Search

Your search keyword '"national metrology institutes"' showing total 18 results
Start Over Descriptor "national metrology institutes"
18 results on '"national metrology institutes"'

3. The International Framework for Maintaining Equivalence and Traceability in Radionuclide Metrology.

Author

Woods, Mike and Sahagia, Maria

Subjects
*METROLOGY, *EQUIVALENCE principle (Physics), *RADIOISOTOPES, *CALIBRATION, *LABORATORIES, *VALUATION, *RADIOACTIVE decay, *NUCLEAR reactions
Abstract

Confidence that a testing or calibration laboratory consistently obtains reliable results is of major importance to users of laboratory services and participation in proficiency testing schemes provides laboratories with an objective means of assessing and demonstrating the level of confidence that can be ascribed to the reliability of the data they are producing. That level of confidence, in turn, depends on the quality of the proficiency tests and, in particular, on the accuracy of the property values associated with the test samples. In the ideal situation, the relevant property value, such as the activity of a particular radionuclide in a test matrix, will be directly traceable to the SI via comparisons with a national or international metrology institute (NMI). This, in turn, begs the question of, how reliable are the results from that NMI. Demonstration of that reliability at the highest metrological levels is achieved through inter-laboratory comparisons that are conducted between national and international metrological institutes. These are coordinated primarily by the Bureau International des Poids et Mesures (BIPM) via Key Comparisons or by comparisons within Regional Metrological Organisations (RMOs), with the results from those RMO exercises being linked to the BIPM Key Comparison results. Such programmes have been in place for many years but they have grown in importance and frequency over the past decade. Tabulation of these comparison data has been regularized recently and made available to the user communities via the BIPM Key Comparison Database (KCDB). In the field of ionizing radiation, the radionuclide metrology discipline exhibits a number of special features. For example, these include the number of potential radionuclides in a user sample; the variety of physical and chemical formats that may be presented; the statistical and temporal effects of radioactive decay; the variations in primary standardization techniques; and the restricted applicability of those primary standardization techniques to the full range of potential radionuclides and activities. Each of these, singly or in combination, ensure that there can never be a fully comprehensive set of Key Comparisons which will cover the requirements of the user community and, in turn, compromise the ability to provide a full range of proficiency tests for testing and calibration laboratories. These problems are discussed, in the context of radioactivity measurements, together with the structure and range of Key Comparisons and associated databases at the highest international level that are currently in place to underpin the proficiency tests that are necessary for the user communities in this field of application. [ABSTRACT FROM AUTHOR]

Published
2008
Full Text
View/download PDF

4. Image based similarity detection in mechanical registers

Author

Carratu, M., Iacono, S. D., Di Leo, G., Liguori, Consolatina, Pietrosanto, A., Carratu, M., Iacono, S. D., Di Leo, G., Liguori, Consolatina, and Pietrosanto, A.

Abstract

Water leakage detection at the household level is going to become one of the most challenging goals in the fields of water metering and smart sensors. While sudden leakage seems to be easier to be noted, the small one is giving researchers a hard time. The main topic of this paper is the digital processing of mechanical register images to provide water flow rate metrics, which can allow small leakage detection. The register images are automatically gathered by an electronic add-on device, which is also featured with a short range antenna to communicate with a gateway. The image processing techniques and experimental test results are finally presented and discussed. The authors' research is funded by the European Association of National Metrology Institutes (EURAMET) within the European Metrology Program for Innovation and Research (EMPIR). © 2020 IEEE.

Published
2020
Full Text
View/download PDF

5. International Comparison on Thermal-Diffusivity Measurements for Iron and Isotropic Graphite Using the Laser Flash Method in CCT-WG9.

Author

Akoshima, M., Hay, B., Zhang, J., Chapman, L., and Baba, T.

Subjects
*THERMAL diffusivity, *COMPARATIVE studies, *LASER beams, *THERMOMETRY, *GRAPHITE, *IRON, *THICKNESS measurement, *THERMAL expansion
Abstract

The first international pilot study of thermal-diffusivity measurements using the laser flash (LF) method was organized by the working group 9 (WG9) of the Consultative Committee for Thermometry (CCT) of the Bureau International des Poids et Mesures (BIPM). Four National Metrology Institutes (NMIs) participated in this comparison. Thermal-diffusivity measurements on the Armco iron and the isotropic graphite IG-110 were carried out from room temperature to about 1200 K. The sample sets consist of five disk-shaped specimens of 10 mm in diameter and (1.0, 1.4, 2.0, 2.8, and 4.0) mm in thickness, each cut from the same block of material. These sample sets were specifically prepared for the comparison and sent to the participants. In the pilot comparison, the thermal diffusivity of each sample was estimated using the LF method with a specific extrapolating procedure. This procedure has the advantage of determining the inherent thermal diffusivity of the material. The extrapolated value in a plot of measured apparent thermal-diffusivity values versus the amplitude of the output signal corresponding to the temperature rise during each measurement is defined as the inherent thermal diffusivity. The overall results showed good agreement between independent laboratories, measurement equipment, and specimen thicknesses. The thermal diffusivities of the materials were determined using our measured results. A quantitative evaluation of the variability of the data obtained by the participants has been done, by evaluating the deviations from the reference value, the Z-value, and the En-number. Some data showed a large deviation from the reference value. It was concluded that these are caused by an insufficient time response of the measurement equipment and some difficulties with changing the pulsed heating energy. The effect of the thermal expansion on the thermal diffusivity was checked. It was found that the thermal-expansion effect was very small and negligible in this case. [ABSTRACT FROM AUTHOR]

Published
2013
Full Text
View/download PDF

6. Intercomparison of flatness measurements of an optical flat at apertures of up to 150 mm in diameter

Author

M Schulz, L Svedova, M Vannoni, D Putland, S Quabis, R Bergmans, F Hungwe, Zbigniew Ramotowski, Petr Křen, M Pérez, Y Kang, P. Balling, E. Prieto, A Küng, M Asar, Antti Lassila, H Piree, G Ehret, and D Williams

Subjects
uncertainty intervals, Aperture, deflectometry, Flatness (systems theory), 02 engineering and technology, 01 natural sciences, law.invention, 010309 optics, Optics, 0203 mechanical engineering, flatness measurements, law, 0103 physical sciences, Optical surface, Optical flat, EURAMET, uncertainty analysis, Mathematics, lateral resolution, business.industry, General Engineering, interferometry, Metrology, 020303 mechanical engineering & transports, comparison, national metrology institutes, Measuring instrument, measuring instruments, business
Abstract

Recently, a scientific comparison of flatness measuring instruments at European National Metrology Institutes (NMIs) was performed in the framework of EURAMET. The specimen was a well-polished optical surface with a maximum measurement aperture of 150 mm in diameter. Here, we present an evaluation concept, which allows the determination of a mean flatness map taking into account different lateral resolutions of the instruments and different orientations of the specimen during measurement. We found that all measurements are in agreement with the mean flatness map within the uncertainty intervals stated by the participants. The aim of this scientific comparison is to specify an appropriate operation and evaluation procedure for future comparisons.

Published
2017
Full Text
View/download PDF

7. Metrology in chemistry – a public task.

Author

Dube, G.

Abstract

The importance of analytical chemistry is increasing in many public fields, and the demand for reliable measurement results is growing accordingly. A measurement result will be reliable only if its uncertainty has been quantified. This can be achieved only by tracing the result back to a standard realizing the unit in which the measurement result is expressed. The National Metrology Institutes (NMIs) can contribute to the reliability of the measurement results by developing measuring methods, and by providing reference materials and standard measuring devices. In fields in which the comparability of measurement results is of particular importance, they establish traceability structures. Responding to the globalization of trade and industry the International Committee for Weights and Measures (CIPM) agreed on an arrangement on the mutual recognition of calibration certificates (CIPM MRA) issued by the NMIs. [ABSTRACT FROM AUTHOR]

Published
2001
Full Text
View/download PDF

8. Why a digital framework for the SI?

Author

Brown, Richard J.C., Janssen, Jan-Theodoor, and Wright, Louise

Subjects
*OPEN data movement, *USER experience, *METROLOGY
Abstract

There has been a significant quantity of debate recently about how metrology and the SI should embrace the emerging societal and scientific trends of digitalisation and the open data movement. Much of this discussion has focussed on 'how' this transition will be implemented, and recent conferences and significantly advanced this understanding (International Bureau of Weights and Measures, 2021 [1]). However, there has been little if any reflection on 'why' this transition is required. This deficiency is worth addressing to provide the evidence base for the 'why' and so drive forward faster progress with the 'how'. Analogy is drawn between the recent revision of the SI and the need to provide a similar step change in end users' experience of the benefits that digitalisation should bring. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

10. Speeding-up Scientific Knowledge Transfer and Improvement of Capabilities of emerging European National Metrology Institutes and Designated Institutes in the field of thermal measurements: Benefits and Impacts

Author

N. Hodzic, Bruno Hay, Lydia Rongione, A. Corman, Igor Pušnik, Mohamed Sadli, S. Cohodarevic, Nenad Milosevic, F. Bourson, V. Stankovic, Jean-Rémy Filtz, N. Arifovic, S. Simic, M. Kalemci, Davor Zvizdić, R. Strnad, N. Stepanic, N. Jandric, D. Mac Lochlainn, Janko Drnovšek, Lenka Knazovicka, E. Turzo-Andras, Jovan Bojkovski, G. Failleau, I. Nikolic, S. Boles, V. Stepanovic, Danijel Šestan, and M. Kludsky

Subjects
History, Sociology of scientific knowledge, Engineering management, Engineering, Upgrade, business.industry, Measurement of high temperatures, Temperature standards, National metrology institutes, Research potential, Capacity building, Frame (networking), business, Field (computer science), Computer Science Applications, Education, Metrology
Abstract

Within the frame of a European project called Eura-Thermal, the general objective was to upgrade the regional metrological infrastructure (Bosnia & Herzegovina, Croatia, Ireland, Serbia...) with new capabilities, especially in the field of thermal measurements. This paper highlights the strategy used for improving in the short term, scientific knowledge transfer and the capabilities of different emerging institutes. Furthermore, as a main output, the impacts and benefit for Industry and for the end-users are also presented as examples. © 2018 Institute of Physics Publishing. All rights reserved. XXII World Congress of the International Measurement Confederation (IMEKO 2018)

Published
2018

11. Improving emerging European NMIs’ capabilities in humidity measurement

Author

S. Cohodarevic, Nedžadeta Hodžić, Nuray Karaböce, Danijel Šestan, N. Jandric, L. Iacomini, Davor Zvizdić, D. Mac Lochlainn, R. Strnad, O. Petrusova, Vito Fernicola, T. Vukicevic, S. Simic, S. Oğuz Aytekin, D. Hudoklin, Jovan Bojkovski, and D. Smorgon

Subjects
History, Meteorology, Humidity, Environmental science, Humidity measurement, Humidity standards, National metrology institutes, Research potential, Capacity building, Computer Science Applications, Education
Abstract

The control and measurement of humidity is important for many industrial applications and to ensure the appropriate storage of materials and products. Humidity measurement techniques are diverse and each presents different challenges for use and calibration for a range of pressures and gases. Over the past few years, the development of humidity sensors and apparatus has matured to a level where traceable calibration is beneficial to all industries in which humidity and moisture measurement and control are important. This paper deals with a European project in which the overall objective is to develop or extend the measurement and research capabilities of the participating emerging NMI/DIs’ countries in the field of humidity measurements, where access to these types of facilities is currently limited.

Published
2018

12. A brief history of the thermal properties metrology.

Author

Hay, Bruno

Subjects
*THERMAL properties, *METRIC system, *SPECIFIC heat, *LATENT heat, *THERMAL conductivity, *HEAT flux measurement, *ELECTRICAL conductors
Abstract

• Metrology appeared in concomitant way with the establishment of commercial exchanges. • Birth of thermal properties metrology coincides with appearance of temperature scales. • First measurement methods of thermal properties were developed in the 18th century. • A major advance was to perform energy calibrations by electrical substitution. • National metrology institutes started to study thermal properties end of 19th century. The metrology of thermal properties, which is more recent than that of length and mass, coincides with the creation of thermometers and the implementation of the temperature scales. The first major contributions to the study of thermal properties can be attributed to Franklin who devised in 1780 an experiment to evaluate the relative capacities of thermal conduction of different materials, and to Lavoisier who developed in 1782 an ice calorimeter for the relative measurements of specific and latent heat. It was not until 1807 that the first determination of an absolute value of thermal conductivity was done by Fourier. The experimental discovery of Joule around 1860, concerning the relationship between the heat generated and current flowing through a conductor, was the next important contribution to the development of metrology of thermal properties, as it provided for the first time the possibility of producing a known amount of heat by electrical way. The instruments involving generation or measurement of heat fluxes could be thus calibrated by Joule effect, enabling to improve the traceability to the International System of Units (SI) of thermal properties measurements. This principle was applied by the National Metrology Institutes, which have worked on the measurement of thermal properties from the beginning of the 20th century by developing reference facilities based on the implementation of "absolute" methods. This paper retraces the major developments in the metrology of thermal properties from its beginnings until now. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

16. International key comparison of neutron fluence measurements in monoenergetic neutron fields - CCRI(III)-K11

Author

Gressier, V., Bonaldi, A. C., Dewey, M. S., Gilliam, D. M., Harano, H., Masuda, A., Matsumoto, T., Moiseev, N., Jeffrey Nico, Nolte, R., Oberstedt, S., Roberts, N. J., Röttger, S., Thomas, D. J., Institut de Radioprotection et de Sûreté Nucléaire (IRSN), JRC Institute for Reference Materials and Measurements [Geel] (IRMM), European Commission - Joint Research Centre [Geel] (JRC), National Institute of Standards and Technology [Gaithersburg] (NIST), National Metrology Institute of Japan, National Institute od Advanced Industrial Science and Technology, Physikalisch-Technische Bundesanstalt [Braunschweig] (PTB), and National Physical Laboratory [Teddington] (NPL)

Subjects
Ionizing radiation, Key comparison reference values, Neutrons, [PHYS]Physics [physics], General Engineering, Mono-energetic neutrons, Degree of equivalence, 01 natural sciences, 010305 fluids & plasmas, National standard, National metrology institutes, 0103 physical sciences, Weighted mean values, Units of measurement, 010306 general physics, Reference instruments, International comparison
Abstract

To ensure the validity of their national standards, National Metrology Institutes, NMIs, participate regularly in international comparisons. In the area of neutron metrology, Section III of the Consultative Committee for Ionizing Radiation is in charge of the organization of these comparisons. From September 2011 to October 2012, the eleventh key comparison, named CCRI(III)-K11, took place at the AMANDE facility of the LNE-IRSN, in France. Participants from nine NMIs came with their own primary reference instruments, or instruments traceable to primary standards, with the aim of determining the neutron fluence, at 1 m distance from the target in vacuum, per monitor count at four monoenergetic neutron fields: 27 keV, 565 keV, 2.5 MeV and 17 MeV. The key comparison reference values (KCRV) were evaluated as the weighted mean values of the results provided by seven participants. The uncertainties of each KCRV are between 0.9 % and 1.7 %. The degree of equivalence (DoE), defined as the deviation of the result reported by the laboratories for each energy from the corresponding KCRV, and the associated expanded uncertainty are also reported and discussed.

Published
2014
Full Text
View/download PDF

17. The 8th International Comparison of Absolute Gravimeters 2009: the first Key Comparison (CCM.G-K1) in the field of absolute gravimetry

Author

S. Merlet, B. Karaboce, Ludger Timmen, L. J. Wang, Zhiheng Jiang, Olivier Francis, Hua Hu, Alessandro Germak, Jakub Kostelecký, Dave Inglis, D. Ruess, Jonas Ågren, H. Baumann, F. Pereira Dos Santos, I M Choi, J. Liard, H. Wilmes, Vojtech Pálinkáš, Chun-Hsing Lee, Reinhard Falk, Jan Krynski, Mirjam Bilker-Koivula, N. Le Moigne, Filippo Greco, Marcin Sękowski, Lennart Robertsson, Q. Wu, Marc Eckl, Roger Bayer, Michel Diament, Felicitas Arias, W. Ji, Sébastien Deroussi, L. Tisserand, Sylvain Bonvalot, C. Del Negro, J. Mäkinen, D. Schmerge, L. Vitushkin, Q. Bodart, I.A. Robinson, Tomasz Olszak, S. Svitlov, Matthias Becker, Christian Ullrich, Shigeki Mizushima, Géosciences Montpellier, and Université des Antilles et de la Guyane (UAG)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)

Subjects
International Committee for Weights and Measures, Absolute gravity, [SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph], [SDE.MCG]Environmental Sciences/Global Changes, High-precision, [PHYS.PHYS.PHYS-GEO-PH]Physics [physics]/Physics [physics]/Geophysics [physics.geo-ph], Metric system, gravimetry, 01 natural sciences, Gravimeters, 010309 optics, Units of measurement, National metrology institutes, 0103 physical sciences, International System of Units, Gravimetry, 010306 general physics, International comparison, CIPM MRA, Mutual recognition arrangements, Gravimeter, Key comparison, General Engineering, Geodesy, Absolute gravimetry, Metrology, Data processing, Pilot studies, Absolute gravimeter, Gravity survey, Mutual recognition, Watt balance
Abstract

The 8th International Comparison of Absolute Gravimeters (ICAG2009) took place at the headquarters of the International Bureau of Weights and Measures (BIPM) from September to October 2009. It was the first ICAG organized as a key comparison in the framework of the CIPM Mutual Recognition Arrangement of the International Committee for Weights and Measures (CIPM MRA) (CIPM 1999). ICAG2009 was composed of a Key Comparison (KC) as defined by the CIPM MRA, organized by the Consultative Committee for Mass and Related Quantities (CCM) and designated as CCM.G-K1. Participating gravimeters and their operators came from national metrology institutes (NMIs) or their designated institutes (DIs) as defined by the CIPM MRA. A Pilot Study (PS) was run in parallel in order to include gravimeters and their operators from other institutes which, while not signatories of the CIPM MRA, nevertheless play important roles in international gravimetry measurements. The aim of the CIPM MRA is to have international acceptance of the measurement capabilities of the participating institutes in various fields of metrology. The results of CCM.G-K1 thus constitute an accurate and consistent gravity reference traceable to the SI (International System of Units), which can be used as the global basis for geodetic, geophysical and metrological observations of gravity. The measurements performed afterwards by the KC participants can be referred to the international metrological reference, i.e. they are SI-traceable. The ICAG2009 was complemented by a number of associated measurements: the Relative Gravity Campaign (RGC2009), high-precision levelling and an accurate gravity survey in support of the BIPM watt balance project. The major measurements took place at the BIPM between July and October 2009. Altogether 24 institutes with 22 absolute gravimeters (one of the 22 AGs was ultimately withdrawn) and nine relative gravimeters participated in the ICAG/RGC campaign. This paper is focused on the absolute gravity campaign. We review the history of the ICAGs and present the organization, data processing and the final results of the ICAG2009. After almost thirty years of hosting eight successive ICAGs, the CIPM decided to transfer the responsibility for piloting the future ICAGs to NMIs, although maintaining a supervisory role through its Consultative Committee for Mass and Related Quantities. © 2012 BIPM & IOP Publishing Ltd.

Published
2012
Full Text
View/download PDF

18. Fixed-point comparison uncertainties for two cell geometries

Author

S. Rudtsch, A.-K. Gerlitzke, and M. Fahr

Subjects
Phase boundary, Standards, Materials science, Single cells, Measurement results, Standard cell, Cells, Nanotechnology, Fixed point, National standard, Thermal effects, Fixed-point materials, National metrology institutes, Homogeneity (physics), Cell geometries, Standard size, Temperature measurement, Pure metals, Purification effect, Mechanics, Freezing temperatures, Condensed Matter Physics, Electric batteries, Metrology, Fixed point cells, Fixed points, Phase transitions, Calibration, Uncertainty analysis, Temperature drifts, Cytology, Temperature fixed points
Abstract

To realize the ITS-90 according to its definition, among others, the melting and freezing temperatures of ideally pure metals are needed. Therefore, many national metrology institutes (NMIs) utilize a group of cells instead of one single cell as the national reference for each temperature. With direct fixed-point cell comparisons on a regular basis, it is feasible to account for the small differences between the individual fixed-point temperatures and to detect possible temperature drifts of the cells. At PTB (the German NMI), in recent years, these groups of national standard cells and the so-called transfer cells for calibrations have been complemented by newly developed slim fixed points. These cells typically contain 75% to 80% less fixed-point material compared with standard cells. Slim cells are used for homogeneity investigations of large batches of fixed-point material, for doping experiments to determine the influence of very small amounts of impurities on the fixed-point temperature with very small uncertainties, and for the investigation of contamination or purification effects after the manufacture of a fixed-point cell. These investigations have shown that the main limitation of slim cells is the quality of the phase boundary. The small dimensions of the cell do not allow the formation of a closed phase boundary (or even two of them). However, this can be compensated using a quasi-adiabatic realization procedure, and in this way, uncertainties comparable to those of standard fixed-point cells can be achieved. In this article, the design of the cells as well as typical measurement results and uncertainties for the direct comparison of fixed-point cells of both types, the standard size and slim design, are presented. © 2011 Springer Science+Business Media, LLC.

Published
2011

Catalog

Books, media, physical & digital resources
See catalog results