I have a set of points in an example ASCII file showing a 2D image.
I would like to estimate the total area that these points are filling. There are some places inside this plane that are not filled by any point because these regions have been masked out. What I guess might be practical for estimating the area would be applying a concave hull or alpha shapes.
I tried this approach to find an appropriate
alpha value, and consequently estimate the area.
from shapely.ops import cascaded_union, polygonize import shapely.geometry as geometry from scipy.spatial import Delaunay import numpy as np import pylab as pl from descartes import PolygonPatch from matplotlib.collections import LineCollection def plot_polygon(polygon): fig = pl.figure(figsize=(10,10)) ax = fig.add_subplot(111) margin = .3 x_min, y_min, x_max, y_max = polygon.bounds ax.set_xlim([x_min-margin, x_max+margin]) ax.set_ylim([y_min-margin, y_max+margin]) patch = PolygonPatch(polygon, fc='#999999', ec='#000000', fill=True, zorder=-1) ax.add_patch(patch) return fig def alpha_shape(points, alpha): if len(points) < 4: # When you have a triangle, there is no sense # in computing an alpha shape. return geometry.MultiPoint(list(points)).convex_hull def add_edge(edges, edge_points, coords, i, j): """ Add a line between the i-th and j-th points, if not in the list already """ if (i, j) in edges or (j, i) in edges: # already added return edges.add( (i, j) ) edge_points.append(coords[ [i, j] ]) coords = np.array([point.coords for point in points]) tri = Delaunay(coords) edges = set() edge_points =  # loop over triangles: # ia, ib, ic = indices of corner points of the # triangle for ia, ib, ic in tri.vertices: pa = coords[ia] pb = coords[ib] pc = coords[ic] # Lengths of sides of triangle a = np.sqrt((pa-pb)**2 + (pa-pb)**2) b = np.sqrt((pb-pc)**2 + (pb-pc)**2) c = np.sqrt((pc-pa)**2 + (pc-pa)**2) # Semiperimeter of triangle s = (a + b + c)/2.0 # Area of triangle by Heron's formula area = np.sqrt(s*(s-a)*(s-b)*(s-c)) circum_r = a*b*c/(4.0*area) # Here's the radius filter. #print circum_r if circum_r < 1.0/alpha: add_edge(edges, edge_points, coords, ia, ib) add_edge(edges, edge_points, coords, ib, ic) add_edge(edges, edge_points, coords, ic, ia) m = geometry.MultiLineString(edge_points) triangles = list(polygonize(m)) return cascaded_union(triangles), edge_points points= with open("test.asc") as f: for line in f: coords=map(float,line.split(" ")) points.append(geometry.shape(geometry.Point(coords,coords))) print geometry.Point(coords,coords) x = [p.x for p in points] y = [p.y for p in points] pl.figure(figsize=(10,10)) point_collection = geometry.MultiPoint(list(points)) point_collection.envelope convex_hull_polygon = point_collection.convex_hull _ = plot_polygon(convex_hull_polygon) _ = pl.plot(x,y,'o', color='#f16824') concave_hull, edge_points = alpha_shape(points, alpha=0.001) lines = LineCollection(edge_points) _ = plot_polygon(concave_hull) _ = pl.plot(x,y,'o', color='#f16824')
My question is what is the best way to estimate an area of the aforementioned shape? I can not figure out what has gone wrong that this code doesn't work properly?!! Any help will be appreciated.