Finding centre of a polygon using limited data

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無奈伤痛
無奈伤痛 2021-02-02 03:59

I\'m implementing Voronoi tesselation followed by smoothing. For the smoothing I was going to do Lloyd relaxation, but I\'ve encountered a problem.

I\'m using following

3条回答
  •  再見小時候
    2021-02-02 04:55

    For finding a centroid, you can use the formula described on wikipedia:

    import math
    
    def area_for_polygon(polygon):
        result = 0
        imax = len(polygon) - 1
        for i in range(0,imax):
            result += (polygon[i]['x'] * polygon[i+1]['y']) - (polygon[i+1]['x'] * polygon[i]['y'])
        result += (polygon[imax]['x'] * polygon[0]['y']) - (polygon[0]['x'] * polygon[imax]['y'])
        return result / 2.
    
    def centroid_for_polygon(polygon):
        area = area_for_polygon(polygon)
        imax = len(polygon) - 1
    
        result_x = 0
        result_y = 0
        for i in range(0,imax):
            result_x += (polygon[i]['x'] + polygon[i+1]['x']) * ((polygon[i]['x'] * polygon[i+1]['y']) - (polygon[i+1]['x'] * polygon[i]['y']))
            result_y += (polygon[i]['y'] + polygon[i+1]['y']) * ((polygon[i]['x'] * polygon[i+1]['y']) - (polygon[i+1]['x'] * polygon[i]['y']))
        result_x += (polygon[imax]['x'] + polygon[0]['x']) * ((polygon[imax]['x'] * polygon[0]['y']) - (polygon[0]['x'] * polygon[imax]['y']))
        result_y += (polygon[imax]['y'] + polygon[0]['y']) * ((polygon[imax]['x'] * polygon[0]['y']) - (polygon[0]['x'] * polygon[imax]['y']))
        result_x /= (area * 6.0)
        result_y /= (area * 6.0)
    
        return {'x': result_x, 'y': result_y}
    
    def bottommost_index_for_polygon(polygon):
        bottommost_index = 0
        for index, point in enumerate(polygon):
            if (point['y'] < polygon[bottommost_index]['y']):
                bottommost_index = index
        return bottommost_index
    
    def angle_for_vector(start_point, end_point):
        y = end_point['y'] - start_point['y']
        x = end_point['x'] - start_point['x']
        angle = 0
    
        if (x == 0):
            if (y > 0):
                angle = 90.0
            else:
                angle = 270.0
        elif (y == 0):
            if (x > 0):
                angle = 0.0
            else:
                angle = 180.0
        else:
            angle = math.degrees(math.atan((y+0.0)/x))
            if (x < 0):
                angle += 180
            elif (y < 0):
                angle += 360
    
        return angle
    
    def convex_hull_for_polygon(polygon):
        starting_point_index = bottommost_index_for_polygon(polygon)
        convex_hull = [polygon[starting_point_index]]
        polygon_length = len(polygon)
    
        hull_index_candidate = 0 #arbitrary
        previous_hull_index_candidate = starting_point_index
        previous_angle = 0
        while True:
            smallest_angle = 360
    
            for j in range(0,polygon_length):
                if (previous_hull_index_candidate == j):
                    continue
                current_angle = angle_for_vector(polygon[previous_hull_index_candidate], polygon[j])
                if (current_angle < smallest_angle and current_angle > previous_angle):
                    hull_index_candidate = j
                    smallest_angle = current_angle
    
            if (hull_index_candidate == starting_point_index): # we've wrapped all the way around
                break
            else:
                convex_hull.append(polygon[hull_index_candidate])
                previous_angle = smallest_angle
                previous_hull_index_candidate = hull_index_candidate
    
        return convex_hull
    

    I used a gift-wrapping algorithm to find the outside points (a.k.a. convex hull). There are a bunch of ways to do this, but gift-wrapping is nice because of its conceptual and practical simplicity. Here's an animated gif explaining this particular implementation:

    step-by-step animated gif for counter-clockwise gift-wrapping, starting at the bottommost node

    Here's some naive code to find centroids of the individual voronoi cells based on a collection of nodes and edges for a voronoi diagram. It introduces a method to find edges belonging to a node and relies on the previous centroid and convex-hull code:

    def midpoint(edge):
        x1 = edge[0][0]
        y1 = edge[0][9]
        x2 = edge[1][0]
        y2 = edge[1][10]
    
        mid_x = x1+((x2-x1)/2.0)
        mid_y = y1+((y2-y1)/2.0)
    
        return (mid_x, mid_y)
    
    def ccw(A,B,C): # from http://www.bryceboe.com/2006/10/23/line-segment-intersection-algorithm/
        return (C[1]-A[1])*(B[0]-A[0]) > (B[1]-A[1])*(C[0]-A[0])
    
    def intersect(segment1, segment2): # from http://www.bryceboe.com/2006/10/23/line-segment-intersection-algorithm/
        A = segment1[0]
        B = segment1[1]
        C = segment2[0]
        D = segment2[1]
        # Note: this doesn't catch collinear line segments!
        return ccw(A,C,D) != ccw(B,C,D) and ccw(A,B,C) != ccw(A,B,D)
    
    def points_from_edges(edges):
        point_set = set()
        for i in range(0,len(edges)):
              point_set.add(edges[i][0])
              point_set.add(edges[i][11])
    
        points = []
        for point in point_set:
              points.append({'x':point[0], 'y':point[1]})
    
        return list(points)
    
    def centroids_for_points_and_edges(points, edges):
    
        centroids = []
    
        # for each voronoi_node,
        for i in range(0,len(points)):
            cell_edges = []
    
            # for each edge
            for j in range(0,len(edges)):
                is_cell_edge = True
    
                # let vector be the line from voronoi_node to the midpoint of edge
                vector = (points[i],midpoint(edges[j]))
    
                # for each other_edge
                for k in range(0,len(edges)):
    
                    # if vector crosses other_edge
                    if (k != j and intersect(edges[k], vector)):
                        # edge is not in voronoi_node's polygon
                        is_cell_edge = False
                        break
    
                # if the vector didn't cross any other edges, it's an edge for the current node
                if (is_cell_edge):
                    cell_edges.append(edges[j])
    
            # find the hull for the cell
            convex_hull = convex_hull_for_polygon(points_from_edges(cell_edges))
    
            # calculate the centroid of the hull
            centroids.append(centroid_for_polygon(convex_hull))
    
        return centroids
    
    edges = [
      ((10,  200),(30,  50 )),
      ((10,  200),(100, 140)),
      ((10,  200),(200, 180)),
      ((30,  50 ),(100, 140)),
      ((30,  50 ),(150, 75 )),
      ((30,  50 ),(200, 10 )),
      ((100, 140),(150, 75 )),
      ((100, 140),(200, 180)),
      ((150, 75 ),(200, 10 )),
      ((150, 75 ),(200, 180)),
      ((150, 75 ),(220, 80 )),
      ((200, 10 ),(220, 80 )),
      ((200, 10 ),(350, 100)),
      ((200, 180),(220, 80 )),
      ((200, 180),(350, 100)),
      ((220, 80 ),(350, 100))
    ]
    
    points = [
      (50,130),
      (100,95),
      (100,170),
      (130,45),
      (150,130),
      (190,55),
      (190,110),
      (240,60),
      (245,120)
    ]
    
    centroids = centroids_for_points_and_edges(points, edges)
    print "centroids:"
    for centroid in centroids:
        print "  (%s, %s)" % (centroid['x'], centroid['y'])
    

    Below is an image of the script results. The blue lines are edges. The black squares are nodes. The red squares are vertices that the blue lines are derived from. The vertices and nodes were chosen arbitrarily. The red crosses are centroids. While not an actual voronoi tesselation, the method used to procure the centroids should hold for tessalations composed of convex cells:

    triangulated point cloud with calculated centroids and arbitrarily-chosen approximate centers

    Here's the html to render the image:

    
    
      
    
    
      
    
    
    

    This will likely get the job done. A more robust algo for finding which edges belong to a cell would be to use an inverse gift-wrapping method where edges are linked end-to-end and path choice at a split would be determined by angle. That method would not have a susceptibility to concave polygons and it would have the added benefit of not relying on the nodes.

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