Position resection and intersection: Difference between revisions

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Revision as of 00:22, 30 January 2023 edit Fgnievinski (talk \| contribs) Autopatrolled, Extended confirmed users 71,091 edits →In surveying Tag: 2017 wikitext editor ← Previous edit		Latest revision as of 14:44, 27 July 2023 edit undo 85.148.89.96 (talk) →See also
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Line 21: {{see also\|Triangulation (surveying)}} In surveying work,<ref>Glossary of the Mapping Sciences, American Society of Civil Engineers, page 451. [https://books.google.com/books?id=jPVxSDzVRP0C&~~lpg~~q=~~PA451&ots=n6eSezdwrn&dq=Cassini's%20resection~~resection&pg=PA450~~#v=onepage&q=resection&f=false~~]</ref> the most common methods of computing the [[coordinate]]s of a point by '''angular resection''' are the '''Collin's "Q" point method''' (after [[John Collins (mathematician)\|John Collins]]) as well as the '''Cassini's Method''' (after [[Giovanni Domenico Cassini]]) and the ''[[Tienstra formula]]'', though the first known solution was given by [[Willebrord Snellius]] (see [[Snellius–Pothenot problem]]). For the type of precision work involved in surveying, the unmapped point is located by measuring the angles subtended by lines of sight from it to a minimum of three mapped (coordinated) points. In [[geodesy\|geodetic]] operations the observations are adjusted for [[spherical excess]] and [[projection variation]]s. Precise angular measurements between lines from the point under ___location using [[theodolite]]s provides more accurate results, with trig beacons erected on high points and hills to enable quick and unambiguous sights to known points. Line 34: * [[Hansen's problem]] * [[Intersection (aeronautics)]] * [[Orienteering]]▼ * [[Orienteering compass]] * [[Position line]] ▲* [[Orienteering]] * [[Real time locating]] * [[Solving triangles]]