ГОСТ ISO Guide 35-2015 Стандартные образцы. Общие и статистические принципы сертификации (аттестации)

[1]

ISO 5725-1

Accuracy (trueness and precision) of measurement methods and results - Part 1: General principles and definitions [Точность (правильность и прецизионность) методов и результатов измерений. Часть 1. Общие положения и определения]

[2]

ISO 5725-2

Accuracy (trueness and precision) of measurement methods and results - Part 2: Basic method for the determination of repeatability and reproducibility of a standard measurement method [Точность (правильность и прецизионность) методов и результатов измерений. Часть 2. Основной метод определения повторяемости и воспроизводимости стандартного метода измерений]

[3]

ISO 5725-3

Accuracy (trueness and precision) of measurement methods and results - Part 3: Intermediate measures of the precision of a standard measurement method [Точность (правильность и прецизионность) методов и результатов измерений. Часть 3. Промежуточные критерии прецизионности стандартного метода измерений]

[4]

ISO 5725-4

Accuracy (trueness and precision) of measurement methods and results - Part 4: Basic methods for the determination of the trueness of a standard measurement method [Точность (правильность и прецизионность) методов и результатов измерений. Часть 4. Основные методы определения правильности стандартного метода измерений]

[5]

ISO 5725-5

Accuracy (trueness and precision) of measurement methods and results - Part 5: Alternative methods for the determination of the precision of a standard measurement method [Точность (правильность и прецизионность) методов и результатов измерений. Часть 5. Альтернативные методы определения прецизионности]

[6]

ISO 5725-6

Accuracy (trueness and precision) of measurement methods and results - Part 6: Use in practice of accuracy values [Точность (правильность и прецизионность) методов и результатов измерений. Часть 6. Использование значений точности на практике]

[7]

ISO Guide 31

Reference materials - Contents of certificates and labels [Стандартные образцы. Содержание сертификатов (паспортов) и этикеток]

[8]

ISO Guide 32

Calibration in analytical chemistry and use of certified reference materials (Калибровка в аналитической химии и использование стандартных образцов)

[9]

ISO Guide 33

Uses of certified reference materials (Применение стандартных образцов)

[10]

ISO Guide 34

General requirements for the competence of reference material producers (Общие требования к компетентности изготовителей стандартных образцов)

[11]

European Commission, Guidelines for the production and certification of BCR reference materials - Part A: Guide to proposers of reference materials projects, Doc. BCR/01/97, Brussels (B), 1 September 1997

[12]

European Commission, Guidelines for the production and certification of BCR reference materials, Doc. BCR/48/93, Brussels (B), 15 December 1994

[13]

Lamberty A., Schimmel H., Pauwels J. The study of the stability of reference materials by isochronous measurements, Fresenius J. Anal. Chemistry, 360 (1997), pp.359-361

[14]

International Laboratory Accreditation Cooperation, ILAC G12 Guidelines for the Requirements for the Competence of Reference Materials Producers, ILAC, 2000

[15]

Ellison S.L.R, Rosslein M., Williams A. (eds.). Eurachem/Citac Guide - Quantifying uncertainty in analytical measurement, LGC, London 2000

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Griepink B., Maier E., Muntau H., Wells D.E. The certification of the contents of six chlorobipbenyls (Nos 28, 52, 101, 118, 153 and 180) in dried sludge. CRM 392, EUR 12823 EN, Luxemburg 1990

[17]

Rice J.A. Mathematical statistics and data analysis, 2nd edition, Duxbury Press, Belmont CA, 1995, chapters 3 and 4

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Van der Veen A.M.H., Linsinger T.P.J. Lamberty A., Pauwels J. Uncertainty calculations in the certification of reference materials. 4. Characterization and certification, Accreditation and Quality Assurance, 6 (2001), pp.290-294

[19]

Linsinger T.P.J., Pauwels J., Van der Veen A.M.H., Schimmel H., Lamberty A. Homogeneity and Stability of Reference Materials, Accreditation and Quality Assurance, 6 (2001), pp.20-25

[20]

Van der Veen A.M.H., Pauwels J. Uncertainty calculations in the certification of reference materials. 1. Principles of analysis of variance, Accreditation and Quality Assurance, 5 (2000), pp.464-469

[21]

Sokal R.R., Rohlf F.J. Biometry, 3rd edition, Freeman, New York 1995

[22]

Van der Veen A.M.H., Linsinger T.P.J, Pauwels J. Uncertainty calculations in the certification of reference materials. 2. Homogeneity study, Accreditation and Quality Assurance, 6 (2001), pp.26-30

[23]

Van der Veen A.M.H., Linsinger T.P.J., Lamberty A., Pauwels J. Uncertainty calculations in the certification of reference materials. 3. Stability study, Accreditation and Quality Assurance, 6 (2001), pp.257-263

[24]

Draper N.R., Smith H. Applied regression analysis, 2nd edition, J. Wiley and Sons, New York, 1981, chapter 1

[25]

Linsinger T.P.J., Pauwels J., Lamberty A., Schimmel H., Van der Veen A.M.H., Siekmann L. Estimating the uncertainty of stability for matrix CRMs, Fresenius J. Anal. Chem., 370 (2001), pp.183-188

[26]

Buck R.P, Rondini S., Covington A.K., Baucke F.G.K., Brett C.M.A., Camoes M.F., Milton M.J.T., Mussini T., Naumann R., Pratt K.W., Spitzer P., Wilson G.S. Measurement of pH. Definition, standards and procedures, IUPAC Recommendations 2002, Pure Appl. Chem., 74 (2002), pp.2169-2200

[27]

King B. Metrology and analytical chemistry: bridging the cultural gap, Metrologia, 34 (1997), pp.41-47

[28]

Schiller S.B. Statistical aspects of the certification of chemical batch SRMs, NIST Special Publication 260-125, Gaithersburg MD, July 1996

[29]

Minutes from the fifth meeting (February 1998) of the Consultative Committee on the Quantity of Material (CCQM) of the Bureau International des Poids et Mesures (BIPM), Sevres, France (1988)

[30]

May W., Parris R., Beck C., Fassett J., Greenberg R., Guenther F., Kramer G., Wise S., Gills T., Colbert J., Gettings R., MacDonald B. Definition and terms and modes used at NIST for valueassignment of reference materials for chemical measurements, NIST Special Publication 260-136, Gaithersburg MD, January 2000

[31]

Kaarls R., Quinn T.J. The Comite Consultatif pour la Quantite de Matiere: a brief review of its origin and present activities, Metrologia, 34 (1997), pp.1-5

[32]

Alink A., Van der Veen A.M.H. Uncertainty calculations for the preparation of primary gas mixtures. Gravimetry, Metrologia, 37 (2000), pp.641-650

[33]

Blaine R.L., Schoff C.K. (eds.). Purity Determinations by Thermal Methods, ASTM STP 838, ASTM, Philadelphia, 1984

[34]

Pauwels J., Lamberty A., Schimmel H. The determination of the uncertainty of reference materials certified by laboratory intercomparison, Accreditation and Quality Assurance, 3 (1998), pp.180-184

[35]

ISO 6142:2001

Gas analysis - Preparation of calibration gas mixtures - Gravimetric method (Газовый анализ. Приготовление калибровочных газовых смесей. Гравиметрический метод стандартного метода измерений)

[36]

Guenther F.R., Dorko W.D., Miller W.R., Rhoderick G.C. The NIST Traceable Reference Material Program for gas standards, NIST Special Publication 260-126, Gaithersburg MD, July 1996

[37]

ISO 6143:2001

Gas analysis - Comparison methods for determining and checking the composition of calibration gas mixtures - Comparison methods (Газовый анализ. Методы сравнения для определения и контроля состава калибровочных газовых смесей. Методы сравнения)

[38]

Van der Veen A.M.H. Determination of the certified value of a reference material appreciating the uncertainty statements obtained in the collaborative study, in Ciarlini P., Cox M.G., Filipe E., Pavese F., Richter D. Advanced Mathematical and Computational Tools in Metrology, V, World Scientific, Singapore, 2000, pp.326-340

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Nielsen L. Evaluation of measurement intercomparisons by the method of least squares, Technical Report CCEM WGKC 00-13, CCEM Working Group on Key Comparisons, 2000

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Cox M.G., Forbes A.B., Harris P.M. SSfM Best Practice Guide 4 - Discrete modeling, Centre for Mathematics and Scientific Computing, NPL, Teddington (UK), Version 1.1, March 2002

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Cox M.G., Dainton M.P., Harris P.M. SSfM Best Practice Guide 6 - Uncertainty and statisticalmodelling, Centre for Mathematics and Scientific Computing, NPL, Teddington (UK), March 2001

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Cox M.G. A discussion of approaches for determining a reference value in the analysis of keycomparison data, CISE 42/99, Centre for Mathematics and Scientific Computing, NPL, Teddington (UK), October 1999

[43]

Levenson M.S., Banks D.L., Eberhardt K.R., Gill L.M., Guthrie W.F., Liu H.K., Vangel M.G., Yen J.H., Zhang N.F. An approach to combining results from multiple methods motivated by the ISO GUM, J. Res. Natl. Inst. Stand. Technol., 105 (2000), pp.571-579

[44]

John P.W.M. Statistical design and analysis of experiments, New York, NY, Macmillan, 1971, p. 76

[45]

Searle S.R. Linear models, New York, NY, John Wiley, 1971

[46]

Linsinger T., Kristiansen N., Schimmel H., Pauwels J. et al. (2000). Catalytic Concentration of -Glutamyltransferase (GGT) determined by the IFCC-Method at 37°C. IRMM/IFCC-452, EUR19577EN

[47]

Schiele F., Siest G., Moss D.W., Colinet E. The certification of the catalytic concentration of gammaglutamyltransferase in a reconstituted lyophilized material (CRM 319), 1986; CEC Report EUR 10628 EN

УДК 655.535.2:006.354

МКС 17.020

Т62

Ключевые слова: аттестованные стандартные образцы, сертифицированные стандартные образцы, аттестованное значение стандартного образца, сертифицированное значение стандартного образца, стабильность стандартного образца, однородность стабильного* образца, характеризация стандартного образца, аттестация стандартного образца, сертификация стандартного образца