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本文(ASTM E1455-2017 Standard Practice for Obtaining Colorimetric Data from a Visual Display Unit Using Tristimulus Colorimeters《用三原色比色计从直观显示装置中获取比色分析数据的标准实施规程》.pdf)为本站会员(roleaisle130)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

ASTM E1455-2017 Standard Practice for Obtaining Colorimetric Data from a Visual Display Unit Using Tristimulus Colorimeters《用三原色比色计从直观显示装置中获取比色分析数据的标准实施规程》.pdf

1、Designation: E1455 17Standard Practice forObtaining Colorimetric Data from a Visual Display UnitUsing Tristimulus Colorimeters1This standard is issued under the fixed designation E1455; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revisio

2、n, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.INTRODUCTIONThis practice provides directions for correcting the results obtained with tristimulus colorimeterswhen

3、 measuring the tristimulus values or chromaticity coordinates of colored displays. Tristimuluscolorimeters approximate the CIE color matching functions x(), y(), z() to make these measure-ments. The errors generated in measuring colors on a display may be minimized using this practice.1. Scope1.1 Th

4、is practice is intended as an aid for improving theaccuracy of colorimetric measurements made with tristimuluscolorimeters on visual display units, such as cathode ray tubes(CRTs) and self-luminous flat-panel displays. It explains auseful step in the analysis of colorimetric data that takesadvantage

5、 of the fact that light from such displays consists ofan additive mixture of three primary colored lights. However,it is not a complete specification of how such measurementsshould be made.1.2 This practice is limited to display devices and colori-metric instruments that meet linearity criteria as d

6、efined in thepractice. It is not concerned with effects that might causemeasurement bias such as temporal or geometric differencesbetween the instrument being optimized and the instrumentused for reference.1.3 This standard does not purport to address all of thesafety concerns, if any, associated wi

7、th its use. It is theresponsibility of the user of this standard to establish appro-priate safety, health and environmental practices and deter-mine the applicability of regulatory limitations prior to use.1.4 This international standard was developed in accor-dance with internationally recognized p

8、rinciples on standard-ization established in the Decision on Principles for theDevelopment of International Standards, Guides and Recom-mendations issued by the World Trade Organization TechnicalBarriers to Trade (TBT) Committee.2. Referenced Documents2.1 ASTM Standards:2E284 Terminology of Appearan

9、ceE1336 Test Method for Obtaining Colorimetric Data From aVisual Display Unit by SpectroradiometryE1341 Practice for Obtaining Spectroradiometric Data fromRadiant Sources for Colorimetry2.2 ISO/CIE Standard:ISO 116641:2007(E)/CIE S 0141/E:2006 Joint StandardISO/CIE Standard: Colorimetry Part 1 CIE S

10、tandardColorimetric Observers33. Terminology3.1 DefinitionsUnless otherwise stated, definitions of ap-pearance terms in Terminology E284 are applicable to thispractice.3.2 Definitions of Terms Specific to This Standard:3.2.1 calibration, nin reference to a tristimuluscolorimeter, the process perform

11、ed outside of this practice toadjust the tristimulus colorimeter to provide the best possibleresults for average or predefined conditions.3.2.2 optimization, nin reference to a tristimuluscolorimeter, the process performed pursuant to this practice toadjust the tristimulus colorimeter or to interpre

12、t its readings toprovide better results when applied to a particular displaydevice.3.2.3 compatible, adjin reference to a tristimuluscolorimeter, one so designed as to automate the proceduredescribed in this practice.1This practice is under the jurisdiction of ASTM Committee E12 on Color andAppearan

13、ce and is the direct responsibility of Subcommittee E12.06 on Display,Imaging and Imaging Colorimetry.Current edition approved July 1, 2017. Published September 2017. Originallyapproved in 1992. Last previous edition approved in 2016 as E1455 16. DOI:10.1520/E1455-17.2For referenced ASTM standards,

14、visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.3Currently available from CIE (Commission International on Illumination),http:/.Copyright AST

15、M International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United StatesThis international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for theDevelopment of International Stan

16、dards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.14. Summary of Practice4.1 Tristimulus colorimeters comprised of three or fourdetector channels are, in general, not amenable to accuratecalibration that holds for all manner of usage

17、 with differentilluminated devices and objects. This is because the spectralresponsivities of their detector channels do not exactly matchthe defined Commission Internationale de Lclairage (CIE)x(), y(), z() functions. Factory or subsequent calibrationreflects judgments and compromises that may not

18、be readilyapparent. Nevertheless, this practice provides guidance on howsuch a tristimulus colorimeter may be optimized for use with aparticular video display device, providing better accuracy withthat device than its more general calibration provides. Anoptimization matrix transforms the instrument

19、al (measured)CIE X, Y, Z values into adjusted X, Y, Z values that are closerto the ideal. This matrix is determined by reference to acolorimeter with higher intrinsic accuracy. The method derivesfrom the fact that the color stimulus functions from displaydevices are linear combinations of three prim

20、ary functions andare not entirely arbitrary.5. Significance and Use5.1 This practice may be applied when tristimulus colorim-eters are used to measure the colors produced on self-luminousvideo display devices such as CRTs and flat-panel displays,including electroluminescent (EL) panels, light emitti

21、ng diodes(LEDs) field emission displays (FEDs), and back-lit liquidcrystal displays (LCDs). This practice is not meant to be acomplete description of a procedure to measure the colorcoordinates of a display. Rather, it provides a method forobtaining more accurate results when certain conditions arem

22、et. It may be used by any person engaged in the measurementof color on display devices who has access to the requisiteequipment.5.2 This practice defines a class of tristimulus colorimetersthat may be said to be compatible with this practice.6. Background of Practice6.1 Colorimetry:6.1.1 Color measu

23、rement instruments consist, in general, ofmeans to measure radiometric power as transmitted through anumber of bandpass filters. Most commonly, electrical devicesare used to measure the filtered light. They may be used withdifferent filters in succession, or multiple devices may be usedconcurrently.

24、 In instruments called spectroradiometers, theradiometric power is measured through a large number (typi-cally 30 to 500) of narrowband filters. (Practice E1341 de-scribes how a monochromator or polychromator (spectrograph)may be employed to filter and measure light in separate bandson the order of

25、1-nm wide.) In instruments called tristimuluscolorimeters, the radiometric power is measured through threeor four wideband filters. These filters may be constructed fromdispersive elements (prisms and gratings) or from materialswith selective spectral transmission or reflection. The lattermay be eit

26、her uniform or comprised of different patches, in amosaic pattern, that provide the desired overall effect.6.1.2 No matter how many filters are used, or in whatmanner, the goal of the measurement process is to determinetristimulus values X, Y, Z. For light with a color stimulusfunction (),X 5 k *360

27、 nm830 nm!x !d (1)Y 5 k *360 nm830 nm!y !dZ 5 k *360 nm830 nm!z!dwhere:k is 683 lm/W for emissive devices, such as displays, and x !,y !, z! are color-matching functions. While the standarddefinition of X, Y, Z requires the use of the CIE 1931 2color-matching functions, the mathematics described in

28、thispractice would also be applicable to any other set of color-matching functions, such as the CIE 1964 10 functions.These equations (Eq 1) are defined by ISO in its StandardISO 116641:2007(E)/CIE S 0141E:2006 and the CIE in itspublication Publ. 015(1).46.1.3 In practice, color measurement instrume

29、nts computeX, Y, Z by the summation of the signals as measured throughthe various filters, each signal being multiplied by an appro-priate calibration factor. In matrix notation:FXmYmZmG5FCX1CX2CX3.CXfCY1CY2CY3.CYfCZ1CZ2CZ3.CZfG3F1F2F3Ff4(2)where:F1, F2, F3, through Ffare the electrical signals from

30、 the ffiltered detectors and the Cijare calibration coefficients. Xm,Ym, Zmhave subscripts to indicate that they are measuredvalues rather than ideal ones.6.1.4 In this practice, we presume that the color measuringinstrument is linear: that each signal Fais strictly proportionalto the received optic

31、al power, that any zero-offset (backgroundin darkness) is removed, that the proportionality for signal Fais not affected by the value of signal Fb, and in the case ofclosely packed detectors (such as charge-coupled device(CCD) detector elements) no signal Faspills over and affectssignal Fbas it appr

32、oaches saturation. These presumptions areamenable to experimental verification using methods beyondthe scope of this practice (2).6.1.5 The values of the matrix elements Cijmay be deter-mined using criteria that depends on the design and intendedapplication of the instrument. The full extent of this

33、 subject isbeyond the scope of this practice. However, in general, forspectroradiometers (f 30 to 500), CXjreflects the tabulatedvalue of () near the center wavelength of Filter j as well as the4The boldface numbers in parentheses refer to the list of references at the end ofthis standard.E1455 172s

34、pectral responsivity of the corresponding detector channel.(Likewise, CYjand CZjvary with ().) For tristimuluscolorimeters, the choice of Cijis discussed further, below. As ageneral matter, the instrument designer should choose pass-bands and matrix elements that balance accuracy, sensitivity,and ot

35、her design requirements.6.1.6 Tristimulus colorimeters are generally designed withfilters that are intended to match the spectral responsivities oftheir detector channels to the CIE color matching functions.For such an instrument,FXmYmZmG5FCX1000 CY2000CZ3GFF1F2F3G(3)where:the non-zero Cijmatrix ele

36、ments represent adjustable gains ofthe detector channels. However, the x() function has twodistinct lobes. This may be dealt with by splitting the lobes intotwo functions, xshort() and xlong(), each with a separate filter(F1and F2, respectively). For such an instrument,FXmYmZmG5FCX1CX20000CY30000CZ4

37、G3F1F2F3F44(4)Alternatively, the z() function properly scaled may serve asthe xshort(), since they have a similar shape,FXmYmZmG5FCX10 CX30 CY2000CZ3GFF1F2F3G(5)In all of these cases, it is difficult to realize an exact matchbetween the CIE color-matching functions and the actualspectral responsivit

38、ies of the corresponding detector channels.This means that no choice of Cijwill provide perfect calibra-tion for all applications of the instrument. The criteria forsetting the Cijmight not be well documented for a particularinstrument.6.1.7 It is generally believed that spectroradiometers, withthei

39、r many detector channels, may be calibrated to yieldsuperior measurements of X, Y, Z for diverse applications.Nevertheless, the relative simplicity of tristimulus colorimetersand their commensurately lower cost have made them popularwhere the highest accuracy is not required.6.2 Self-Luminous Displa

40、ys:6.2.1 A self-luminous display, such as a CRT, an electrolu-minescent (EL) panel, a field emission display (FED), lightemitting diodes (LED) or a back-lit liquid crystal display(LCD) generates colored light by the proportional superposi-tion (addition) of primary colored lights r(), g(), b().The s

41、ubscripts represent red, green, and blue, the primarycolors of an additive set. An arbitrarily colored patch on thevisual display has one and only one color stimulus function(),! 5 ar!1bg!1cb! (6)where a, b, c are coefficients that are determined by thedisplay electronics.6.2.2 The display electroni

42、cs vary a, b, c over the face of thedisplay in order to generate a colored image. For this practice,we presume that the display electronics may be set to make a,b, c uniform (perhaps after averaging nonobvious fine-structure) over a sufficient area of the display to permitmeasurements to be made on

43、that area.6.2.3 It is a requirement for the applicability of this practicethat the display device behaves as stated in Eq 6. This practicedoes not represent that any particular display device will act aspredicted by Eq 6, though those within the mentioned classesof devices might do so. The procedure

44、 for experimentalverification of this property for a specific display device isbeyond the scope of this practice (3).6.3 Colorimetric Measurement of Displays:6.3.1 Each of the primary color stimulus functions r(),g(), b() stimulates responses in the f detector channels thatmay be represented by a ve

45、ctor F (that is, Fr, Fg, Fb). Giventheir construction, these vectors are linearly independent.(None of the three can be expressed as a linear combination ofthe other two.) While F is an element of an f-dimensionalvector space, it is clear that only a three-dimensional subspaceis spanned by the Fs of

46、 all possible color stimulus functionsfollowing Eq 6. Further, the mapping of F into (Xm, Ym, Zm)space by Eq 2 remains three dimensional. In other words, thereis a one-to-one mapping of the vector (a, b, c) onto (X, Y, Z)byapplication of Eq 1; and, for a particular instrument with afixed calibration

47、 matrix C, there is also a one-to-one mappingof the vector (a, b, c) onto (Xm, Ym, Zm). From this we deducethat a matrix R exists that can be used to translate (Xm, Ym, Zm)values into actual (X, Y, Z) values.6.3.2 A colorimeter that takes advantage of this fact mustprovide means for implementing the

48、 matrix R. That is, all ffiltered detector signals should contribute linearly toward thecomputation of each output, Xm, Ym, Zm, instead of usingdifferent detectors for each output. This idea was reported aslong ago as 1973 by Wagner (4), and it has been expandedupon and rediscovered by others since

49、then (5-10).6.3.3 On the basis of this property, a tristimulus colorimetercan be optimized for use on a self-luminous display by theproper derivation of a matrix R for that display. We proceed onthe assumptions that the components are sufficiently stable, andthat similarly built displays have similar enough spectralprimaries to make a derivation of R worthwhile. However,these assumptions should be quantified before accuracy claimsare made in any specific situation.6

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