity evaluation value becomes the smallest. In this manner, based on the similarity evaluation values of the etching characteristics of the respective etching characteristics and the group etching characteristics of each of the characteristic groups, a grouping process of any one of the characteristic groups including the target position P corresponding to the etching characteristics in the set number of groups is performed. By group processing, at least one object position P is included in each characteristic group.

於未滿足後述之結束條件之情形時,再次取得各特性組之組蝕刻特性。此時,自藉由之前之組化處理而於各特性組所包含之所有對象位置P之蝕刻特性,求出該特性組之組蝕刻特性。具體而言,關於蝕刻曲線之各種類,針對各特性組所包含之所有對象位置P之蝕刻曲線,取得表示各間隙寬度之蝕刻量之平均值或中央值等代表值之蝕刻曲線作為組蝕刻特性之蝕刻曲線。另,各間隙寬度之蝕刻量之代表值只要為表示蝕刻量之分佈之中央附近之值即可。又,各特性組之組蝕刻特性之蝕刻曲線亦可為表示該特性組所包含之複數個對象位置P之蝕刻曲線之分佈之中央附近之一對象位置P之蝕刻曲線本身。 When the end condition described later is not satisfied, the group etching characteristics of each characteristic group are obtained again. At this time, the group etching characteristics of the characteristic group are obtained from the etching characteristics of all the object positions P included in the respective characteristic groups by the previous grouping processing. Specifically, regarding the etching curve of all the object positions P included in each of the characteristic groups, an etching curve indicating a representative value such as an average value or a central value of the etching amount of each gap width is obtained as a group etching characteristic. Etching curve. In addition, the representative value of the etching amount of each gap width may be a value indicating the vicinity of the center of the distribution of the etching amount. Further, the etching curve of the group etching characteristics of each of the characteristic groups may be an etching curve itself of one of the object positions P in the vicinity of the center of the distribution of the etching curves of the plurality of object positions P included in the characteristic group.

接著,與上述同樣,求出各蝕刻特性與各特性組之組蝕刻特性之類似度評估值,並基於類似度評估值進行將對象位置P包含於任一 特性組之新的組化處理(對象位置P之重新分配)。換言之,即更新各特性組所包含之對象位置P。於更新後之各特性組所包含之對象位置P與更新前之該特性組所包含之對象位置P不同之情形時,由於未滿足結束條件,故反復進行上述組蝕刻特性之取得及組化處理。於更新後之各特性組所包含之對象位置P與更新前之該特性組所包含之對象位置P一致之情形時,作為滿足結束條件者,而結束上述組蝕刻特性之取得及組化處理之反復。即,特性組之取得處理完成。於以下之說明中,將滿足結束條件時之特性組稱為「決定特性組」。 Then, similarly to the above, the similarity evaluation value of each etching characteristic and the group etching characteristic of each characteristic group is obtained, and the object position P is included in any one based on the similarity evaluation value. New grouping process for the feature group (redistribution of object location P). In other words, the object position P included in each attribute group is updated. When the target position P included in each of the updated characteristic groups is different from the target position P included in the characteristic group before the update, since the end condition is not satisfied, the acquisition of the group etching characteristics and the grouping processing are repeated. . When the target position P included in each of the updated characteristic groups coincides with the target position P included in the characteristic group before the update, the group etching characteristic is obtained and the grouping processing is ended as the end condition is satisfied. repeatedly. That is, the acquisition processing of the feature group is completed. In the following description, the characteristic group when the end condition is satisfied is referred to as "determination characteristic group".

藉由特性組取得部215之上述處理,將與相互類似之蝕刻特性對應之對象位置P包含於1個決定特性組,而將複數個(所有)對象位置P分成較該複數個對象位置P更少之設定組數之決定特性組。如已敘述般,由於藉由異常特性檢測部213檢測異常蝕刻特性並置換為替代蝕刻特性,故可精度良好地進行對決定特性組之分組(分群)。於圖9中,藉由將對顯示特性取得用圖案95之矩形標註之平行斜線之寬度變更為3種,而顯示3個決定特性組所包含之對象位置P。另,結束條件亦可為上述組蝕刻特性之取得及組化處理之反復次數到達預定次數之情形等。 By the above-described processing by the characteristic group acquisition unit 215, the object position P corresponding to the etching characteristics similar to each other is included in one determination characteristic group, and the plurality of (all) object positions P are divided into more than the plurality of object positions P. The set of determining characteristics of the number of groups is small. As described above, the abnormal characteristic detecting unit 213 detects the abnormal etching characteristics and replaces them with the alternative etching characteristics, so that the grouping (grouping) of the determined characteristic groups can be performed with high precision. In FIG. 9, the width of the parallel hatching of the rectangular shape of the display characteristic obtaining pattern 95 is changed to three types, and the object position P included in the three determining characteristic groups is displayed. Further, the termination condition may be a case where the acquisition of the above-described group of etching characteristics and the number of repetitions of the grouping process are reached a predetermined number of times.

將最後取得之複數個特性組之組蝕刻特性分別決定為複數個決定特性組之代表蝕刻特性。於後述之處理中,將各決定特性組之代表蝕刻特性作為該決定特性組所包含之對象位置P之蝕刻特性處理。 The group etching characteristics of the plurality of characteristic groups finally obtained are respectively determined as representative etching characteristics of a plurality of determining characteristic groups. In the processing described later, the representative etching characteristics of each of the determined characteristic groups are treated as the etching characteristics of the target position P included in the determined characteristic group.

接著,於描繪裝置1中,藉由將預定於基板9上藉由蝕刻形成之圖案之設計資料輸入於資料修正裝置21、並記憶至設計資料記憶部211予以準備(步驟S17)。 Next, in the drawing device 1, the design data of the pattern formed by etching on the substrate 9 is input to the material correction device 21, and is memorized in the design data storage unit 211 (step S17).

圖10係顯示設計資料所示之設計圖案83之圖。於圖10中,以粗二點鏈線顯示預定描繪設計圖案83之大致矩形之基板9之外形。設計圖案83包含矩陣狀地配置(即,多面標註)之複數塊圖案84。複數塊圖 案84分別為構成設計圖案83之圖案要素,且設計圖案83為複數個圖案要素之集合即圖案要素群。於圖10中,以矩形顯示塊圖案84。 Figure 10 is a diagram showing a design pattern 83 shown in the design data. In Fig. 10, the outer shape of the substantially rectangular substrate 9 which is intended to depict the design pattern 83 is displayed with a thick two-dot chain line. The design pattern 83 includes a plurality of block patterns 84 arranged in a matrix (i.e., multi-faceted). Complex block diagram The case 84 is a pattern element constituting the design pattern 83, and the design pattern 83 is a set of a plurality of pattern elements, that is, a pattern element group. In FIG. 10, the block pattern 84 is shown in a rectangle.

於圖10中顯示各塊圖案84之矩形係包圍該塊圖案84所包含之複數個圖形要素全部之大致最小矩形。於圖10之例中,沿與以二點鏈線顯示之基板9之正交2條邊對應之2方向(於圖10中,與圖5等同樣顯示為x方向及y方向),二維地排列多個塊圖案84。該等塊圖案84係相互相同之圖案。 The rectangular shape of each block pattern 84 is shown in FIG. 10 to surround the substantially smallest rectangle of all of the plurality of graphic elements included in the block pattern 84. In the example of FIG. 10, the two directions corresponding to the two sides orthogonal to the substrate 9 displayed by the two-dot chain line (in FIG. 10, the same as FIG. 5 and the like are shown as the x direction and the y direction), two-dimensionally A plurality of block patterns 84 are arranged. The block patterns 84 are the same pattern as each other.

由於設計圖案83係預定描繪於基板9上之圖案,故可理解為於設計圖案83中亦設定有複數個對象位置P。同樣,亦可理解為於基板9上,設定有預定描繪各塊圖案84之位置(以下,簡稱為「塊圖案84之位置」。)。 Since the design pattern 83 is a pattern that is intended to be drawn on the substrate 9, it can be understood that a plurality of object positions P are also set in the design pattern 83. Similarly, it is also understood that a position at which each of the block patterns 84 is predetermined to be drawn on the substrate 9 (hereinafter simply referred to as "the position of the block pattern 84") is set.

於資料修正部217中,自設計圖案83之設計資料,擷取分別顯示複數個塊圖案84之複數個分割資料(資料區塊)。換言之,將設計圖案83之設計資料分割成分別顯示複數個塊圖案84之複數個分割資料。又,對於各分割資料所示之塊圖案84之位置(例如塊圖案84之中央)特定出最接近之對象位置P。然後,藉由基於該對象位置P之蝕刻特性、即該對象位置P所屬之決定特性組之代表蝕刻特性,修正該分割資料,而求出顯示各塊圖案84之已修正分割資料(步驟S18)。另,於圖9中,以二點鏈線之矩形A1顯示將各對象位置P設為最靠近之對象位置P之區域,於圖10中亦相同。矩形A1係以該對象位置P為中心。 The data correcting unit 217 extracts a plurality of divided data (data blocks) of the plurality of block patterns 84 from the design data of the design pattern 83. In other words, the design data of the design pattern 83 is divided into a plurality of pieces of divided data in which a plurality of block patterns 84 are respectively displayed. Further, the closest object position P is specified for the position of the block pattern 84 (for example, the center of the block pattern 84) indicated by each divided material. Then, the segmentation data is corrected based on the etching characteristic of the target position P, that is, the representative etching characteristic of the determination characteristic group to which the target position P belongs, and the corrected segmentation data for displaying each block pattern 84 is obtained (step S18). . In addition, in FIG. 9, the area which sets each object position P to the closest target position P is shown by the rectangle A1 of the two-point chain line, and is the same also in FIG. The rectangle A1 is centered on the object position P.

於分割資料之修正中,考慮到於基板9上之各塊圖案84之位置,進行按照蝕刻特性所示之蝕刻量之過度(即,超過所需量)之蝕刻。即,參照與各塊圖案84之位置之蝕刻特性大致等價之決定特性組之代表蝕刻特性,以將蝕刻後之基板9上之圖案之各圖形要素以所需之線寬或大小形成之方式,進行擴寬各分割資料之圖形要素之線寬、或擴大圖形要素之修正。 In the correction of the divided data, in consideration of the position of each of the block patterns 84 on the substrate 9, etching is performed in an excessive amount (i.e., exceeding a required amount) in accordance with the etching characteristics. That is, the representative etching characteristics of the characteristic set are determined substantially in accordance with the etching characteristics of the positions of the respective block patterns 84, so that the respective pattern elements of the pattern on the substrate 9 after etching are formed in a desired line width or size. , to widen the line width of the graphic elements of each divided data, or to expand the correction of the graphic elements.

此處,若將描繪有各塊圖案84之基板9上之區域(塊)稱為分割區域,則於步驟S18中,藉由資料修正部217首先將設計圖案83之設計資料分割成分別與設定於基板9上之複數個分割區域對應之分割資料。然後,將各分割資料基於代表與該分割資料對應之分割區域之最靠近之對象位置P所屬之一決定特性組之蝕刻特性(代表蝕刻特性)而修正。以此方式,藉由進行對各分割資料之蝕刻修正,而取得已修正分割資料。 Here, when a region (block) on the substrate 9 on which each block pattern 84 is drawn is referred to as a divided region, the material correction unit 217 first divides the design data of the design pattern 83 into respective settings and in step S18. The plurality of divided regions on the substrate 9 correspond to the divided data. Then, each of the divided data is corrected based on one of the closest target positions P of the divided regions corresponding to the divided data to determine the etching characteristics (representing etching characteristics) of the characteristic group. In this way, the corrected segmentation data is obtained by performing etching correction on each of the divided data.

如上所述,於圖10所示之例中,設計資料之複數個分割資料分別顯示之分割圖案、即塊圖案84係相同。因此,可將使用各決定特性組之代表蝕刻特性而取得之已修正分割資料直接利用作為將該特性組所包含之對象位置P設為最靠近之對象位置之其他分割區域之分割資料。藉此,對分割資料之蝕刻修正之執行次數變少,而於短時間內完成分別對應於複數個分割區域之複數個已修正分割資料之取得(蝕刻修正)。於圖10中,藉由使對顯示塊圖案84之矩形標註之平行斜線之寬度一致,而表現利用相同已修正分割資料之塊圖案84。 As described above, in the example shown in FIG. 10, the division pattern displayed by the plurality of pieces of division data of the design data, that is, the block pattern 84 is the same. Therefore, the corrected divided data obtained by using the representative etching characteristics of each of the determined characteristic groups can be directly used as the divided data of the other divided regions in which the target position P included in the characteristic group is the closest target position. Thereby, the number of executions of the etching correction of the divided data is reduced, and the acquisition (etching correction) of the plurality of corrected divided data corresponding to the plurality of divided regions is completed in a short time. In FIG. 10, the block pattern 84 using the same corrected divided data is represented by making the widths of the parallel oblique lines of the rectangles of the display block pattern 84 uniform.

於資料修正部217中,藉由統一上述之複數個已修正分割資料,而產生上述已修正資料。將該已修正資料自資料修正裝置21傳送至資料轉換部22。於資料轉換部22中,將矢量資料即已修正資料轉換為光柵資料即描繪資料(步驟S19)。 The data correction unit 217 generates the corrected data by unifying the plurality of corrected divided data described above. The corrected data is transmitted from the material correction device 21 to the material conversion unit 22. The data conversion unit 22 converts the corrected data of the vector data into raster data, that is, the drawing data (step S19).

將該描繪資料自資料轉換部22傳送至曝光裝置3之描繪控制器31。於曝光裝置3中,藉由基於來自資料處理裝置2之描繪資料,利用描繪控制器31控制光出射部33之光調變部332及掃描機構35,而進行對基板9之描繪(步驟S20)。對已進行描繪之基板9,以與測試基板9a相同條件,進行顯影、蝕刻等各種處理。如已敘述般,於基板9之表面設置有銅等導電性材料之膜,且藉由上述處理,於基板9上形成分別顯示塊圖案84之複數個獨立之配線圖案。 This drawing data is transmitted from the material conversion unit 22 to the drawing controller 31 of the exposure device 3. In the exposure device 3, the light-modulating portion 332 and the scanning mechanism 35 of the light-emitting portion 33 are controlled by the drawing controller 31 based on the drawing data from the data processing device 2, and the substrate 9 is drawn (step S20). . The substrate 9 which has been drawn is subjected to various processes such as development and etching under the same conditions as the test substrate 9a. As described above, a film of a conductive material such as copper is provided on the surface of the substrate 9, and a plurality of independent wiring patterns respectively displaying the block patterns 84 are formed on the substrate 9 by the above-described processing.

實際上,對以相同設計圖案83為描繪對象之複數個基板9,利用相同已修正資料依序進行描繪。又,於變更設計圖案、亦即以新的設計圖案為描繪對象時,一面直接使用複數個決定特性組之代表蝕刻特性,一面使用該新的設計圖案進行步驟S17、S18,而產生已修正資料。然後,基於該已修正資料,進行對基板9之描繪。 Actually, a plurality of substrates 9 having the same design pattern 83 as a drawing target are sequentially drawn using the same corrected data. Further, when the design pattern is changed, that is, when a new design pattern is used as the drawing target, the representative etching characteristics of the plurality of determining characteristic groups are directly used, and the new design pattern is used to perform steps S17 and S18 to generate corrected data. . Then, based on the corrected data, the drawing of the substrate 9 is performed.

然而,於異常特性檢測部213之檢測處理中,於檢測出異常蝕刻特性時,考慮使用一般之統計檢定。於統計檢定中,使用母群之標準偏差等之統計標度。然而,由於蝕刻特性根據基板9上之位置而不同,故難以藉由統計檢定檢測出異常蝕刻特性。 However, in the detection processing of the abnormality detecting unit 213, when the abnormal etching characteristics are detected, it is considered to use a general statistical test. In the statistical verification, the statistical scale of the standard deviation of the parent group is used. However, since the etching characteristics differ depending on the position on the substrate 9, it is difficult to detect abnormal etching characteristics by statistical verification.

相對於此,於資料修正裝置21中,藉由對各對象位置P之蝕刻特性、與位於該對象位置P周圍之參照對象位置群之蝕刻特性進行比較之檢測處理,而檢測出特異之蝕刻特性作為異常蝕刻特性。藉此,可適當地檢測異常蝕刻特性。又,使用位於異常蝕刻特性之對象位置P周圍之對象位置群之蝕刻特性求出新的蝕刻特性(替代蝕刻特性),並將該異常蝕刻特性置換為該新的蝕刻特性。然後,基於對於複數個對象位置P之複數種蝕刻特性,修正設計資料。如此,可藉由將異常蝕刻特性置換為新的蝕刻特性,而更確實且精度良好地修正設計資料。 On the other hand, in the data correction device 21, the specific etching characteristics are detected by the detection processing of comparing the etching characteristics of the respective target positions P with the etching characteristics of the reference target position groups located around the target position P. As an abnormal etching characteristic. Thereby, the abnormal etching characteristics can be appropriately detected. Further, a new etching characteristic (instead of etching characteristics) is obtained using the etching characteristics of the target position group around the target position P of the abnormal etching property, and the abnormal etching characteristic is replaced with the new etching characteristic. The design data is then corrected based on a plurality of etching characteristics for a plurality of object positions P. In this way, the design data can be corrected more accurately and accurately by replacing the abnormal etching characteristics with new etching characteristics.

又,於異常特性檢測部213中,對於各對象位置P,藉由使用參照對象位置群之蝕刻特性之內插運算而取得參照蝕刻特性,並求出基於參照蝕刻特性、與該對象位置P之蝕刻特性之間之距離之判定值。如此,藉由基於參照蝕刻特性群之蝕刻特性使用認為最合理之參照蝕刻特性求出判定值,可精度良好地檢測異常蝕刻特性。 Further, in the abnormality detecting unit 213, the reference etching characteristic is obtained by interpolation calculation using the etching characteristics of the reference target position group for each target position P, and the reference etching characteristic and the target position P are obtained. The judgment value of the distance between the etching characteristics. By using the reference etching characteristic which is considered to be the most reasonable based on the etching characteristic of the reference etching characteristic group, the abnormal etching characteristic can be accurately detected.

然而,於參照蝕刻特性之取得中,如圖8所示,亦包含自周圍之蝕刻曲線大幅度離散之蝕刻曲線La,作為對一對象位置P之參照對象位置群之蝕刻曲線之1條。於該情形時,該對象位置P之參照蝕刻曲線受到蝕刻曲線La之影響,雖不至於影響蝕刻曲線La之判定值之程度, 但對於該對象位置P之蝕刻特性之判定值亦變得較大。因此,於假設為將判定值大於閾值之複數種蝕刻特性一度自處理對象排除之比較例之處理之情形時,有將對於該對象位置P之蝕刻特性亦與包含蝕刻曲線La之蝕刻特性一起自處理對象排除之情況。於該情形時,操作者將不認為是異常之蝕刻特性作為異常蝕刻特性錯誤排除。 However, in the acquisition of the reference etching characteristics, as shown in FIG. 8, the etching curve La which is largely dispersed from the surrounding etching curve is included as one of the etching curves of the reference target position group for one object position P. In this case, the reference etching curve of the object position P is affected by the etching curve La, and although it does not affect the degree of the determination value of the etching curve La, However, the determination value of the etching characteristic of the object position P also becomes large. Therefore, when it is assumed that a plurality of kinds of etching characteristics whose determination value is larger than the threshold value are once excluded from the processing target, the etching characteristics for the object position P are also included together with the etching characteristics including the etching curve La. Handling object exclusions. In this case, the operator erroneously excludes the etching characteristics that are not considered to be abnormal as the abnormal etching characteristics.

又,假設為每當檢測到一異常蝕刻特性,則於步驟S14中,藉由自位於該異常蝕刻特性之對象位置P之周圍之對象位置群之蝕刻特性取得之替代蝕刻特性,置換該異常蝕刻特性之另一比較例之處理。於該另一比較例之處理中,於在上述對象位置群之蝕刻特性包含特異之蝕刻特性(例如雖非最大之判定值,但成為大於閾值之判定值之蝕刻特性)之情形時,使用上述對象位置群之蝕刻特性求出之替代蝕刻特性受到該特異之蝕刻特性之影響,而有成為稍微歪斜形狀之可能性。 Further, assuming that an abnormal etching characteristic is detected, in step S14, the abnormal etching is replaced by an alternative etching characteristic obtained from an etching characteristic of a target position group located around the target position P of the abnormal etching characteristic. Processing of another comparative example of characteristics. In the processing of the other comparative example, when the etching characteristic of the target position group includes a specific etching characteristic (for example, an etching characteristic that is greater than a maximum determination value but is greater than a threshold value), the above-described use is performed. The alternative etching characteristics obtained by the etching characteristics of the target position group are affected by the specific etching characteristics, and may be slightly skewed.

另一方面,於異常特性檢測部213中,每當檢測出一異常蝕刻特性時,即排除該異常蝕刻特性,且再次進行檢測處理,而檢測另一異常蝕刻特性。藉此,可防止或抑制起因於如上述比較例之處理般包含自周圍之蝕刻曲線大幅度離散之蝕刻曲線作為參照對象位置群之蝕刻曲線之1條之異常蝕刻特性之誤檢測。又,於排出所有異常蝕刻特性之後,對異常蝕刻特性之對象位置P,使用位於該對象位置P之周圍之對象位置群之蝕刻特性(未排除之蝕刻特性)取得替代蝕刻特性,並將該異常蝕刻特性置換為該替代蝕刻特性。藉此,不會如上述之另一比較例般受到其他異常蝕刻特性之影響,而可對異常蝕刻特性之對象位置P,取得較佳形狀之替代蝕刻特性。其結果,可實現較設計資料更高精度之修正。另,根據於設計資料之修正所要求之精度,於資料修正裝置21中,亦可採用上述比較例之處理或上述其他比較例之處理。 On the other hand, in the abnormal characteristic detecting unit 213, each time an abnormal etching characteristic is detected, the abnormal etching characteristic is excluded, and the detecting process is performed again to detect another abnormal etching characteristic. As a result, it is possible to prevent or suppress the erroneous detection of the abnormal etching characteristic of one of the etching curves including the etching curve which is largely dispersed from the etching curve as the processing of the above-mentioned comparative example as the reference target position group. Further, after all the abnormal etching characteristics are discharged, the target etching position of the abnormal etching characteristic is obtained by using the etching characteristics (etching characteristics not excluded) of the target position group located around the target position P, and the abnormal etching property is obtained, and the abnormality is obtained. The etch characteristics are replaced by the alternative etch characteristics. Thereby, it is not affected by other abnormal etching characteristics as in the other comparative example described above, and an alternative etching characteristic of a preferable shape can be obtained for the target position P of the abnormal etching property. As a result, corrections with higher precision than design data can be achieved. Further, in the data correction device 21, the processing of the above comparative example or the processing of the other comparative examples described above may be employed depending on the accuracy required for the correction of the design data.

於資料修正裝置21中,將複數個對象位置P分成特定數之決定特性組。然後,將設計資料之各分割資料基於代表與該分割資料對應之 分割區域之最靠近之對象位置P所屬之一決定特性組之蝕刻特性而修正。藉此,實現高效地進行高精度之蝕刻修正。 In the data correction device 21, a plurality of object positions P are divided into a specific number of determination characteristic groups. Then, the segmentation data of the design data is based on the representative corresponding to the segmentation data. One of the closest object positions P of the divided regions determines the etching characteristics of the characteristic group and is corrected. Thereby, it is possible to efficiently perform high-accuracy etching correction.

此處,假如,於以對於複數個對象位置P之複數種蝕刻特性包含異常蝕刻特性之狀態下,藉由圖4之步驟S16之處理取得決定特性組之情形時,各異常蝕刻特性構成1個決定特性組之可能性變高,從而無法適當地取得特定數之決定特性組。其結果,使用異常蝕刻特性進行修正之分割圖案之修正之精度大幅度降低,且於其他分割資料中修正之精度亦變低。 Here, in the case where a plurality of kinds of etching characteristics for a plurality of object positions P include abnormal etching characteristics, when the characteristic group is determined by the process of step S16 of FIG. 4, each abnormal etching characteristic constitutes one. The possibility of determining the characteristic group becomes high, so that the determination characteristic group of the specific number cannot be appropriately obtained. As a result, the accuracy of the correction of the division pattern corrected by the abnormal etching characteristics is greatly reduced, and the accuracy of correction in other divided data is also lowered.

相對於此,於資料修正裝置21中,藉由將異常蝕刻特性置換為替代蝕刻特性,可適當地取得特定數之決定特性組。其結果,可更確實精度良好、且高效地修正所有分割資料。 On the other hand, in the data correction device 21, by changing the abnormal etching characteristics to the alternative etching characteristics, it is possible to appropriately obtain the determination characteristic set of the specific number. As a result, all the divided data can be corrected with high accuracy and efficiency.

根據於資料修正裝置21要求之處理效率,亦可省略圖4之步驟S16,而將與各分割區域對應之分割資料基於該分割區域之最靠近之對象位置P之蝕刻特性予以修正。 Depending on the processing efficiency required by the data correcting means 21, step S16 of FIG. 4 may be omitted, and the divided data corresponding to each divided area may be corrected based on the etching characteristic of the closest target position P of the divided area.

又,亦可對於各分割區域個別地求出蝕刻特性。於該情形時,於步驟S16中,不進行特性組之取得處理,而進行例如與上述參照蝕刻特性之取得相同之修正運算。即,基於各分割區域、與該分割區域之周圍之複數個對象位置P之位置關係,對該等複數個對象位置P之複數種蝕刻特性進行加權,而基於進行加權之複數種蝕刻特性求出該分割區域之蝕刻特性。然後,基於該蝕刻特性,修正與該分割區域對應之分割資料。 Moreover, the etching characteristics can be individually obtained for each divided region. In this case, in step S16, the same correction processing as that of the above-described reference etching characteristic is performed without performing the characteristic group acquisition processing. That is, based on the positional relationship between each of the divided regions and the plurality of target positions P around the divided regions, the plurality of etching characteristics of the plurality of target positions P are weighted, and the plurality of etching characteristics are determined based on the weighting Etching characteristics of the divided regions. Then, based on the etching characteristics, the segmentation data corresponding to the segmentation region is corrected.

如以上,於資料修正裝置21中,較佳將最接近與各分割資料對應之分割區域之對象位置P(最靠近之對象位置P)之蝕刻特性設為最接近蝕刻特性,並至少基於最接近蝕刻特性修正該分割資料(於後述之檢查裝置1a中亦相同)。 As described above, in the data correcting device 21, it is preferable that the etching characteristic of the object position P (the closest target position P) closest to the divided region corresponding to each divided material is set to be the closest to the etching characteristic, and at least based on the closest The segmentation data is corrected by the etching characteristics (the same applies to the inspection device 1a to be described later).

其次,對本發明之第2實施形態之檢查裝置進行說明。圖11係顯 示檢查裝置1a之功能之方塊圖。檢查裝置1a係檢查描繪設計圖案後藉由蝕刻而於基板9上形成之圖案之裝置。於檢查裝置1a中,進行基板9上之圖案、與經後述之蝕刻修正之設計資料之比較。檢查裝置1a係與圖2所示之資料處理裝置2同樣,成為一般之電腦系統之構成。 Next, an inspection apparatus according to a second embodiment of the present invention will be described. Figure 11 shows A block diagram showing the function of the inspection apparatus 1a. The inspection device 1a is a device that inspects a pattern formed on the substrate 9 by etching after drawing a design pattern. In the inspection apparatus 1a, the pattern on the substrate 9 is compared with the design data of the etching correction described later. The inspection device 1a is configured as a general computer system similarly to the data processing device 2 shown in Fig. 2 .

檢查裝置1a包含資料修正裝置21a、實際圖像記憶部25、及缺陷檢測部26。資料修正裝置21a與圖3所示之資料修正裝置21同樣,包含設計資料記憶部211、蝕刻特性記憶部212、異常特性檢測部213、特性置換部214、特性組取得部215、及資料修正部217。實際圖像記憶部25記憶形成於基板9上之圖案之圖像資料即檢查圖像資料。缺陷檢測部26檢測形成於基板9上之該圖案之缺陷。 The inspection device 1a includes a material correction device 21a, an actual image storage unit 25, and a defect detection unit 26. Similarly to the data correction device 21 shown in FIG. 3, the data correction device 21a includes a design data storage unit 211, an etching characteristic storage unit 212, an abnormality characteristic detecting unit 213, a characteristic replacing unit 214, a characteristic group obtaining unit 215, and a data correcting unit. 217. The actual image storage unit 25 stores the image data of the pattern formed on the substrate 9, that is, the inspection image data. The defect detecting unit 26 detects a defect of the pattern formed on the substrate 9.

其次,一面參照圖12,一面對檢查裝置1a之檢查流程進行說明。於檢查裝置1a之檢查中,進行與圖4之步驟S11~S18同樣之處理。具體而言,基於形成於測試基板9a上之測定圖案,取得複數個對象位置之蝕刻特性,並於蝕刻特性記憶部212予以準備(步驟S11)。接著,求出檢測處理之處理對象所包含之所有蝕刻特性之判定值(步驟S12)。於最大判定值大於閾值之情形時(步驟S13),一面將最大判定值之蝕刻特性(異常蝕刻特性)自處理對象排除,一面再次求出處理對象所包含之所有蝕刻特性之判定值(步驟S14、S12)。上述步驟S14、S12之處理係反復進行至最大判定值成為閾值以下為止(步驟S13)。若最大判定值成為閾值以下,則對各異常蝕刻特性之對象位置求出替代蝕刻特性,並將該異常蝕刻特性置換為該替代蝕刻特性(步驟S15)。 Next, the inspection flow of the inspection apparatus 1a will be described with reference to Fig. 12 . In the inspection of the inspection apparatus 1a, the same processing as steps S11 to S18 of Fig. 4 is performed. Specifically, the etching characteristics of a plurality of target positions are acquired based on the measurement pattern formed on the test substrate 9a, and are prepared in the etching characteristic storage unit 212 (step S11). Next, determination values of all the etching characteristics included in the processing target of the detection processing are obtained (step S12). When the maximum determination value is larger than the threshold value (step S13), the etching characteristic (abnormal etching characteristic) of the maximum determination value is excluded from the processing target, and the determination value of all the etching characteristics included in the processing target is obtained again (step S14). , S12). The processing of steps S14 and S12 described above is repeated until the maximum determination value becomes equal to or smaller than the threshold (step S13). When the maximum determination value is equal to or less than the threshold value, the alternative etching characteristic is obtained for the target position of each abnormal etching characteristic, and the abnormal etching characteristic is replaced with the alternative etching characteristic (step S15).

於特性組取得部215中,取得複數個特性組(步驟S16)。即,直至滿足特定結束條件之前,反復進行各特性組之組蝕刻特性之取得、及基於各對象位置之蝕刻特性與各特性組之組蝕刻特性之間之類似度評估值之組化處理,而決定出決定特性組。又,決定出決定特性組之代表蝕刻特性。 The characteristic group acquisition unit 215 acquires a plurality of characteristic groups (step S16). That is, until the specific termination condition is satisfied, the group etching processing of each characteristic group is repeated, and the grouping processing based on the similarity evaluation value between the etching characteristics of the respective target positions and the group etching characteristics of the respective characteristic groups is performed. Decide on the decision attribute group. Further, it is determined that the representative etching characteristics of the characteristic group are determined.

接著,將設計圖案83之設計資料記憶於設計資料記憶部211予以準備(步驟S17)。於資料修正部217中,自設計圖案83之設計資料,擷取分別顯示複數個塊圖案84(參照圖10)之複數個分割資料。換言之,將設計圖案83之設計資料分割成分別與複數個分割區域對應之複數個分割資料。然後,基於代表與各分割資料對應之分割區域之最靠近之對象位置所屬之一決定特性組之蝕刻特性,修正(即、蝕刻修正)該分割資料,而求出各塊圖案84之已修正分割資料(步驟S18)。 Next, the design data of the design pattern 83 is stored in the design data storage unit 211 to be prepared (step S17). The data correcting unit 217 extracts a plurality of divided pieces of the plurality of block patterns 84 (see FIG. 10) from the design data of the design pattern 83. In other words, the design data of the design pattern 83 is divided into a plurality of pieces of divided data corresponding to a plurality of divided areas, respectively. Then, based on one of the closest object positions representing the divided regions corresponding to the divided data, the etching characteristics of the characteristic group are determined, and the divided data is corrected (ie, etched and corrected), and the corrected segmentation of each block pattern 84 is obtained. Information (step S18).

此處,檢查裝置1a之蝕刻修正之內容與描繪裝置1之蝕刻修正不同。具體而言,考慮到於基板9之各塊圖案84之位置,於實際蝕刻時進行按照蝕刻特性所示之蝕刻量之過度蝕刻。即,以各塊圖案84所包含之圖形要素成為實際之蝕刻後之線寬或大小之方式,進行縮窄各分割資料之圖形要素之線寬、或縮小圖形要素之修正。換言之,對各分割資料進行與於描繪裝置1中在上述之步驟S18對分割資料進行之修正相反之修正。 Here, the content of the etching correction of the inspection apparatus 1a is different from the etching correction of the drawing apparatus 1. Specifically, in consideration of the position of each of the block patterns 84 of the substrate 9, over etching is performed in accordance with the etching amount indicated by the etching characteristics at the time of actual etching. In other words, the line width of the graphic element for narrowing each divided material or the correction of the reduced graphic element is performed so that the graphic element included in each of the block patterns 84 becomes the line width or size after the actual etching. In other words, the correction of the divided data is performed in contrast to the correction of the divided material in the above-described step S18 in the drawing device 1.

於資料修正部217中,藉由統一與複數個塊圖案84對應之複數個已修正分割資料,而產生經修正之設計圖案83之設計資料即已修正資料。將該已修正資料自資料修正裝置21傳送至缺陷檢測部26。 In the data correcting unit 217, the corrected data of the design data of the corrected design pattern 83 is generated by unifying a plurality of corrected divided data corresponding to the plurality of block patterns 84. The corrected data is transmitted from the material correction device 21 to the defect detecting unit 26.

接著,取得基板9上之蝕刻圖案之圖像資料,並將該圖像資料作為檢查圖像資料記憶於實際圖像記憶部25予以準備(步驟S21)。此處,基板9上之蝕刻圖案係藉由將基於修正前之設計圖案83之設計資料描繪於基板9上之抗蝕劑膜之圖案予以顯影而形成抗蝕劑圖案,並利用該抗蝕劑圖案實施蝕刻,而形成於基板9上之圖案。步驟S21既可與步驟S11~S18並行進行,亦可於步驟S11~S18之前進行。該檢查圖像資料既可於檢查裝置1a以外之裝置中取得,亦可於檢查裝置1a中取得。於檢查裝置1a中進行檢查圖像資料之取得時,於檢查裝置1a中,設置取得檢查圖像資料之攝像部。另,於上述步驟S11中,於在 檢查裝置1a中取得測定圖案96之圖像之情形時,檢查圖像資料之取得亦較佳於檢查裝置1a中進行。 Next, the image data of the etching pattern on the substrate 9 is obtained, and the image data is stored as the inspection image data in the actual image storage unit 25 (step S21). Here, the etching pattern on the substrate 9 is developed by developing a pattern of a resist film which is drawn on the substrate 9 based on the design data of the design pattern 83 before the correction, and the resist is used. The pattern is etched to form a pattern on the substrate 9. Step S21 may be performed in parallel with steps S11 to S18, or may be performed before steps S11 to S18. The inspection image data may be acquired by a device other than the inspection device 1a or may be acquired by the inspection device 1a. When the inspection image data is acquired in the inspection apparatus 1a, the inspection apparatus 1a is provided with an imaging unit that acquires inspection image data. In addition, in the above step S11, When the image of the measurement pattern 96 is acquired in the inspection apparatus 1a, the acquisition of the inspection image data is also preferably performed in the inspection apparatus 1a.

將檢查圖像資料自實際圖像記憶部25傳送至缺陷檢測部26。於缺陷檢測部26中,藉由比較該檢查圖像資料、與自資料修正裝置21a傳送來之已修正資料(即,藉由資料修正裝置21a蝕刻修正後之設計資料),而檢測形成於基板9上之蝕刻圖案之缺陷(步驟S22)。如上所述,由於在該已修正資料中,以各塊圖案84之圖形要素變成實際之蝕刻後之線寬或大小之方式進行修正,故於缺陷檢測部26中,將檢查圖像資料與已修正資料之差異作為基板9上之蝕刻圖案缺陷檢測出。 The inspection image data is transmitted from the actual image storage unit 25 to the defect detecting unit 26. The defect detecting unit 26 detects the formed image data and the corrected data transmitted from the data correcting device 21a (that is, the corrected design data is etched by the data correcting device 21a), thereby detecting the formation on the substrate. A defect in the etching pattern on 9 (step S22). As described above, since the corrected image is corrected such that the pattern element of each block pattern 84 becomes the actual line width or size after etching, the defect detecting unit 26 checks the image data and the image. The difference in the correction data is detected as an etch pattern defect on the substrate 9.

如以上所說明般,於資料修正裝置21a中,藉由異常特性檢測部213之檢測處理,檢測異常蝕刻特性。然後,使用位於異常蝕刻特性之對象位置周圍之對象位置群之蝕刻特性求出新的蝕刻特性(替代蝕刻特性),並取代異常蝕刻特性作為該對象位置之蝕刻特性加以利用。藉此,可更確實且精度良好地修正設計資料。且,於檢查裝置1a中,假若抑制於比較檢查圖像資料與未經蝕刻修正之設計資料之情形時所檢測出之虛報(起因於過度蝕刻之偽缺陷之檢測),則可高精度地進行基板9上之蝕刻圖案之檢查。 As described above, in the data correction device 21a, the abnormal etching characteristic is detected by the detection processing by the abnormality detecting unit 213. Then, new etching characteristics (instead of etching characteristics) are obtained using the etching characteristics of the target position group around the target position of the abnormal etching characteristics, and the abnormal etching characteristics are used instead of the etching characteristics of the target position. Thereby, the design data can be corrected more reliably and accurately. Further, in the inspection apparatus 1a, if the false detection (detection of a false defect due to over-etching) detected when comparing the inspection image data with the design data without the etching correction is suppressed, the inspection can be performed with high precision Inspection of the etching pattern on the substrate 9.

於上述描繪裝置1及檢查裝置1a中,可進行各種變更。 Various changes can be made in the drawing device 1 and the inspection device 1a described above.

於檢測處理中判定值之算出所利用之參照蝕刻特性亦可藉由使用參照對象位置群之蝕刻特性之內插運算以外之方法求出。例如,可於參照對象位置群之蝕刻特性所包含之同種之複數條蝕刻曲線中,取得表示各間隙寬度之蝕刻量之平均值或中央值等代表值之蝕刻曲線,作為參照蝕刻特性之蝕刻曲線。即,參照蝕刻特性只要為使用位於各對象位置周圍之對象位置群之蝕刻特性取得者即可。 The reference etching characteristic used for the calculation of the determination value in the detection process can also be obtained by a method other than the interpolation operation using the etching characteristics of the reference target position group. For example, an etching curve indicating a representative value such as an average value or a central value of the etching amount of each gap width may be obtained in a plurality of etching curves of the same kind included in the etching characteristics of the reference target group, as an etching curve with reference etching characteristics. . In other words, the reference etching characteristics may be obtained by using the etching characteristics of the target position group located around each target position.

於上述檢測處理中,雖基於由測定得出之蝕刻曲線、與參照蝕刻曲線之間之離散度求出判定值,但亦可例如將各間隙寬度之兩蝕刻 曲線之間之距離設為α,而求出基於特定間隙寬度之範圍內之α之和(面積)或α2之和等之判定值。如此,藉由求出基於由測定所得出之蝕刻特性、與參照蝕刻特性之間之距離之判定值,可精度良好地檢測異常蝕刻特性。 In the above detection processing, the determination value is obtained based on the dispersion between the etching curve obtained by the measurement and the reference etching curve. For example, the distance between the two etching curves of the respective gap widths may be α. The determination value based on the sum of the α (area) or the sum of α 2 in the range of the specific gap width is obtained. As described above, by determining the determination value based on the distance between the etching characteristics obtained by the measurement and the reference etching characteristic, the abnormal etching characteristics can be accurately detected.

又,根據蝕刻曲線之形狀,亦可求出其他判定值。例如,於蝕刻曲線中,亦可將表示間隙寬度之變數設為G,將表示蝕刻量之變數設為E,並藉由式1求出蝕刻曲線之全部變動T。 Further, other determination values can be obtained based on the shape of the etching curve. For example, in the etching curve, the variable indicating the gap width may be G, the variable indicating the etching amount may be E, and all the variations T of the etching curve may be obtained by Equation 1.

全部變動T係蝕刻曲線之起落之總和,且於異常特性檢測部213中,比較各對象位置之蝕刻曲線之全部變動T與位於該對象位置周圍之參照對象位置群之複數條蝕刻曲線之全部變動T。例如,使用各對象位置之全部變動T與參照對象位置群之全部變動T之平均值之差(絕對值)求出該對象位置之蝕刻特性之判定值。然後,於對所有對象位置之判定值中最大判定值大於閾值之情形時,將成為該最大判定值之蝕刻特性作為異常蝕刻特性而自檢測處理之處理對象排除。 The total variation of the rise and fall of the T-based etching curve is changed, and the abnormality detecting unit 213 compares all the variations T of the etching curve of each target position and the plurality of etching curves of the reference object position group around the target position. T. For example, the determination value of the etching characteristic of the target position is obtained by using the difference (absolute value) between the total variation T of each target position and the average value of all the variations T of the reference target position group. Then, when the maximum determination value is greater than the threshold value among the determination values of all the object positions, the etching characteristic that becomes the maximum determination value is excluded from the processing target of the detection processing as the abnormal etching characteristic.

又,亦可將基於由測定得出之蝕刻特性與參照蝕刻特性之間之距離之值、與基於兩蝕刻特性之全部變動T之值合成之值(例如加權和)作為判定值予以處理。進而,亦可求出基於對由測定得出之蝕刻曲線進行微分而得之曲線、與對參照蝕刻曲線進行微分所得之曲線之間之距離之判定值。如此,作為於檢測處理所利用之判定值,可利用各種者。 Further, a value (for example, a weighted sum) based on a value obtained by the measurement between the etching characteristic and the reference etching characteristic and a value based on all the variations T of the two etching characteristics may be treated as a determination value. Further, a determination value based on the distance between the curve obtained by differentiating the measured etching curve and the curve obtained by differentiating the reference etching curve may be obtained. As described above, various types of determination values can be utilized as the determination values used for the detection processing.

圖4及圖12之處理順序亦可適當變更。例如,既可並行進行步驟S17、與步驟S11~S16,亦可於步驟S11~S16之前進行步驟S17。 The processing order of FIGS. 4 and 12 can also be changed as appropriate. For example, step S17 and steps S11 to S16 may be performed in parallel, or step S17 may be performed before steps S11 to S16.

設計圖案83之複數個塊圖案84(基板9上之複數個塊)之配置及數 量並非限定於圖10所示者,可適當變更。測試基板9a上之複數個特性取得用圖案95之配置及數量並非限定於圖5所示者,可適當變更。特性取得用圖案95並非必須按一定間距排列。例如,於基板9上於塊之良率較高之區域較稀疏地配置特性取得用圖案95,於塊之良率較低之區域較密地配置特性取得用圖案95。 Configuration and number of a plurality of block patterns 84 (multiple blocks on the substrate 9) of the design pattern 83 The amount is not limited to those shown in Fig. 10, and can be appropriately changed. The arrangement and number of the plurality of characteristic acquisition patterns 95 on the test substrate 9a are not limited to those shown in FIG. 5, and can be appropriately changed. The feature acquisition patterns 95 do not have to be arranged at a certain pitch. For example, the characteristic acquisition pattern 95 is disposed sparsely on the substrate 9 in a region where the yield of the block is high, and the characteristic acquisition pattern 95 is densely arranged in a region where the yield of the block is low.

於設計圖案83中,既可包含一種塊圖案84、與另一種塊圖案84,亦可為設計圖案83全部為1種塊圖案84。於資料修正部217之設計資料之修正中,使用一蝕刻特性進行修正之分割資料亦可對應於與塊圖案84不同尺寸之區域。 The design pattern 83 may include one block pattern 84 and another block pattern 84, or the design pattern 83 may be one block pattern 84. In the correction of the design data of the data correction unit 217, the divided data corrected using an etching characteristic may correspond to an area different in size from the block pattern 84.

基板9除印刷基板之製造用之基板以外,亦可為半導體基板或玻璃基板等。描繪裝置1亦可利用於對基板9以外之各種對象物上之圖案之描繪。檢查裝置1a亦可利用於檢查藉由蝕刻而於基板9以外之各種對象物上形成之圖案之檢查。資料修正裝置21、21a亦可作為與描繪裝置1及檢查裝置1a獨立之裝置利用。又,資料修正裝置亦可利用於藉由蝕刻在基板9以外之各種對象物上形成之圖案之設計資料之修正。 The substrate 9 may be a semiconductor substrate, a glass substrate or the like in addition to the substrate for manufacturing the printed substrate. The drawing device 1 can also be used for drawing a pattern on various objects other than the substrate 9. The inspection device 1a can also be used to inspect an inspection of a pattern formed on various objects other than the substrate 9 by etching. The data correction devices 21 and 21a can also be used as devices independent of the drawing device 1 and the inspection device 1a. Further, the data correction device can also be used for correction of design data by etching a pattern formed on various objects other than the substrate 9.

上述實施形態及各變化例之構成只要不互相矛盾則可加以適當組合。 The configurations of the above-described embodiments and the respective modifications can be appropriately combined as long as they do not contradict each other.

雖已詳細地描述說明發明,但已敘述之說明僅為例示並非限定者。因此,只要不脫離本發明之範圍,亦可有多種變化或態樣。 The description of the invention has been described in detail, but the description of the invention is intended to be illustrative only. Therefore, various changes or aspects may be made without departing from the scope of the invention.

2‧‧‧資料處理裝置 2‧‧‧ data processing device

21‧‧‧資料修正裝置 21‧‧‧Data correction device

22‧‧‧資料轉換部 22‧‧‧Data Conversion Department

31‧‧‧描繪控制器 31‧‧‧Drawing controller

211‧‧‧設計資料記憶部 211‧‧‧Design Data Memory Department

212‧‧‧蝕刻特性記憶部 212‧‧‧ Etching Characteristics Memory

213‧‧‧異常特性檢測部 213‧‧‧Abnormal characteristic detection department

214‧‧‧特性置換部 214‧‧‧Characteristic Replacement Department

215‧‧‧特性組取得部 215‧‧‧ Characteristic Group Acquisition Department

217‧‧‧資料修正部 217‧‧‧ Data Correction Department

Claims (13)

一種資料修正裝置,其係修正藉由蝕刻而於對象物上形成之圖案之設計資料者,且包含:設計資料記憶部,其記憶藉由蝕刻而於對象物上形成之圖案之設計資料;蝕刻特性記憶部,其記憶對於上述對象物上之複數個對象位置之複數種蝕刻特性;異常特性檢測部,其藉由對各對象位置之蝕刻特性、與位於上述各對象位置的周圍之對象位置群之蝕刻特性進行比較之檢測處理,而檢測特異之蝕刻特性作為異常蝕刻特性;特性置換部,其使用位於上述異常蝕刻特性之對象位置的周圍之對象位置群之蝕刻特性求出新的蝕刻特性,並將上述異常蝕刻特性置換為上述新的蝕刻特性;及資料修正部,其基於對於上述複數個對象位置之複數種蝕刻特性而修正上述設計資料。 A data correction device for correcting design information of a pattern formed on an object by etching, and comprising: a design data storage portion that memorizes design data of a pattern formed on the object by etching; etching The characteristic memory unit stores a plurality of etching characteristics for a plurality of object positions on the object; the abnormal characteristic detecting unit has an etching characteristic for each object position and a target position group located around each of the object positions The etching characteristics are compared, and the specific etching characteristics are detected as abnormal etching characteristics. The characteristic replacing unit obtains new etching characteristics using the etching characteristics of the target position group located around the target position of the abnormal etching characteristics. And replacing the abnormal etching characteristics with the new etching characteristics; and the data correcting unit correcting the design data based on a plurality of etching characteristics of the plurality of target positions. 如請求項1之資料修正裝置,其中於上述檢測處理中,求出基於使用位於上述各對象位置的周圍之對象位置群之蝕刻特性而取得之一蝕刻特性、與上述各對象位置之蝕刻特性之間之距離之判定值。 The data correction device according to claim 1, wherein in the detecting process, an etching characteristic obtained by using a target position group located around each of the target positions is obtained, and an etching characteristic and an etching characteristic of each of the target positions are obtained. The value of the distance between the two. 如請求項2之資料修正裝置,其中上述一蝕刻特性係藉由使用上述對象位置群之蝕刻特性之內插運算而對上述各對象位置取得。 The data correction device of claim 2, wherein the one etching characteristic is obtained for each of the object positions by an interpolation operation using an etching characteristic of the target position group. 如請求項1之資料修正裝置,其中上述異常特性檢測部係每當檢測出一異常蝕刻特性時,排除上述一異常蝕刻特性,且再次進行上述檢測處理,而檢測另一 異常蝕刻特性。 The data correction device of claim 1, wherein the abnormal characteristic detecting unit excludes the abnormal etching characteristic when detecting an abnormal etching characteristic, and performs the detecting process again to detect another Abnormal etch characteristics. 一種描繪裝置,其係於對象物上描繪圖案者,且包含:如請求項1至4中任一項之資料修正裝置;光源;光調變部,其基於藉由上述資料修正裝置修正後之設計資料而對來自上述光源之光進行調變;及掃描機構,其於對象物上掃描藉由上述光調變部調變後之光。 A drawing device for drawing a pattern on an object, comprising: the data correcting device according to any one of claims 1 to 4; a light source; a light modulation portion, which is corrected based on the data correcting device The material is modulated by the design data, and the scanning mechanism scans the object for the light modulated by the light modulation unit. 一種檢查裝置,其係檢查藉由蝕刻而於對象物上形成之圖案者,且包含:如請求項1至4中任一項之資料修正裝置;實際圖像記憶部,其記憶藉由蝕刻而於對象物上形成之圖案之圖像資料即檢查圖像資料;及缺陷檢測部,其藉由比較由上述資料修正裝置修正後之設計資料與上述檢查圖像資料,而檢測形成於上述對象物上之上述圖案之缺陷。 An inspection apparatus for inspecting a pattern formed on an object by etching, and comprising: the data correction device according to any one of claims 1 to 4; the actual image memory portion whose memory is etched The image data of the pattern formed on the object is the inspection image data; and the defect detecting unit detects and forms the object by comparing the design data corrected by the data correction device with the inspection image data. The above defects in the pattern. 一種資料修正方法,其係修正藉由蝕刻而於對象物上形成之圖案之設計資料者,且包含:a)準備藉由蝕刻而於對象物上形成之圖案之設計資料之步驟;b)準備對於上述對象物上之複數個對象位置之複數種蝕刻特性之步驟;c)藉由對各對象位置之蝕刻特性、與位於上述各對象位置的周圍之對象位置群之蝕刻特性進行比較之檢測處理,而檢測出特異之蝕刻特性作為異常蝕刻特性之步驟;d)使用位於上述異常蝕刻特性之對象位置的周圍之對象位置群之蝕刻特性求出新的蝕刻特性,並將上述異常蝕刻特性置換為 上述新的蝕刻特性之步驟;及e)基於對於上述複數個對象位置之複數種蝕刻特性而修正上述設計資料之步驟。 A data correction method for correcting design information of a pattern formed on an object by etching, and comprising: a) a step of preparing design data of a pattern formed on the object by etching; b) preparing a step of etching a plurality of etching characteristics of a plurality of object positions on the object; c) detecting processing by comparing etching characteristics of respective object positions with etching characteristics of a target position group located around each of the object positions And detecting a specific etching characteristic as a step of abnormal etching characteristics; d) obtaining a new etching characteristic using an etching characteristic of a target position group located around the target position of the abnormal etching characteristic, and replacing the abnormal etching characteristic with The steps of the new etching characteristics; and e) the step of modifying the design data based on a plurality of etching characteristics for the plurality of object positions. 如請求項7之資料修正方法,其中於上述檢測處理中,求出基於使用位於上述各對象位置的周圍之對象位置群之蝕刻特性取得之一蝕刻特性、與上述各對象位置之蝕刻特性之間之距離之判定值。 The data correction method of claim 7, wherein in the detecting processing, between one etching characteristic obtained by using an etching characteristic of a target position group located around each of the target positions, and an etching characteristic between the respective object positions The judgment value of the distance. 如請求項8之資料修正方法,其中上述一蝕刻特性係藉由使用上述對象位置群之蝕刻特性之內插運算而對上述各對象位置取得。 The data correction method of claim 8, wherein the one etching characteristic is obtained for each of the object positions by an interpolation operation using an etching characteristic of the target position group. 如請求項7之資料修正方法,其中於上述c)步驟中,每當檢測出一異常蝕刻特性時,排除上述一異常蝕刻特性,且再次進行上述檢測處理,而檢測另一異常蝕刻特性。 The data correction method of claim 7, wherein in the step c), each time an abnormal etching characteristic is detected, the abnormal etching characteristic is excluded, and the detecting process is performed again to detect another abnormal etching characteristic. 一種描繪方法,其係於對象物上描繪圖案者,且包含:藉由如請求項7至10中任一項之資料修正方法而修正設計資料之步驟;及於對象物上掃描基於經修正之上述設計資料而調變後之光之步驟。 A drawing method for drawing a pattern on an object, and comprising: a step of correcting design data by a data correction method according to any one of claims 7 to 10; and scanning the object based on the corrected The steps of the light after the above design data. 一種檢查方法,其係檢查藉由蝕刻而於對象物上形成之圖案者,且包含:藉由如請求項7至10中任一項之資料修正方法而修正設計資料之步驟;及藉由對經修正之上述設計資料與藉由蝕刻而於對象物上形成之圖案之圖像資料即檢查圖像資料進行比較,而檢測形成於上述對象物上之上述圖案之缺陷之步驟。 An inspection method for inspecting a pattern formed on an object by etching, and comprising: a step of correcting design data by a data correction method according to any one of claims 7 to 10; The corrected design data is compared with the image data of the pattern formed on the object by etching, that is, the inspection image data, and the defect of the pattern formed on the object is detected. 一種記錄媒體,其係記錄有修正藉由蝕刻而於對象物上形成之圖案之設計資料之程式者,且藉由電腦對上述程式之執行係使上述電腦執行如下步驟:a)準備藉由蝕刻而於對象物上形成之圖案之設計資料之步驟;b)準備對於上述對象物上之複數個對象位置之複數種蝕刻特性之步驟;c)藉由對各對象位置之蝕刻特性、與位於上述各對象位置周圍之對象位置群之蝕刻特性進行比較之檢測處理,而檢測出特異之蝕刻特性作為異常蝕刻特性之步驟;d)使用位於上述異常蝕刻特性之對象位置周圍之對象位置群之蝕刻特性求出新的蝕刻特性,並將上述異常蝕刻特性置換為上述新的蝕刻特性之步驟;及e)將上述設計資料基於對於上述複數個對象位置之複數種蝕刻特性進行修正之步驟。 A recording medium recording a design material for correcting a pattern formed on an object by etching, and executing the program by a computer causes the computer to perform the following steps: a) preparing to be etched a step of designing a pattern of the pattern formed on the object; b) preparing a plurality of etching characteristics for a plurality of object positions on the object; c) etching characteristics of each object position, and The etching characteristic of the target position group around each object position is compared, and the specific etching characteristic is detected as the abnormal etching characteristic step; d) the etching characteristic of the object position group around the object position of the abnormal etching characteristic is used. a step of determining a new etching characteristic and replacing the abnormal etching characteristic with the new etching characteristic; and e) modifying the design data based on a plurality of etching characteristics for the plurality of object positions.
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