Spatial algorithms and data structures (scipy.spatial
)¶
Spatial Transformations¶
Contained in the scipy.spatial.transform
submodule.
Nearest-neighbor Queries¶
KDTree (data[, leafsize]) |
kd-tree for quick nearest-neighbor lookup |
cKDTree (data[, leafsize, compact_nodes, …]) |
kd-tree for quick nearest-neighbor lookup |
Rectangle (maxes, mins) |
Hyperrectangle class. |
Distance metrics are contained in the scipy.spatial.distance
submodule.
Delaunay Triangulation, Convex Hulls and Voronoi Diagrams¶
Delaunay (points[, furthest_site, …]) |
Delaunay tessellation in N dimensions. |
ConvexHull (points[, incremental, qhull_options]) |
Convex hulls in N dimensions. |
Voronoi (points[, furthest_site, …]) |
Voronoi diagrams in N dimensions. |
SphericalVoronoi (points[, radius, center, …]) |
Voronoi diagrams on the surface of a sphere. |
HalfspaceIntersection (halfspaces, interior_point) |
Halfspace intersections in N dimensions. |
Plotting Helpers¶
delaunay_plot_2d (tri[, ax]) |
Plot the given Delaunay triangulation in 2-D |
convex_hull_plot_2d (hull[, ax]) |
Plot the given convex hull diagram in 2-D |
voronoi_plot_2d (vor[, ax]) |
Plot the given Voronoi diagram in 2-D |
See also
Simplex representation¶
The simplices (triangles, tetrahedra, …) appearing in the Delaunay tessellation (N-dim simplices), convex hull facets, and Voronoi ridges (N-1 dim simplices) are represented in the following scheme:
tess = Delaunay(points)
hull = ConvexHull(points)
voro = Voronoi(points)
# coordinates of the j-th vertex of the i-th simplex
tess.points[tess.simplices[i, j], :] # tessellation element
hull.points[hull.simplices[i, j], :] # convex hull facet
voro.vertices[voro.ridge_vertices[i, j], :] # ridge between Voronoi cells
For Delaunay triangulations and convex hulls, the neighborhood structure of the simplices satisfies the condition:
tess.neighbors[i,j]
is the neighboring simplex of the i-th simplex, opposite to the j-vertex. It is -1 in case of no neighbor.
Convex hull facets also define a hyperplane equation:
(hull.equations[i,:-1] * coord).sum() + hull.equations[i,-1] == 0
Similar hyperplane equations for the Delaunay triangulation correspond to the convex hull facets on the corresponding N+1 dimensional paraboloid.
The Delaunay triangulation objects offer a method for locating the simplex containing a given point, and barycentric coordinate computations.
Functions¶
tsearch (tri, xi) |
Find simplices containing the given points. |
distance_matrix (x, y[, p, threshold]) |
Compute the distance matrix. |
minkowski_distance (x, y[, p]) |
Compute the L**p distance between two arrays. |
minkowski_distance_p (x, y[, p]) |
Compute the p-th power of the L**p distance between two arrays. |
procrustes (data1, data2) |
Procrustes analysis, a similarity test for two data sets. |