Опрацювання результатів вимірювань довжини для звірень або калібрувань віддалемірів і тахеометрів на польовому компараторі

Simple item page
dc.citation.epage28
dc.citation.issue90
dc.citation.journalTitleГеодезія, картографія і аерофотознімання
dc.citation.spage15
dc.contributor.affiliationДП “УКРМЕТРТЕСТСТАНДАРТ”
dc.contributor.affiliationResearch and Production Institute SE “UKRMETRTESTSTANDART”
dc.contributor.authorСамойленко, О. М.
dc.contributor.authorАдаменко, О. М.
dc.contributor.authorSamoilenko, O.
dc.contributor.authorAdamenko, O.
dc.coverage.placenameЛьвів
dc.coverage.placenameLviv
dc.date.accessioned2023-02-13T10:51:23Z
dc.date.available2023-02-13T10:51:23Z
dc.date.created2019-03-12
dc.date.issued2019-03-12
dc.description.abstractРозроблено методику зрівнювання результатів вимірювань довжини під час калібрування польового компаратора для повірки (калібрування) віддалемірів та віддалемірної частини тахеометрів. На її основі також створено методику опрацювання результатів звірень еталонних віддалемірів на польовому компараторі за методом найменших квадратів (МНК). За МНК оцінюють адитивні систематичні зміщення вимірювань довжини кожним віддалеміром та систематичні зміщення, які вносить у результати вимірювань довжини кожний відбивач. Також визначають мультиплікативні ступені еквівалентності віддалемірів. Під час калібрувань польових компараторів систематичні зміщення та ступені еквівалентності, одержані під час звірень віддалемірів, потрібно використовувати як поправлення. За МНК оцінюють невизначеність за типом А значень довжини ліній польового компаратора, а також систематичних зміщень вимірювань віддалемірами.
dc.description.abstractA method has been developed for the adjustment of the results of measurements of length during calibration of a field comparator for verification (calibration) of distance meters and distance metric parts of total stations. The method of processing the results of comparisons of distance meters to the field comparator using the least squares method (LSM) was also developed on its basis. The additive biases of length measurements by each distance meter are evaluated according to the LSM, as well as the biases that are entered to the results of length measurements by each reflector. Multiplicative degrees of equivalence of the distance meters are also calculated. During calibrations of field comparators, the biases and degrees of equivalence, obtained during the comparisons of distance meters, should be used as corrections. According to the LSM, the uncertainty is evaluated by type A of the value of the length of the field comparator lines, as well as the biases of measurements by distance meters.
dc.format.extent15-28
dc.format.pages14
dc.identifier.citationСамойленко О. М. Опрацювання результатів вимірювань довжини для звірень або калібрувань віддалемірів і тахеометрів на польовому компараторі / О. М. Самойленко, О. М. Адаменко // Геодезія, картографія і аерофотознімання. — Львів : Видавництво Львівської політехніки, 2019. — № 90. — С. 15–28.
dc.identifier.citationenSamoilenko O. Processing of the length measuring results during comparisons or calibrations the distance meters and total stations on a field comparator / O. Samoilenko, O. Adamenko // Geodesy, cartography and aerial photography. — Lviv : Lviv Politechnic Publishing House, 2019. — No 90. — P. 15–28.
dc.identifier.doidoi.org/10.23939/istcgcap2019.90.015
dc.identifier.urihttps://ena.lpnu.ua/handle/ntb/57346
dc.language.isouk
dc.publisherВидавництво Львівської політехніки
dc.publisherLviv Politechnic Publishing House
dc.relation.ispartofГеодезія, картографія і аерофотознімання, 90, 2019
dc.relation.ispartofGeodesy, cartography and aerial photography, 90, 2019
dc.relation.referencesBraun, J., Dvořáček, F., & Štroner, M. (2014). Absolute Baseline for Testing of Electronic Distance Meters. Geoinformatics FCE CTU, 12, 28–33.
dc.relation.referencesCox, M. G. (2002). The evaluation of key comparison data: An introduction. Metrologia, 39(6), 587.
dc.relation.referencesISO 17123-4:2012. Optics and optical instruments – Field procedures for testing geodetic and surveying instruments. Part 4: Electro-optical distance meter (EDM measurements to reflectors).
dc.relation.referencesJCGM 100:2008 Evaluation of Measurement Data–Guide to the Expression of Uncertainty in Measurement. Joint Committee for Guides in Metrology. Retrieved from:
dc.relation.referenceshttps://www.bipm.org/utils/common/documents/-jcgm/JCGM_100_2008_E.pdf
dc.relation.referencesJCGM 200:2012 International vocabulary of metrology – Basic and general concepts and associated terms (VIM). Joint Committee for Guides in Metrology.Retrieved from:
dc.relation.referenceshttps://www.bipm.org/utils/common/documents/-jcgm/JCGM_200_2012_E.pdf
dc.relation.referencesJCGM 102:2011. Evaluation of measurement data – Supplement 2 to the “Guide to the expression of uncertainty in measurement” Extension to any number of output quantities. Joint Committee for Guides in Metrology.
dc.relation.referencesRetrieved from: https://www.bipm.org/utils/common/documents/-jcgm/JCGM_102_2011_E.pdf
dc.relation.referencesJokela, J., Häkli, P., Ahola, J., Buga, A., & Putrimas, R. (2009, September). On traceability of long distances. In Proceedings of XIX IMEKO World Congress, Fundamental and Applied Metrology (pp. 6-11).
dc.relation.referencesJokela, J., Häkli, P., Kugler, R., Skorpil, H., Matus, M., & Poutanen, M. (2010, April). Calibration of the BEV geodetic baseline. In FIG Congress 2010(pp. 2873–87).
dc.relation.referencesJRP SIB 60 Metrology for long distance surveying. Retrieved from: http://www.ptb.de/emrp/sib60-home.html.
dc.relation.referencesKostetskaya, Y. M. (1986). Light and radio distance meters. Lviv: High school Publishing house, p. 264.
dc.relation.referencesKravchenko, N. I. (2004). Methods and tools for metrological support of linear measurements at Ukraine’s geodynamic test ranges. Ukrainian Metrology Journal, 2, 23–28.
dc.relation.referencesKupko, V., Prokopov, O., Lukin, I., Sobol, V., Kosenko, O., Kofman, O. (2004). National Standard Linear Geodetic Range. Modern Achievements of Geodesic Science and Production: Proc. sciences. works. Lviv, 98–104.
dc.relation.referencesKuzmenko, Yu., Samoilenko, O. (2018). Processing by the method of least squares of measurement results for key, regional and additional comparisons of standards. Metrology and devices. Kharkiv: “Favor” VKF, no. 2.
dc.relation.referencesLawson, R. (1986). Henson Solving Least Squares Problems/Trans. from English. Moscow: Science. Head Editor phys.-mat. lit., 232 p.
dc.relation.referencesNielsen, L. (2003). Identification and handling of discrepant measurements in key comparisons. Measurement Techniques, 46(5), 513–522. Retrieved from: https://doi.org/10.1023/A:1025373701977
dc.relation.referencesNielsen, L. (2000). Evaluation of measurement intercomparisons by the method of least squares. Danish Institute of Fundamental Metrology, Technical Report DFM-99-R39.
dc.relation.referencesPollinger, F., Meyer, T., Beyer, J., Doloca, N. R., Schellin, W., Niemeier, W., ... & Meiners-Hagen, K. (2012). The upgraded PTB 600 m baseline: a highaccuracy reference for the calibration and the development of long
dc.relation.referencesdistance measurement devices. Measurement Science and Technology, 23(9), 094018.
dc.relation.referencesRaishmann, S. (2010). Accreditation inspires confidence. Retrieved from: https://w3.leica-geosystems.com/media/new/product_solution/Reporter63_MAG_201009_ru.pdf]
dc.relation.referencesSamoilenko, O. M., Berezan, I. O. (2008). Reduction of measured lengths and zenith distances to averaged values of meteorological parameters of the atmosphere and to reference points of a local geodetic network.
dc.relation.referencesThe engineering geodesy. Kyiv: “Builder”, 54, 190–200.
dc.relation.referencesTrevoho, I., Savchuk, S., Denysov, A., Volchko, P. (2004). New exemplary geodetic basis. Herald of Geodesy and Cartography. 1, 12–16.
dc.relation.referencesTrevoho, I., Denysov, A., Tsyupak, I., Heger, V., Timchuk, V. (2010). Standard geodesic basis of original construction. Modern achievements of geodesic science and production. Lviv: LeaguePress, 1 (19), 43–49.
dc.relation.referencesTrevoho, I., & Tsyupak, I. (2014). Features metrological certification standard geodetic basis. Modern achievements of geodesic science and production. Lviv: 1 (27), 29–33.
dc.relation.referencesenBraun, J., Dvořáček, F., & Štroner, M. (2014). Absolute Baseline for Testing of Electronic Distance Meters. Geoinformatics FCE CTU, 12, 28–33.
dc.relation.referencesenCox, M. G. (2002). The evaluation of key comparison data: An introduction. Metrologia, 39(6), 587.
dc.relation.referencesenISO 17123-4:2012. Optics and optical instruments – Field procedures for testing geodetic and surveying instruments. Part 4: Electro-optical distance meter (EDM measurements to reflectors).
dc.relation.referencesenJCGM 100:2008 Evaluation of Measurement Data–Guide to the Expression of Uncertainty in Measurement. Joint Committee for Guides in Metrology. Retrieved from:
dc.relation.referencesenhttps://www.bipm.org/utils/common/documents/-jcgm/JCGM_100_2008_E.pdf
dc.relation.referencesenJCGM 200:2012 International vocabulary of metrology – Basic and general concepts and associated terms (VIM). Joint Committee for Guides in Metrology.Retrieved from:
dc.relation.referencesenhttps://www.bipm.org/utils/common/documents/-jcgm/JCGM_200_2012_E.pdf
dc.relation.referencesenJCGM 102:2011. Evaluation of measurement data – Supplement 2 to the "Guide to the expression of uncertainty in measurement" Extension to any number of output quantities. Joint Committee for Guides in Metrology.
dc.relation.referencesenRetrieved from: https://www.bipm.org/utils/common/documents/-jcgm/JCGM_102_2011_E.pdf
dc.relation.referencesenJokela, J., Häkli, P., Ahola, J., Buga, A., & Putrimas, R. (2009, September). On traceability of long distances. In Proceedings of XIX IMEKO World Congress, Fundamental and Applied Metrology (pp. 6-11).
dc.relation.referencesenJokela, J., Häkli, P., Kugler, R., Skorpil, H., Matus, M., & Poutanen, M. (2010, April). Calibration of the BEV geodetic baseline. In FIG Congress 2010(pp. 2873–87).
dc.relation.referencesenJRP SIB 60 Metrology for long distance surveying. Retrieved from: http://www.ptb.de/emrp/sib60-home.html.
dc.relation.referencesenKostetskaya, Y. M. (1986). Light and radio distance meters. Lviv: High school Publishing house, p. 264.
dc.relation.referencesenKravchenko, N. I. (2004). Methods and tools for metrological support of linear measurements at Ukraine’s geodynamic test ranges. Ukrainian Metrology Journal, 2, 23–28.
dc.relation.referencesenKupko, V., Prokopov, O., Lukin, I., Sobol, V., Kosenko, O., Kofman, O. (2004). National Standard Linear Geodetic Range. Modern Achievements of Geodesic Science and Production: Proc. sciences. works. Lviv, 98–104.
dc.relation.referencesenKuzmenko, Yu., Samoilenko, O. (2018). Processing by the method of least squares of measurement results for key, regional and additional comparisons of standards. Metrology and devices. Kharkiv: "Favor" VKF, no. 2.
dc.relation.referencesenLawson, R. (1986). Henson Solving Least Squares Problems/Trans. from English. Moscow: Science. Head Editor phys.-mat. lit., 232 p.
dc.relation.referencesenNielsen, L. (2003). Identification and handling of discrepant measurements in key comparisons. Measurement Techniques, 46(5), 513–522. Retrieved from: https://doi.org/10.1023/A:1025373701977
dc.relation.referencesenNielsen, L. (2000). Evaluation of measurement intercomparisons by the method of least squares. Danish Institute of Fundamental Metrology, Technical Report DFM-99-R39.
dc.relation.referencesenPollinger, F., Meyer, T., Beyer, J., Doloca, N. R., Schellin, W., Niemeier, W., ... & Meiners-Hagen, K. (2012). The upgraded PTB 600 m baseline: a highaccuracy reference for the calibration and the development of long
dc.relation.referencesendistance measurement devices. Measurement Science and Technology, 23(9), 094018.
dc.relation.referencesenRaishmann, S. (2010). Accreditation inspires confidence. Retrieved from: https://w3.leica-geosystems.com/media/new/product_solution/Reporter63_MAG_201009_ru.pdf]
dc.relation.referencesenSamoilenko, O. M., Berezan, I. O. (2008). Reduction of measured lengths and zenith distances to averaged values of meteorological parameters of the atmosphere and to reference points of a local geodetic network.
dc.relation.referencesenThe engineering geodesy. Kyiv: "Builder", 54, 190–200.
dc.relation.referencesenTrevoho, I., Savchuk, S., Denysov, A., Volchko, P. (2004). New exemplary geodetic basis. Herald of Geodesy and Cartography. 1, 12–16.
dc.relation.referencesenTrevoho, I., Denysov, A., Tsyupak, I., Heger, V., Timchuk, V. (2010). Standard geodesic basis of original construction. Modern achievements of geodesic science and production. Lviv: LeaguePress, 1 (19), 43–49.
dc.relation.referencesenTrevoho, I., & Tsyupak, I. (2014). Features metrological certification standard geodetic basis. Modern achievements of geodesic science and production. Lviv: 1 (27), 29–33.
dc.relation.urihttps://www.bipm.org/utils/common/documents/-jcgm/JCGM_100_2008_E.pdf
dc.relation.urihttps://www.bipm.org/utils/common/documents/-jcgm/JCGM_200_2012_E.pdf
dc.relation.urihttps://www.bipm.org/utils/common/documents/-jcgm/JCGM_102_2011_E.pdf
dc.relation.urihttp://www.ptb.de/emrp/sib60-home.html
dc.relation.urihttps://doi.org/10.1023/A:1025373701977
dc.relation.urihttps://w3.leica-geosystems.com/media/new/product_solution/Reporter63_MAG_201009_ru.pdf
dc.rights.holder© Національний університет “Львівська політехніка”, 2019
dc.subjectеталон
dc.subjectзвірення
dc.subjectкалібрування
dc.subjectвіддалемір
dc.subjectтахеометр
dc.subjectпольовий компаратор
dc.subjectадитивні зміщення
dc.subjectмультиплікативні ступені еквівалентності
dc.subjectневизначеність
dc.subjectmeasuring standard
dc.subjectcomparison
dc.subjectcalibration
dc.subjectdistance meter
dc.subjecttotalstation
dc.subjectfield comparator
dc.subjectadditive biases
dc.subjectmultiplicative degree of equivalence
dc.subjectuncertainty
dc.subject.udc51-74
dc.titleОпрацювання результатів вимірювань довжини для звірень або калібрувань віддалемірів і тахеометрів на польовому компараторі
dc.title.alternativeProcessing of the length measuring results during comparisons or calibrations the distance meters and total stations on a field comparator
dc.typeArticle

Files

Original bundle

Now showing 1 - 2 of 2
Thumbnail Image
Name:
2019n90_Samoilenko_O-Processing_of_the_length_15-28.pdf
Size:
528.79 KB
Format:
Adobe Portable Document Format
Download
Thumbnail Image
Name:
2019n90_Samoilenko_O-Processing_of_the_length_15-28__COVER.png
Size:
454.36 KB
Format:
Portable Network Graphics
Download

License bundle

Now showing 1 - 1 of 1
No Thumbnail Available
Name:
license.txt
Size:
1.81 KB
Format:
Plain Text
Description:
Download

Collections

Геодезія, картографія і аерофотознімання. – 2019. – Випуск 90