The function surface_neighbor_coordinates_3 computes natural neighbor coordinates for surface points associated to a finite set of sample points issued from the surface. The coordinates are computed from the intersection of the Voronoi cell of the query point p with the tangent plane to the surface at p. If the sampling is sufficiently dense, the coordinate system meets the properties described in the manual pages and in [BF02],[Flö03b]. The query point p needs to lie inside the convex hull of the projection of the sample points onto the tangent plane at p.
#include <CGAL/surface_neighbor_coordinates_3.h>
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The sample points $$ are provided in the range
$$[.first, beyond$$.).
InputIterator::value_type is the point type
Kernel::Point_3. The tangent plane is defined by the point
p and the vector normal. The parameter K
determines the kernel type that will instantiate
the template parameter of Voronoi_intersection_2_traits_3<K>. The natural neighbor coordinates for p are computed in the power diagram that results from the intersection of the $$3D Voronoi diagram of $$ with the tangent plane. The sequence of point/coordinate pairs that is computed by the function is placed starting at out. The function returns a triple with an iterator that is placed past-the-end of the resulting sequence of point/coordinate pairs, the normalization factor of the coordinates and a boolean value which is set to true iff the coordinate computation was successful, i.e. if p lies inside the convex hull of the projection of the points $$ onto the tangent plane. | ||||
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the same as above only that the traits class must be instantiated by the user. ITraits must be equivalent to Voronoi_intersection_2_traits_3<K>. |
The next functions return, in addition, a second boolean value (the fourth value of the quadrupel) that certifies whether or not, the Voronoi cell of p can be affected by points that lie outside the input range, i.e. outside the ball centered on p passing through the furthest sample point from p in the range $$[.first, beyond$$.). If the sample points are collected by a $$k-nearest neighbor or a range search query, this permits to check whether the neighborhood which has been considered is large enough.
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Similar to the first function. The additional fourth return value is true if the furthest point in the range $$[.first, beyond$$.) is further away from p than twice the distance from p to the furthest vertex of the intersection of the Voronoi cell of p with the tangent plane defined by (p,normal). It is false otherwise. | ||||
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The same as above except that this function takes the maximal distance from p to the points in the range $$[.first, beyond$$.) as additional parameter. | ||||
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The same as above only that the traits class must be instantiated by the user and without the parameter max_distance. ITraits must be equivalent to Voronoi_intersection_2_traits_3<K>. | ||||
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The same as above with the parameter max_distance. |
The next function allows to filter some potential neighbors of the query point p from $$ via its three-dimensional Delaunay triangulation. All surface neighbors of p are necessarily neighbors in the Delaunay triangulation of $$ {p}.
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computes the surface neighbor coordinates with respect to the points that are vertices of the Delaunay triangulation dt. The type Dt must be equivalent to Delaunay_triangulation_3<Gt, Tds>. The optional parameter start is used as a starting place for the search of the conflict zone. It may be the result of the call dt.locate(p). This function instantiates the template parameter ITraits to be Voronoi_intersection_2_traits_3<Dt::Geom_traits>. | ||||
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The same as above only that the parameter traits instantiates the geometric traits class. Its type ITraits must be equivalent to Voronoi_intersection_2_traits_3<K>. |