ISO Linear Calibration and Measurement Uncertainty of the Result Obtained With the Calibrated Instrument

Palenčár Jakub; Palenčár Rudolf; Chytil Miroslav; Wimmer Gejza; Wimmer Gejza; Witkovský Viktor

doi:10.2478/msr-2022-0037

Measurement Science Review (Dec 2022)

ISO Linear Calibration and Measurement Uncertainty of the Result Obtained With the Calibrated Instrument

Palenčár Jakub,
Palenčár Rudolf,
Chytil Miroslav,
Wimmer Gejza,
Wimmer Gejza,
Witkovský Viktor

Affiliations

Palenčár Jakub: Faculty of Mechanical Engineering of the Slovak University of Technology in Bratislava, Námestie slobody 17, 812 31Bratislava, Slovak Republic
Palenčár Rudolf: Faculty of Mechanical Engineering of the Slovak University of Technology in Bratislava, Námestie slobody 17, 812 31Bratislava, Slovak Republic
Chytil Miroslav: Slovak Institute of Metrology, Karloveská 63, 842 55Bratislava, Slovak Republic
Wimmer Gejza: Institute of Measurement Science of the Slovak Academy of Sciences, Dúbravská cesta 9, 841 07Bratislava, Slovak Republic
Wimmer Gejza: Mathematical Institute of the Science of the Slovak Academy of Sciences, Štefánikova 49, 814 73Bratislava, Slovak Republic
Witkovský Viktor: Institute of Measurement Science of the Slovak Academy of Sciences, Dúbravská cesta 9, 841 07Bratislava, Slovak Republic

DOI: https://doi.org/10.2478/msr-2022-0037
Journal volume & issue: Vol. 22, no. 6
pp. 293 – 307

Abstract

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We address the problem of linear comparative calibration, a special case of linear calibration where both variables are measured with errors, and the analysis of the uncertainty of the measurement results obtained with the calibrated instrument. The concept is explained in detail using the calibration experiment of the pressure transducer and the subsequent analysis of the measurement uncertainties. In this context, the calibration and the measurements with the calibrated instrument are performed according to ISO Technical Specification 28037:2010 (here referred to as ISO linear calibration), based on the approximate linear calibration model and the application of the law of propagation of uncertainty (LPU) in this approximate model. Alternatively, estimates of the calibration line parameters, their standard uncertainties, the coverage intervals and the associated probability distributions are obtained using the Monte Carlo method (MCM) based on the law of propagation of distributions (LPD). Here we also obtain the probability distributions and the coverage interval for the quantities measured with the calibrated instrument. Furthermore, motivated by the model structure of this particular example, we conducted a simulation study that presents the empirical coverage probabilities of the ISO and MCM coverage intervals and investigates the influence of the sample size, i.e. the number of calibration points in the measurement range, and the different combinations of measurement uncertainties. The study generally confirms the good properties and validity of the ISO technical specification within the considered (limited) framework of experimental designs motivated by real-world application, with small uncertainties in relation to the measurement range. We also point out the potential weaknesses of this method that require increased user attention and emphasise the need for further research in this area.

Published in Measurement Science Review

ISSN: 1335-8871 (Online)
Publisher: Sciendo
Country of publisher: Poland
LCC subjects: Science: Mathematics
Website: https://sciendo.com/journal/MSR

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