1995
DOI: 10.1111/j.1365-246x.1995.tb06841.x
|View full text |Cite
|
Sign up to set email alerts
|

Geophysical parametrization and interpolation of irregular data using natural neighbours

Abstract: S U M M A R YAn approach is presented for interpolating a property of the Earth (for example temperature or seismic velocity) specified at a series of 'reference' points with arbitrary distribution in two or three dimensions. The method makes use of some powerful algorithms from the field of computational geometry to efficiently partition the medium into 'Delaunay' triangles (in 2-D) or tetrahedra (in 3-D) constructed around the irregularly spaced reference points. The field can then be smoothly interpolated a… Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
3
1
1

Citation Types

0
214
0
3

Year Published

1998
1998
2017
2017

Publication Types

Select...
6
2

Relationship

0
8

Authors

Journals

citations
Cited by 334 publications
(217 citation statements)
references
References 32 publications
(48 reference statements)
0
214
0
3
Order By: Relevance
“…In our database, the distance between points varies from 200 to c. 50,000 m. According to Sambridge et al (1995), the optimum grid spacing ranges between 100 and 25,000 m. If we used the former grid spacing, some artefacts would be created whereas using the latter would result in an appreciable loss of information. The adopted solution was to calculate the grid spacing from the weighted average distance between TIN nodes, which is 2000 m. See Ayala (2013) for a complete explanation of the procedure; further discussions about gridding can be found in previous work, for example, Rubio and Plata (1998); Smith and Wessel (1990); Sambridge et al (1995). The data are stored in both geographical coordinates (Longitude/Latitude; 10°W to 5°E, 35°50′ N to 44°N) and rectangular coordinates (UTM 30N in m; −75,000 to 113,600 easting, 3,980,000 to 4,871,000 northing), using the ETRS89 datum.…”
Section: Source Data and Methodologymentioning
confidence: 99%
See 2 more Smart Citations
“…In our database, the distance between points varies from 200 to c. 50,000 m. According to Sambridge et al (1995), the optimum grid spacing ranges between 100 and 25,000 m. If we used the former grid spacing, some artefacts would be created whereas using the latter would result in an appreciable loss of information. The adopted solution was to calculate the grid spacing from the weighted average distance between TIN nodes, which is 2000 m. See Ayala (2013) for a complete explanation of the procedure; further discussions about gridding can be found in previous work, for example, Rubio and Plata (1998); Smith and Wessel (1990); Sambridge et al (1995). The data are stored in both geographical coordinates (Longitude/Latitude; 10°W to 5°E, 35°50′ N to 44°N) and rectangular coordinates (UTM 30N in m; −75,000 to 113,600 easting, 3,980,000 to 4,871,000 northing), using the ETRS89 datum.…”
Section: Source Data and Methodologymentioning
confidence: 99%
“…The optimum grid spacing has been calculated using Esri ArcMap. As the stations of the database have extremely inhomogeneous distribution, to grid the data we have followed the steps described in Sambridge, Braun, and McQueen (1995): (a) create a triangulated mesh (called TIN, Triangular Irregular Networks); (b) estimate the best grid spacing and (c) grid TIN using the Natural Neighbour algorithm. In our database, the distance between points varies from 200 to c. 50,000 m. According to Sambridge et al (1995), the optimum grid spacing ranges between 100 and 25,000 m. If we used the former grid spacing, some artefacts would be created whereas using the latter would result in an appreciable loss of information.…”
Section: Source Data and Methodologymentioning
confidence: 99%
See 1 more Smart Citation
“…The NEM (Natural Element Method) interpolant is based on the Sibson's natural neighbor coordinates (shape functions) [3,10] and is constructed on the basis of the Voronoi diagram. For a set of nodes S = {n 1 , n 2 , .…”
Section: Headlines Of the Natural Element Methodsmentioning
confidence: 99%
“…For the generation of the regular grid v(x, z), we first have to know in which triangle a particular gridpoint is located, and then to interpolate within this triangle. The efficient search of the encircling triangle is performed by the walking triangle or trifind algorithm (Lawson 1977;Lee & Schachter 1980;Sambridge et al 1995) without the need to check all triangles. The interpolation within a particular triangle is done by barycentric interpolation well known from computer graphics (e.g.…”
Section: O D E L Pa R a M E T R I Z At I O Nmentioning
confidence: 99%