TWI832737B - Carrier of absolute position encoder - Google Patents

Carrier of absolute position encoder Download PDF

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TWI832737B
TWI832737B TW112111209A TW112111209A TWI832737B TW I832737 B TWI832737 B TW I832737B TW 112111209 A TW112111209 A TW 112111209A TW 112111209 A TW112111209 A TW 112111209A TW I832737 B TWI832737 B TW I832737B
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carrier
logo
mark
along
absolute position
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TW112111209A
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TW202348963A (en
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陳志鑫
莊運清
洪崇文
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高明鐵企業股份有限公司
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Abstract

The invention provides a carrier of absolute position encoder, which forms several first identifiers and a second identifier, wherein the linear each of the first identifiers is configured in the carrier at intervals along the first direction, and the linear extension direction of each of the first identifiers is defined as the second direction. The continuous linear second identifier and each of the first identifiers correspond along the second direction. The distance between the second identifier and each of the first identifiers along the second direction increases from one end of the second identifier along the first direction to the other end of the second identifier.

Description

絕對位置編碼器之載體Absolute position encoder carrier

本發明涉及一種光學式線性編碼器;特別是指一種絕對位置編碼器之載體之創新結構型態揭示者。The present invention relates to an optical linear encoder; in particular, it refers to an innovative structural type revealer of a carrier of an absolute position encoder.

光學式線性編碼器包括一標尺、一投射單元、一讀取頭及一處理單元,其中該標尺形成線性排列的數個刻度,該投射單元對該標尺投光,該讀取頭與該刻度相對,該讀取頭讀取該刻度反射的光,將編碼位置轉換為數字信號,數字讀出器或運動控制器解碼該數字信號,即可獲得該讀取頭及標尺彼此間相對移動的距離,光學尺是一種常見的線性編碼器。The optical linear encoder includes a scale, a projection unit, a read head and a processing unit, wherein the scale forms several linearly arranged scales, the projection unit emits light to the scale, and the read head is opposite to the scale , the read head reads the light reflected by the scale and converts the encoded position into a digital signal. The digital reader or motion controller decodes the digital signal to obtain the relative movement distance between the read head and the scale. Optical scale is a common linear encoder.

伺服控制系統採用線性編碼器,可以提供兩物件相對運動的位移量,其中將該標尺設置在一物件,該讀取頭設置在另一物件,各該物件相對線性運動時,通過該讀取頭讀取對應的該刻度,可以獲得各該物件的相對位移量。The servo control system uses a linear encoder, which can provide the displacement of the relative movement of two objects. The ruler is set on one object and the read head is set on the other object. When the objects move linearly relative to each other, the read head passes through the ruler. By reading the corresponding scale, the relative displacement of each object can be obtained.

查,習知線性編碼器於實際應用經驗中發現仍舊存在下述問題與缺弊:習知線性編碼器可以應用在檢測該標尺及該讀取頭的相對位移量,該標尺及該讀取頭相對運動後,若未能復歸為初始位置,電力中斷後再次啟動時,無法通過習知線性編碼器判斷該標尺或該讀取頭的絕對位置,必需進行復歸校正,該伺服控制系統始能再次運作,對於材料層積製程或其他需要連續製程的應用場合,可能由於無法辨識絕對位置,而無法續行製程,導致未完成的半成品廢棄。After investigation, it was found that the conventional linear encoder still has the following problems and disadvantages in practical application experience: the conventional linear encoder can be used to detect the relative displacement of the scale and the read head, and the scale and the read head After relative movement, if it fails to return to the initial position, and when restarted after a power interruption, the absolute position of the scale or the read head cannot be judged by the conventional linear encoder, and a return correction must be performed before the servo control system can resume operation. Operation, for material lamination processes or other applications that require continuous processes, the process may not be continued due to the inability to identify the absolute position, resulting in the abandonment of unfinished semi-finished products.

本發明之主要目的,係在提供一種絕對位置編碼器之載體,其所欲解決之技術問題,係針對如何研發出一種更具理想實用性之新式用於編碼器之載體為目標加以思索創新突破。The main purpose of the present invention is to provide a carrier for an absolute position encoder. The technical problem to be solved is to think about innovative breakthroughs with the goal of developing a new carrier for the encoder that is more ideal and practical. .

基於前述目的,本發明解決問題之技術特點,主要在於該絕對位置編碼器之載體形成數個第一標識及一第二標識,其中直線狀的各該第一標識沿著一第一方向依序間隔配置,各該第一標識的線性延伸方向定義為第二方向;Based on the aforementioned objectives, the technical feature of the present invention to solve the problem is mainly that the carrier of the absolute position encoder forms a plurality of first marks and a second mark, wherein the linear first marks are sequentially along a first direction. Arranged at intervals, the linear extension direction of each first mark is defined as the second direction;

連續線性的該第二標識及各該第一標識沿著該第二方向對應,該第二標識及各該第一標識之間沿著該第二方向的距離係由該第二標識的一端沿著該第一方向向該第二標識的另一端遞增。The continuous linear second logo and each of the first logos correspond along the second direction, and the distance between the second logo and each of the first logos along the second direction is measured along one end of the second logo. Increasingly toward the other end of the second mark along the first direction.

本發明之主要效果與優點,係能夠使得絕對位置編碼器得以產生位置碼,據此判斷該載體及絕對位置編碼器之感測單元在該第一方向上的絕對位置。The main effect and advantage of the present invention is that it enables the absolute position encoder to generate a position code, thereby determining the absolute position of the carrier and the sensing unit of the absolute position encoder in the first direction.

請參閱圖式所示,係本發明絕對位置編碼器之數個實施例,惟此等實施例僅供說明之用,在專利申請上並不受此結構之限制。Please refer to the drawings, which show several embodiments of the absolute position encoder of the present invention. However, these embodiments are for illustration only and are not limited by this structure in patent applications.

如圖1至圖4所示,所述絕對位置編碼器的實施例一,包括一載體10、數個直線狀的第一標識20、一連續線性的第二標識30、一投射單元40、一感測單元50及一訊號處理單元60,其中該載體10係片狀的碼盤,該第一標識20形成於該載體10,各該第一標識20沿著一第一方向92依序間隔配置,各該第一標識20的線性延伸方向定義為第二方向94,該第二標識30及各該第一標識20沿著該第二方向94對應,該第二標識30及各該第一標識20之間沿著該第二方向94的距離D係由該第二標識30的一端沿著該第一方向92向該第二標識30的另一端遞增。As shown in Figures 1 to 4, the first embodiment of the absolute position encoder includes a carrier 10, several linear first marks 20, a continuous linear second mark 30, a projection unit 40, a Sensing unit 50 and a signal processing unit 60, wherein the carrier 10 is a sheet-shaped code disk, the first marks 20 are formed on the carrier 10, and each of the first marks 20 is sequentially spaced along a first direction 92. , the linear extension direction of each first logo 20 is defined as the second direction 94, the second logo 30 and each first logo 20 correspond along the second direction 94, the second logo 30 and each first logo The distance D between 20 along the second direction 94 increases from one end of the second mark 30 to the other end of the second mark 30 along the first direction 92 .

該投射單元40包括一第一投光器42及一第二投光器44,其中定義一第三方向96正交該第一方向92及該第二方向94,該第一標識20及該第二標識30分別與該投射單元40沿著該第三方向96相對,該第一投光器42用於對各該第一標識20依序投射第一光學訊號,該第二投光器44用於對該第二標識30投射第二光學訊號。The projection unit 40 includes a first light projector 42 and a second light projector 44, wherein a third direction 96 is defined that is orthogonal to the first direction 92 and the second direction 94. The first logo 20 and the second logo 30 are respectively Opposite to the projection unit 40 along the third direction 96 , the first light projector 42 is used to project first optical signals to each of the first signs 20 in sequence, and the second light projector 44 is used to project the second signs 30 second optical signal.

該投射單元40及該感測單元50沿著該第一方向92同步地相對於該載體10往復作動,該感測單元50包括一第一感測模組52及一第二感測模組54,其中該第一標識20及該第二標識30分別與該感測單元50沿著該第三方向96相對,該第一感測模組52用於感測該第一光學訊號,該第二感測模組54用於感測該第二光學訊號,該感測單元50基於該第一光學訊號及該第二光學訊號生成相應的電子訊號。The projection unit 40 and the sensing unit 50 reciprocate synchronously along the first direction 92 relative to the carrier 10 . The sensing unit 50 includes a first sensing module 52 and a second sensing module 54 , wherein the first mark 20 and the second mark 30 are respectively opposite to the sensing unit 50 along the third direction 96. The first sensing module 52 is used to sense the first optical signal, and the second The sensing module 54 is used to sense the second optical signal, and the sensing unit 50 generates corresponding electronic signals based on the first optical signal and the second optical signal.

該第一感測模組52是光學感測器,通過是否讀取該第一光學訊號及讀取該第一光學訊號的次數,可作為判斷該感測單元50及該載體10沿著該第一方向92相對作動距離的依據,該第二感測模組54是感光元件,所述感光元件的具體例包括電荷耦合裝置(Charge-coupled Device,簡稱CCD)及應用作為互補式金氧半圖像傳感裝置的互補式金屬氧化物半導體(Complementary Metal-Oxide-Semiconductor,簡稱 CMOS)。 The first sensing module 52 is an optical sensor. Whether to read the first optical signal and the number of times to read the first optical signal can be used to determine whether the sensing unit 50 and the carrier 10 are along the first optical signal. Based on the relative actuating distance in one direction 92, the second sensing module 54 is a photosensitive element. Specific examples of the photosensitive element include a charge-coupled device (CCD for short) and a complementary metal oxide half pattern. Complementary metal oxide semiconductors like sensing devices Metal-Oxide-Semiconductor, referred to as CMOS).

該訊號處理單元60連接該感測單元50,該訊號處理單元60主要由電子電路構成,該訊號處理單元60用於將該電子訊號轉換為編碼值,該訊號處理單元60係電子電路領域人士所熟習的既有技術,恕不詳述該訊號處理單元60的具體構成。The signal processing unit 60 is connected to the sensing unit 50. The signal processing unit 60 is mainly composed of an electronic circuit. The signal processing unit 60 is used to convert the electronic signal into a coded value. The signal processing unit 60 is understood by those in the field of electronic circuits. As we are familiar with the existing technology, the specific structure of the signal processing unit 60 will not be described in detail.

本例中,該載體10具有一第一側12,該第一標識20及該第二標識30配置在該第一側12,該投射單元40及該感測單元50面向該第一側12,該第一側12形成反光狀態,且該第一標識20及該第二標識30分別由吸光材料構成。In this example, the carrier 10 has a first side 12, the first logo 20 and the second logo 30 are arranged on the first side 12, and the projection unit 40 and the sensing unit 50 face the first side 12, The first side 12 is in a reflective state, and the first logo 20 and the second logo 30 are each made of light-absorbing material.

該第一側12可置換為吸光狀態,該第一標識20及該第二標識30配合置換為反光材料構成,據此構成基於實施例一變換的變換實施例。The first side 12 can be replaced with a light-absorbing state, and the first logo 20 and the second logo 30 can be replaced with reflective materials, thereby forming a modified embodiment based on the modification of the first embodiment.

該第一標識20及該第二標識30分別為薄膜,該第一標識20及該第二標識30可選擇利用印刷手段形成,亦可選擇對薄膜施以裁切構成該第一標識20及該第二標識30,亦可選擇將吸光性油墨或反光性油墨利用印刷手段形成該第一標識20及該第二標識30。The first logo 20 and the second logo 30 are films respectively. The first logo 20 and the second logo 30 can be formed by printing, or the film can be cut to form the first logo 20 and the second logo 30 . For the second mark 30, light-absorbing ink or reflective ink can also be used to form the first mark 20 and the second mark 30 by printing means.

該第一標識20對該第一感測模組52反射該第一光學訊號,據使該訊號處理單元60編成距離碼,該距離碼用於判斷該載體10相對於該投射單元40及該感測單元50移動的距離。The first mark 20 reflects the first optical signal to the first sensing module 52, causing the signal processing unit 60 to encode a distance code. The distance code is used to determine the relative position of the carrier 10 to the projection unit 40 and the sensor. distance moved by the measuring unit 50.

隨著所述相對移動的進行,該第二標識30對該第二感測模組54反射該第二光學訊號,該第二感測模組54基於感測光量及接受該第二光學訊號的分佈位置,對該訊號處理單元60傳送相對應的電子訊號,所述感測光量及分布位置的不同,該第二感測模組54傳送不同的電子訊號,不同的電子訊號具有不同的電壓值,該訊號處理單元60基於所述的電壓值,編成相應的位置碼,該位置碼用於判斷該載體10相對於該投射單元40及該感測單元50的絕對位置。As the relative movement proceeds, the second mark 30 reflects the second optical signal to the second sensing module 54. The second sensing module 54 senses the amount of light and receives the second optical signal. The distribution position transmits corresponding electronic signals to the signal processing unit 60. The second sensing module 54 transmits different electronic signals depending on the difference in the sensing light amount and distribution position. Different electronic signals have different voltage values. , the signal processing unit 60 compiles a corresponding position code based on the voltage value. The position code is used to determine the absolute position of the carrier 10 relative to the projection unit 40 and the sensing unit 50 .

應用在伺服控制系統時,該載體10及該感測單元50相對運動後,縱然未執行該載體10或該感測單元50復歸初始位置的操作,設備關機或電力中斷後,再次啟動時,能夠依據該第二感測模組54感測結果,立即獲得該位置碼,不需要執行復歸校正,該伺服控制系統即可再次運作。When used in a servo control system, after the carrier 10 and the sensing unit 50 move relative to each other, even if the carrier 10 or the sensing unit 50 does not return to the initial position, the device can be turned off or restarted after power interruption. According to the sensing result of the second sensing module 54, the position code is obtained immediately. There is no need to perform reset correction, and the servo control system can operate again.

應用在短行程位移的系統時,不需要配置數量龐大的該第二投光器44及該第二感測模組54,甚至不需要為了配置更多數量的該第二投光器44及該第二感測模組54,而選擇利用微小形且單價較高的組件,能夠降低設備成本。When applied to a short-stroke displacement system, there is no need to configure a large number of the second light projectors 44 and the second sensing modules 54 , and there is even no need to configure a larger number of the second light projectors 44 and the second sensing modules. Module 54, and choosing to use components with small shapes and high unit prices can reduce equipment costs.

本例中,該第二標識30係選擇為直線狀標識,該第二標識30亦可選擇置換為其他形式,該載體10進一步形成一直線狀的基準標識22,該基準標識22沿著該第一方向92延伸,各該第一標識20分別連接該基準標識22,據此提供各該第一標識20配置時的對位方便性。In this example, the second mark 30 is selected as a linear mark. The second mark 30 can also be replaced with other forms. The carrier 10 further forms a linear reference mark 22 along the first line. The direction 92 extends, and each first mark 20 is connected to the reference mark 22 respectively, thereby providing convenience in positioning when arranging each first mark 20 .

如圖5及圖6所示,實施例二主要不同於實施例一之構成在於,該投射單元40包括數個該第二投光器44,各該第二投光器44沿著該第二方向94配置,該感測單元50包括數個該第二感測模組54,各該第二感測模組54沿著該第二方向94配置。As shown in FIGS. 5 and 6 , the second embodiment is mainly different from the first embodiment in that the projection unit 40 includes a plurality of second light projectors 44 , and each second light projector 44 is arranged along the second direction 94 . The sensing unit 50 includes a plurality of second sensing modules 54 , and each second sensing module 54 is arranged along the second direction 94 .

該載體10相對於該投射單元40及該感測單元50沿著該第一方向92作動時,各該第二投光器44分別沿著該第三方向96對該載體10投射該第二光學訊號,隨著所述移動的進行,各該第二投光器44分別依序地沿著該第三方向96對應該第二標識30,據此,各該第二光學訊號依序接觸該第二標識30,各該第二感測模組54依序地讀取接觸該第二標識30的相應該第二光學訊號,各該第二感測模組54遂基於讀取該第二光學訊號及未讀取該第二光學訊號分別生成不同形態的該電子訊號,該訊號處理單元60基於各該電子訊號編成相應的位置碼,該位置碼用於判斷該載體10相對於該投射單元40及該感測單元50的絕對位置。When the carrier 10 moves along the first direction 92 relative to the projection unit 40 and the sensing unit 50, each of the second light projectors 44 projects the second optical signal to the carrier 10 along the third direction 96, As the movement proceeds, each of the second light projectors 44 sequentially corresponds to the second mark 30 along the third direction 96. Accordingly, each of the second optical signals contacts the second mark 30 in sequence. Each second sensing module 54 sequentially reads the corresponding second optical signal contacting the second mark 30, and each second sensing module 54 is based on reading the second optical signal and not reading the second optical signal. The second optical signals respectively generate different forms of electronic signals. The signal processing unit 60 compiles corresponding position codes based on each of the electronic signals. The position codes are used to determine the position of the carrier 10 relative to the projection unit 40 and the sensing unit. Absolute position of 50.

具體而言,該第二感測模組54可選擇利用感光器構成,各該第二感測模組54可依序派發識別代碼,設若未讀取該第二光學訊號的該第二感測模組54生成代碼0,讀取該第二光學訊號的該第二感測模組54生成代碼1,配合所述的識別代碼,即可組合產生該位置碼,且該位置碼對應該感測單元50相對於該第二標識30在該第一方向92上的絕對位置;未讀取該第二光學訊號的該第二感測模組54亦可選擇生成代碼1,讀取該第二光學訊號的該第二感測模組54則生成代碼0,同樣能夠產生對應所述絕對位置的該位置碼。Specifically, the second sensing modules 54 can optionally be composed of photoreceptors, and each of the second sensing modules 54 can issue identification codes in sequence. If the second sensing module of the second optical signal is not read, The module 54 generates code 0, and the second sensing module 54 that reads the second optical signal generates code 1. Together with the identification code, the position code can be combined to generate the position code, and the position code corresponds to the sensing The absolute position of the unit 50 in the first direction 92 relative to the second mark 30; the second sensing module 54 that has not read the second optical signal can also choose to generate code 1 to read the second optical signal. The second sensing module 54 of the signal generates code 0, which can also generate the position code corresponding to the absolute position.

如圖7所示,實施例三主要不同於實施例一之構成在於,該載體10係為線性滑軌,亦可選擇工具載台或被加工物作為該載體10的具體示例。As shown in FIG. 7 , the third embodiment is mainly different from the first embodiment in that the carrier 10 is a linear slide rail. A tool carrier or a workpiece can also be selected as a specific example of the carrier 10 .

如圖8所示,實施例四主要不同於實施例一之構成在於,該第一標識20及該第二標識30作為一標識系統01的構成,分別形成該標識系統01的兩側。As shown in FIG. 8 , the fourth embodiment is mainly different from the first embodiment in that the first logo 20 and the second logo 30 are components of a logo system 01 and form two sides of the logo system 01 respectively.

如圖9所示,實施例五主要不同於實施例一之構成在於,該載體10具有該第一側12及一第二側14,該第一側12及該第二側14沿著該第三方向96相對,該投射單元40面向該第一側12,該感測單元50面向該第二側14,第一標識20及該第二標識30分別位於該第一側12,該第二側14進一步對應該第一側12形成相同的該第一標識20及該第二標識30。As shown in FIG. 9 , the fifth embodiment is mainly different from the first embodiment in that the carrier 10 has a first side 12 and a second side 14 , and the first side 12 and the second side 14 are along the first side. Three directions 96 are opposite, the projection unit 40 faces the first side 12 , the sensing unit 50 faces the second side 14 , the first logo 20 and the second logo 30 are located on the first side 12 and the second side respectively. 14 further forms the same first logo 20 and the second logo 30 corresponding to the first side 12 .

實施例五可進一步選擇變化該載體10係利用透明材料構成的碼盤,該載體10選擇在該第一側12或該第二側14配置該第一標識20及該第二標識30,從而構成基於實施例五的變換實施例。Embodiment 5 can be further optionally modified. The carrier 10 is made of a code disk made of transparent material. The carrier 10 can choose to configure the first mark 20 and the second mark 30 on the first side 12 or the second side 14, thereby forming a A modified embodiment based on the fifth embodiment.

實施例五可進一步選擇利用面光源裝置作為該投射單元40,並配合該載體10利用透明材料構成,該投射單元40對該第一側12投射的光學訊號涵蓋該第一標識20及該第二標識30,從而構成基於實施例五的另一種變換實施例,據此該投射單元40及該載體10不需要相對作動,該感測單元50及該載體10相對作動,即可遂行作動距離及絕對位置的編碼,所述的面光源裝置乃是所屬領域具有通常知識的人士依據既有技術對該第一投光器42及該第二投光器44所能易於思及的等效置換。Embodiment 5 can further choose to use a surface light source device as the projection unit 40, and use a transparent material in conjunction with the carrier 10. The optical signal projected by the projection unit 40 to the first side 12 covers the first logo 20 and the second The mark 30 constitutes another alternative embodiment based on the fifth embodiment. According to this, the projection unit 40 and the carrier 10 do not need to move relative to each other. The sensing unit 50 and the carrier 10 move relative to each other, so that the operation distance and absolute As for position encoding, the surface light source device is an equivalent replacement that a person with ordinary knowledge in the field can easily think of for the first light projector 42 and the second light projector 44 based on the existing technology.

如圖10所示,實施例六主要不同於實施例五之構成在於,該第一標識20及該第二標識30分別係貫穿該載體10所形成者;實施例六亦可進一步選擇利用面光源裝置作為該投射單元40,從而構成基於實施例六的另一種變換實施例。As shown in FIG. 10 , the sixth embodiment is mainly different from the fifth embodiment in that the first mark 20 and the second mark 30 are formed through the carrier 10 respectively; the sixth embodiment can also further choose to use a surface light source. The device serves as the projection unit 40, thus forming another modified embodiment based on the sixth embodiment.

如圖11及圖12所示,實施例七主要不同於實施例二之構成在於,實施例七更包括一標識圖形70形成於該載體10,其中該第一標識20連接該標識圖形70的一側,該第二標識30形成該標識圖形70的另一側,該第一方向92及該第二方向94分別為直線方向。As shown in Figures 11 and 12, the seventh embodiment is mainly different from the second embodiment in that the seventh embodiment further includes a logo pattern 70 formed on the carrier 10, wherein the first logo 20 is connected to a part of the logo pattern 70. On one side, the second logo 30 forms the other side of the logo graphic 70 , and the first direction 92 and the second direction 94 are linear directions respectively.

該載體10相對於該投射單元40及該感測單元50沿著該第一方向92作動時,各該第二投光器44分別投射的該第二光學訊號依序接觸該第二標識30及該標識圖形70,各該第二感測模組54依序地讀取接觸該第二標識30或該標識圖形70的相應該第二光學訊號,各該第二感測模組54據此分別生成不同形態的該電子訊號,該訊號處理單元60基於各該電子訊號編成相應的位置碼,該位置碼用於判斷該載體10相對於該投射單元40及該感測單元50的絕對位置。When the carrier 10 moves along the first direction 92 relative to the projection unit 40 and the sensing unit 50 , the second optical signals respectively projected by the second light projectors 44 contact the second mark 30 and the mark in sequence. Pattern 70, each second sensing module 54 sequentially reads the corresponding second optical signal that contacts the second mark 30 or the mark pattern 70, and each second sensing module 54 generates different signals accordingly. In the form of the electronic signals, the signal processing unit 60 compiles corresponding position codes based on each of the electronic signals. The position codes are used to determine the absolute position of the carrier 10 relative to the projection unit 40 and the sensing unit 50 .

如圖13至圖15所示,實施例八主要不同於實施例七之構成在於,該第二標識30係圓弧形,該標識圖形70具有一圓弧形的弧邊72,該弧邊72及該第二標識30分別形成該標識圖形70沿著該弧邊72之半徑方向的兩側,所述半徑方向係指通過該弧邊72之圓心C並正交該弧邊72的方向,該弧邊72的半徑小於該第二標識30的半徑,該弧邊72及該第二標識30的一端連接,且該弧邊72及該第二標識30相切,該弧邊72位於該第二標識30及該弧邊72之圓心C之間,各該第一標識20選擇沿著該第一方向92等距間隔配置,該第一標識20的一端連接該弧邊72,另一端指向該圓心C,據此標示依據該圓心C為中心在該弧邊72的圓周方向上的角度。As shown in Figures 13 to 15, the eighth embodiment is mainly different from the seventh embodiment in that the second logo 30 is arc-shaped, and the logo graphic 70 has an arc-shaped arc edge 72. The arc edge 72 and the second logo 30 respectively form two sides of the logo graphic 70 along the radial direction of the arc edge 72 , the radial direction refers to the direction passing through the center C of the arc edge 72 and orthogonal to the arc edge 72 . The radius of the arc edge 72 is smaller than the radius of the second logo 30. The arc edge 72 is connected to one end of the second logo 30, and the arc edge 72 is tangent to the second logo 30. The arc edge 72 is located on the second logo 30. Between the mark 30 and the center C of the arc edge 72, each of the first marks 20 is equidistantly arranged along the first direction 92. One end of the first mark 20 is connected to the arc edge 72, and the other end points to the center of the circle. C, thereby marking the angle in the circumferential direction of the arc edge 72 based on the circle center C.

定義一虛擬的軸線L沿著該第三方向96通過該圓心C,該投射單元40及該感測單元50分別依據該軸線L為中心同步地相對於該載體10往復旋轉。A virtual axis L is defined to pass through the center C along the third direction 96 , and the projection unit 40 and the sensing unit 50 respectively rotate reciprocally relative to the carrier 10 synchronously based on the axis L as the center.

實施例八可應用在該載體10相對於該投射單元40及該感測單元50旋轉作動的場合,從而對作動的角度及絕對位置取得編碼。Embodiment 8 can be applied when the carrier 10 rotates relative to the projection unit 40 and the sensing unit 50, so as to obtain the encoding of the angle and absolute position of the movement.

本發明前述各實施例,利用該第一標識20及該第二標識30之間在距離上漸變的變化,作為判別該載體10及該感測單元50相對作動之距離及位置的依據,進而編成該距離碼及該位置碼,具有極高的產業利用價值。In each of the foregoing embodiments of the present invention, the gradual change in distance between the first mark 20 and the second mark 30 is used as a basis for determining the distance and position of the relative movement of the carrier 10 and the sensing unit 50, and then the system is compiled into The distance code and the position code have extremely high industrial utilization value.

01:標識系統 10:載體 12:第一側 14:第二側 20:第一標識 22:基準標識 30:第二標識 40:投射單元 42:第一投光器 44:第二投光器 50:感測單元 52:第一感測模組 54:第二感測模組 60:訊號處理單元 70:標識圖形 72:弧邊 92:第一方向 94:第二方向 96:第三方向 C:圓心 D:距離 L:軸線 01:Identification system 10: Carrier 12: First side 14: Second side 20:First logo 22:Datum mark 30: Second logo 40: Projection unit 42:First projector 44:Second light projector 50: Sensing unit 52: First sensing module 54: Second sensing module 60:Signal processing unit 70: Logo graphics 72: Arc edge 92:First direction 94:Second direction 96:Third direction C: center of circle D: distance L: axis

圖1係本發明實施例一之架構示意圖。 圖2係本發明實施例一之載體的俯視圖。 圖3係本發明實施例一之使用狀態示意圖(一)。 圖4係本發明實施例一之使用狀態示意圖(二)。 圖5係本發明實施例二之架構示意圖。 圖6係本發明實施例二之俯視示意圖。 圖7係本發明實施例三之載體的部份立體圖。 圖8係本發明實施例四之載體的立體圖。 圖9係本發明實施例五之架構示意圖。 圖10係本發明實施例六之載體的立體圖。 圖11係本發明實施例七之載體的俯視圖。 圖12係本發明實施例七之俯視示意圖。 圖13係本發明實施例八之架構示意圖。 圖14係本發明實施例八之載體的俯視圖。 圖15係本發明實施例八之使用狀態示意圖。 Figure 1 is a schematic structural diagram of Embodiment 1 of the present invention. Figure 2 is a top view of the carrier according to Embodiment 1 of the present invention. Figure 3 is a schematic diagram (1) of the use state of the first embodiment of the present invention. Figure 4 is a schematic diagram (2) of the usage state of the first embodiment of the present invention. Figure 5 is a schematic diagram of the architecture of Embodiment 2 of the present invention. Figure 6 is a schematic top view of the second embodiment of the present invention. Figure 7 is a partial perspective view of a carrier according to the third embodiment of the present invention. Figure 8 is a perspective view of a carrier according to Embodiment 4 of the present invention. Figure 9 is a schematic diagram of the architecture of Embodiment 5 of the present invention. Figure 10 is a perspective view of a carrier according to Embodiment 6 of the present invention. Figure 11 is a top view of a carrier according to Embodiment 7 of the present invention. Figure 12 is a schematic top view of Embodiment 7 of the present invention. Figure 13 is a schematic structural diagram of Embodiment 8 of the present invention. Figure 14 is a top view of a carrier according to Embodiment 8 of the present invention. Figure 15 is a schematic diagram of the usage state of the eighth embodiment of the present invention.

10:載體 12:第一側 20:第一標識 22:基準標識 30:第二標識 40:投射單元 42:第一投光器 50:感測單元 52:第一感測模組 54:第二感測模組 60:訊號處理單元 92:第一方向 94:第二方向 96:第三方向 10: Carrier 12: First side 20:First logo 22:Datum mark 30: Second logo 40: Projection unit 42:First projector 50: Sensing unit 52: First sensing module 54: Second sensing module 60:Signal processing unit 92:First direction 94:Second direction 96:Third direction

Claims (7)

一種絕對位置編碼器之載體,所述的絕對位置編碼器包括一個該載體、一投射單元、一感測單元及一訊號處理單元,其中該載體、該投射單元及該感測單元沿著一第三方向相對,該訊號處理單元連接該感測單元,該感測單元沿著一第一方向相對於該載體往復作動,該感測單元包括一第一感測模組及至少一第二感測模組,該第二感測模組是電荷耦合裝置或互補式金屬氧化物半導體;該載體形成數個第一標識及一第二標識,其中直線狀的各該第一標識沿著該第一方向依序間隔配置,各該第一標識的線性延伸方向定義為第二方向;連續線性的該第二標識及各該第一標識沿著該第二方向對應,該第二標識及各該第一標識之間沿著該第二方向的距離係由該第二標識的一端沿著該第一方向向該第二標識的另一端遞增;據此,該第二感測模組基於感測光量及接受該第二光學訊號的分佈位置,對該訊號處理單元傳送相對應的電子訊號,不同的電子訊號具有不同的電壓值,該訊號處理單元基於所述的電壓值,編成相應的位置碼,該位置碼用於判斷該載體相對於該投射單元及該感測單元的絕對位置。 A carrier of an absolute position encoder. The absolute position encoder includes a carrier, a projection unit, a sensing unit and a signal processing unit, wherein the carrier, the projection unit and the sensing unit are along a first Three directions are opposite, the signal processing unit is connected to the sensing unit, the sensing unit reciprocates along a first direction relative to the carrier, the sensing unit includes a first sensing module and at least a second sensing unit module, the second sensing module is a charge coupled device or a complementary metal oxide semiconductor; the carrier forms a plurality of first marks and a second mark, wherein each linear first mark is along the first The directions are arranged at intervals in sequence, and the linear extension direction of each first mark is defined as the second direction; the continuous linear second mark and each first mark correspond along the second direction, and the second mark and each third mark correspond to each other. The distance between a mark along the second direction increases from one end of the second mark along the first direction to the other end of the second mark; accordingly, the second sensing module determines the amount of light based on the sensed light amount. And receive the distribution position of the second optical signal, and transmit the corresponding electronic signal to the signal processing unit. Different electronic signals have different voltage values. The signal processing unit compiles the corresponding position code based on the voltage value, The position code is used to determine the absolute position of the carrier relative to the projection unit and the sensing unit. 如請求項1所述之絕對位置編碼器之載體,其中該載體具有一第一側,該第一標識及該第二標識配置在該第一側。 The carrier of the absolute position encoder as claimed in claim 1, wherein the carrier has a first side, and the first identification and the second identification are arranged on the first side. 如請求項1所述之絕對位置編碼器之載體,其中定義一第三方向正 交該第一方向及該第二方向,該載體具有一第一側及一第二側,該第一側及該第二側沿著該第三方向相對,該第一標識及該第二標識分別係貫穿該載體形成者。 The carrier of the absolute position encoder as described in claim 1, wherein a third direction positive is defined Intersecting the first direction and the second direction, the carrier has a first side and a second side, the first side and the second side are opposite along the third direction, the first logo and the second logo Respectively, they are formed throughout the carrier. 如請求項1所述之絕對位置編碼器之載體,更包括一標識圖形形成於該載體,其中該第一標識連接該標識圖形的一側,該第二標識形成該標識圖形的另一側,該第一方向係直線狀,該第二標識係直線狀。 The carrier of the absolute position encoder as described in claim 1 further includes a logo graphic formed on the carrier, wherein the first logo is connected to one side of the logo graphic, and the second logo forms the other side of the logo graphic, The first direction is linear, and the second mark is linear. 如請求項1至4中任一請求項所述之絕對位置編碼器之載體,其中該載體係碼盤或線性滑軌或工具載台或被加工物。 The carrier of the absolute position encoder according to any one of claims 1 to 4, wherein the carrier is a coding disk or a linear slide rail or a tool carrier or a workpiece. 如請求項1或2所述之絕對位置編碼器之載體,更包括一標識圖形形成於該載體,其中該第二標識係圓弧形,該標識圖形具有一圓弧形的弧邊,該弧邊及該第二標識分別形成該標識圖形沿著沿著該弧邊之半徑方向的兩側,該弧邊的半徑小於該第二標識的半徑,該弧邊及該第二標識的一端連接,且該弧邊及該第二標識相切,該弧邊位於該第二標識及該弧邊之圓心之間,各該第一標識沿著該第一方向方向等角間隔配置,該第一標識的一端連接該弧邊,另一端指向該圓心,據此標識依據該圓心為中心在該弧邊的圓周方向上的角度。 The carrier of the absolute position encoder as described in claim 1 or 2 further includes a logo graphic formed on the carrier, wherein the second logo is arc-shaped, and the logo graphic has an arc-shaped arc edge. The edge and the second logo respectively form two sides of the logo graphic along the radial direction of the arc edge, the radius of the arc edge is smaller than the radius of the second logo, and one end of the arc edge and the second logo is connected, And the arc edge and the second mark are tangent, and the arc edge is located between the second mark and the center of the arc edge. Each of the first marks is arranged at equal angular intervals along the first direction, and the first marks are One end of is connected to the arc edge, and the other end points to the center of the circle, thereby marking the angle in the circumferential direction of the arc edge based on the center of the circle. 如請求項6所述之絕對位置編碼器之載體,其中該載體係碼盤或線性滑軌或工具載台或被加工物。 The carrier of the absolute position encoder as described in claim 6, wherein the carrier is a code disk, a linear slide rail, a tool carrier, or a workpiece.
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TW202211080A (en) * 2020-08-19 2022-03-16 荷蘭商Asml荷蘭公司 Apparatus and method for selecting high quality images from raw images automatically

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TW202211080A (en) * 2020-08-19 2022-03-16 荷蘭商Asml荷蘭公司 Apparatus and method for selecting high quality images from raw images automatically

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