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Metrology for long distance surveying: A joint attempt to improve traceability of long distance measurements
RISE, SP – Sveriges Tekniska Forskningsinstitut, SP Mätteknik.
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2016 (English)In: International Association of Geodesy Symposia, 2016, p. 651-656Conference paper, Published paper (Refereed)
Abstract [en]

Based on the current state of technology, distance measurements over a few hundred metres in air with relative uncertainties significantly better than 10_6 are still an almost impossible challenge. In the European Joint Research Project (JRP) “Metrology for long distance surveying” measurement uncertainties in GNSS-based and optical distance metrology are going to be thoroughly investigated, novel technologies and primary standards developed and guidelines to improve surveying practice in the field worked out. A better understanding and a decrease of measurement uncertainty is also targeted for the critical local tie measurement at geodetic fundamental stations. © Springer International Publishing Switzerland 2015.

Place, publisher, year, edition, pages
2016. p. 651-656
Keywords [en]
Calibration, EDM, GNSS, Local ties, Long distance, Reference baseline, Surveying, Surveys, Units of measurement, Long distance measurement, Measurement uncertainty, Primary standards, Relative uncertainty, Uncertainty analysis
National Category
Natural Sciences
Identifiers
URN: urn:nbn:se:ri:diva-27680DOI: 10.1007/1345_2015_154Scopus ID: 2-s2.0-84984870859ISBN: 9783319246031 (print)OAI: oai:DiVA.org:ri-27680DiVA, id: diva2:1059154
Conference
150th Anniversary with a Scientific Assembly, IAG 2013, 2 September 2013 through 6 September 2013
Note

References: Brunner, F., Lienhardt, W., Anwendung der “local scale parameter method (LSPM)” bei der vermessung von basislinien (2012) AVN, 119 (809), pp. 363-368; Brunner, F., Rüeger, J.M., Theory of the local scale parameter method for EDM (1992) Bull Geod, 66, pp. 355-364; Ciddor, P.E., Refractive index of air: New equations for the visible and near infrared (1996) Appl Opt, 35 (9), pp. 1566-1573; Ciddor, P.E., Hill, R.J., Refractive index of air. 2. Group index (1999) Appl Opt, 38 (9), pp. 1663-1667; Colosimo, G., Crespi, M., Mazzoni, A., Jones, M., Missiaen, D., Determination of the CNGS global geodesy (2011) OPERA Public Note, 132, pp. 1-7; Giacomo, P., News from the BIPM (1984) Metrologia, 20 (1), p. 25; Görres, B., Ist das GNSS–Antennenproblem gelöst? (2010) Zeitschrift für Vermessungswesen Zfv, 135 (4), pp. 256-267; Gross, R., Beutler, G., Plag, H., Integrated scientific and societal user requirements and functional specifications for the GGOS (2009) Global Geodetic Observing System Meeting the Requirements of a Global Society on a Changing Planet In, 2020, pp. 209-224. , Plag HP, Pearlman M (eds), Springer, Berlin/Heidelberg; Heunecke, O., Auswertung des Ringversuchs auf der neuen Kalibrierbasis der UniBw München zur Bestimmung der Sollstrecken (2012) AVN, 2012 (1112), pp. 380-385; Hieta, T., Merimaa, M., Vainio, M., Seppä, J., Lassila, A., Highprecision diode-laser-based temperature measurement for air refractive index compensation (2011) Appl Opt, 50 (31), pp. 5990-5998; (2012) Optics and Optical Instruments – Field Procedures for Testing Geodetic and Surveying Instruments – Part 4: Electro-Optical Distance Meters (Edminstruments to Reflectors), , http://www.iso.org/iso/home/store/catalogue_tc/catalogue_detail.htm?csnumber=54624; (2008) Evaluation of Measurement Data - Guide to the Expression of Uncertainty in Measurement, , 1st edn. JCGM 100:2008; http://www.iso.org/sites/JCGM/GUM-introduction.htmJokela, J., Häkli, P., Interference measurements of the Nummela standard baseline in 2005 and 2007 (2010) Publications of the Finnish Geodetic Institute, 144. , Finnish Geodetic Institute, Kirkkonummi; Jokela, J., Häkli, P., Poutanen, M., Kallio, U., Ahola, J., Improving length and scale traceability in local geodynamical measurements (2012) Geodesy for Planet Earth, International Association of Geodesy Symposia, 136, pp. 59-66. , Kenyon S, Pacino MC, Marti U, Springer, Berlin/Heidelberg; (2013) JRP Surveying Project Webpage, , http://www.emrp-surveying.eu, Accessed 20 Dec 2013; Koivula, H., Häkli, P., Jokela, J., Buga, A., Putrimas, R., GPS metrology: Bringing traceable scale to a local crustal deformation GPS network (2012) Geodesy for Planet Earth, International Association of Geodesy Symposia, 136, pp. 105-112. , Kenyon S, Pacino MC, Marti U, Springer, Berlin/Heidelberg; Méchain, M., Delambre, M., (1806) Base De système métrique Decimal Ou Mesure De l’arc Du Meridian Compris Entre Les parallèles De Dunkerque Et Barcelone, Execute En 1792 Et années Suivantes, , Suite des Mémoires de l’institute, Tome Premier; Meiners-Hagen, K., Pollinger, F., Rückführbare Messung langer Distanzen in der PTB - Traceable measurements of long distances in the PTB (2012) AVN, 118 (809), pp. 283-290; Milne, G.A., Davis, J.L., Mitrovica, J.X., Scherneck, H.G., Johansson, J.M., Vermeer, M., Koivula, H., Space-geodetic constraints on glacial isostatic adjustment in Fennoscandia (2001) Science, 291 (5512), pp. 2381-2385; Nocquet, J., Walpersdorf, A., Jouanne, F., Masson, F., Chéry, J., Vernant P (2011) Slow deformation in the western alps from a decade of continuous GPS measurements (2011) Proceedings of 3Rd International Colloquium - Scientific and Fundamental Aspects of the Galileo Programme, , Copenhagen, 31 August–2 Sept; Plag, H., Pearlman, M., (2009) Global Geodetic Observing System Meeting the Requirements of a Global Society on a Changing Planet in 2020, , Springer, Berlin/Heidelberg; Pollinger, F., Meyer, T., Beyer, J., Doloca, N.R., Schellin, W., Niemeier, W., Jokela, J., Meiners-Hagen, K., The upgraded PTB 600 m baseline: A high-accuracy reference for the calibration and the development of long distance measurement devices (2012) Meas Sci Technol, 23, p. 9; Rothacher, M., Beutler, G., Behrend, D., Donellan, A., Hinderer, J., Ma, C., Noll, C., Woodworth, P.L., The future global geodeticobserving system (2009) Global Geodetic Observing System Meeting the Requirements of a Global Society on a Changing Planet In, 2020, pp. 237-273. , Plag HP, Pearlman M, Springer, Berlin/Heidelberg; Rüeger, J.M., (1996) Electronic Distance Measurement –an Introduction, , 4th edn. Springer, Berlin; Seeber, G., (2003) Satellite Geodesy, , 2nd edn. Walter de Gruyter, Berlin/New York; Wallerand, J.P., Abou-Zeid, A., Badr, T., Balling, P., Jokela, J., Kugler, R., Matus, M., Zucco, M., (2008) Towards new absolute long distance measurement in air, , NCSL International Workshop and Symposium, Orlando; Weinbach, U., Schön, S., GNSS receiver clock modeling when using high-precision oscillators and its impact on PPP (2011) Adv Space Res, 47 (2), pp. 229-238; Weiss, A., Hennes, M., Rotach, M., Derivation of the refractive index and temperature gradiens from optical scintillometry to correct atmospherically induced errors for highly precise geodetic measurements (2001) Surv Geophys, 22, pp. 589-596

Available from: 2016-12-22 Created: 2016-12-21 Last updated: 2016-12-22Bibliographically approved

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