Proceedings of the International Scientific Conference The Fifth Technological Order: Prospects for the Development and Modernization of the Russian Agro-Industrial Sector (TFTS 2019)

<Previous Article In Volume
Next Article In Volume>

Analysis of Geodetic Latitude Calculation Algorithms Using Chord Method

Authors
Pavel Medvedev, Anatoly Uvarov, Alexander Garagul
Corresponding Author
Pavel Medvedev
Available Online 29 January 2020.
DOI
10.2991/assehr.k.200113.179How to use a DOI?
Keywords
geodetic and rectangular spatial coordinates, ellipsoid, algorithms, chord method, latitude, formula errors
Abstract

This article is an extension of investigation performed by the authors earlier, on the transformation of spatial rectangular coordinates X, Y, Z into geodetic curvilinear ones: latitude B, longitude L, height H. To calculate geodetic latitude B and reduced latitude U by solving a transcendental equation with variable coefficients f(t)This article is an extension of investigation performed by the authors earlier, on the transformation of spatial rectangular coordinates X, Y, Z into geodetic curvilinear ones: latitude B, longitude L, height H. To calculate geodetic latitude B and reduced latitude U by solving a transcendental equation with variable coefficients f(t)=0, where tThis article is an extension of investigation performed by the authors earlier, on the transformation of spatial rectangular coordinates X, Y, Z into geodetic curvilinear ones: latitude B, longitude L, height H. To calculate geodetic latitude B and reduced latitude U by solving a transcendental equation with variable coefficients f(t)=0, where t=tgU, a chord method was applied for the segment This article is an extension of investigation performed by the authors earlier, on the transformation of spatial rectangular coordinates X, Y, Z into geodetic curvilinear ones: latitude B, longitude L, height H. To calculate geodetic latitude B and reduced latitude U by solving a transcendental equation with variable coefficients f(t)=0, where t=tgU, a chord method was applied for the segment [T1, T2]; T1=tgu1; T-; T-=tgu2. It is mathematically proved that the algorithm constructed on this segment using chord method will be valid only for points on the earth’s surface with heights above sea level and with maximum error ΔB; T-=tgu2. It is mathematically proved that the algorithm constructed on this segment using chord method will be valid only for points on the earth’s surface with heights above sea level and with maximum error ΔB=0. 0017”. To expand the limits of algorithm and to increase its accuracy, the segment of root location ; T-=tgu2. It is mathematically proved that the algorithm constructed on this segment using chord method will be valid only for points on the earth’s surface with heights above sea level and with maximum error ΔB=0. 0017”. To expand the limits of algorithm and to increase its accuracy, the segment of root location [T1, T2] is reduced on the right to the value of ] is reduced on the right to the value of [T1, T6] where the latitude is determined not only for H>0 but also for H<0. The general formula of chords is transformed to a convenient for calculations form by introducing auxiliary quantities. Its accuracy was estimated and a comparative analysis with the previously obtained algorithm on segment ] where the latitude is determined not only for H>0 but also for H<0. The general formula of chords is transformed to a convenient for calculations form by introducing auxiliary quantities. Its accuracy was estimated and a comparative analysis with the previously obtained algorithm on segment [T3, T2] was performed. As a result of a two-sided reduction of interval ] was performed. As a result of a two-sided reduction of interval [T1, T2], segment ], segment [T3, T6], segment [T3, T6] is obtained where the root of equation will be located only for H>0. It was proved that in order to calculate latitude for points of the earth’s surface for ], segment [T3, T6] is obtained where the root of equation will be located only for H>0. It was proved that in order to calculate latitude for points of the earth’s surface for |H], segment [T3, T6] is obtained where the root of equation will be located only for H>0. It was proved that in order to calculate latitude for points of the earth’s surface for |H| ≤ 10 km in non-iterative way using chord method, it was reasonable to use an algorithm constructed on segment ], segment [T3, T6] is obtained where the root of equation will be located only for H>0. It was proved that in order to calculate latitude for points of the earth’s surface for |H| ≤ 10 km in non-iterative way using chord method, it was reasonable to use an algorithm constructed on segment [T3, T2], segment [T3, T6] is obtained where the root of equation will be located only for H>0. It was proved that in order to calculate latitude for points of the earth’s surface for |H| ≤ 10 km in non-iterative way using chord method, it was reasonable to use an algorithm constructed on segment [T3, T2], and for near-Earth space points at H>a, calculations should be carried out according to the algorithm constructed on segment ], segment [T3, T6] is obtained where the root of equation will be located only for H>0. It was proved that in order to calculate latitude for points of the earth’s surface for |H| ≤ 10 km in non-iterative way using chord method, it was reasonable to use an algorithm constructed on segment [T3, T2], and for near-Earth space points at H>a, calculations should be carried out according to the algorithm constructed on segment [T1, T6], segment [T3, T6] is obtained where the root of equation will be located only for H>0. It was proved that in order to calculate latitude for points of the earth’s surface for |H| ≤ 10 km in non-iterative way using chord method, it was reasonable to use an algorithm constructed on segment [T3, T2], and for near-Earth space points at H>a, calculations should be carried out according to the algorithm constructed on segment [T1, T6].

Copyright
© 2020, the Authors. Published by Atlantis Press.
Open Access
This is an open access article distributed under the CC BY-NC license (http://creativecommons.org/licenses/by-nc/4.0/).

Download article (PDF)

<Previous Article In Volume
Next Article In Volume>
Volume Title
Proceedings of the International Scientific Conference The Fifth Technological Order: Prospects for the Development and Modernization of the Russian Agro-Industrial Sector (TFTS 2019)
Series
Advances in Social Science, Education and Humanities Research
Publication Date
29 January 2020
ISBN
10.2991/assehr.k.200113.179
ISSN
2352-5398
DOI
10.2991/assehr.k.200113.179How to use a DOI?
Copyright
© 2020, the Authors. Published by Atlantis Press.
Open Access
This is an open access article distributed under the CC BY-NC license (http://creativecommons.org/licenses/by-nc/4.0/).

Cite this article

risenwbib
TY  - CONF
AU  - Pavel Medvedev
AU  - Anatoly Uvarov
AU  - Alexander Garagul
PY  - 2020
DA  - 2020/01/29
TI  - Analysis of Geodetic Latitude Calculation Algorithms Using Chord Method
BT  - Proceedings of the International Scientific Conference The Fifth Technological Order: Prospects for the Development and Modernization of the Russian Agro-Industrial Sector (TFTS 2019)
PB  - Atlantis Press
SP  - 248
EP  - 251
SN  - 2352-5398
UR  - https://doi.org/10.2991/assehr.k.200113.179
DO  - 10.2991/assehr.k.200113.179
ID  - Medvedev2020
ER  -