169 lines
5.2 KiB
Python
169 lines
5.2 KiB
Python
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import numpy as np
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from scipy import signal
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def approximate_polygon(coords, tolerance):
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"""Approximate a polygonal chain with the specified tolerance.
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It is based on the Douglas-Peucker algorithm.
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Note that the approximated polygon is always within the convex hull of the
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original polygon.
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Parameters
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----------
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coords : (N, 2) array
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Coordinate array.
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tolerance : float
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Maximum distance from original points of polygon to approximated
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polygonal chain. If tolerance is 0, the original coordinate array
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is returned.
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Returns
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-------
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coords : (M, 2) array
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Approximated polygonal chain where M <= N.
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References
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----------
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.. [1] https://en.wikipedia.org/wiki/Ramer-Douglas-Peucker_algorithm
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"""
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if tolerance <= 0:
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return coords
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chain = np.zeros(coords.shape[0], 'bool')
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# pre-allocate distance array for all points
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dists = np.zeros(coords.shape[0])
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chain[0] = True
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chain[-1] = True
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pos_stack = [(0, chain.shape[0] - 1)]
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end_of_chain = False
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while not end_of_chain:
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start, end = pos_stack.pop()
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# determine properties of current line segment
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r0, c0 = coords[start, :]
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r1, c1 = coords[end, :]
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dr = r1 - r0
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dc = c1 - c0
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segment_angle = - np.arctan2(dr, dc)
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segment_dist = c0 * np.sin(segment_angle) + r0 * np.cos(segment_angle)
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# select points in-between line segment
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segment_coords = coords[start + 1:end, :]
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segment_dists = dists[start + 1:end]
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# check whether to take perpendicular or euclidean distance with
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# inner product of vectors
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# vectors from points -> start and end
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dr0 = segment_coords[:, 0] - r0
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dc0 = segment_coords[:, 1] - c0
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dr1 = segment_coords[:, 0] - r1
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dc1 = segment_coords[:, 1] - c1
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# vectors points -> start and end projected on start -> end vector
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projected_lengths0 = dr0 * dr + dc0 * dc
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projected_lengths1 = - dr1 * dr - dc1 * dc
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perp = np.logical_and(projected_lengths0 > 0,
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projected_lengths1 > 0)
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eucl = np.logical_not(perp)
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segment_dists[perp] = np.abs(
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segment_coords[perp, 0] * np.cos(segment_angle)
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+ segment_coords[perp, 1] * np.sin(segment_angle)
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- segment_dist
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)
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segment_dists[eucl] = np.minimum(
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# distance to start point
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np.sqrt(dc0[eucl] ** 2 + dr0[eucl] ** 2),
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# distance to end point
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np.sqrt(dc1[eucl] ** 2 + dr1[eucl] ** 2)
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)
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if np.any(segment_dists > tolerance):
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# select point with maximum distance to line
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new_end = start + np.argmax(segment_dists) + 1
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pos_stack.append((new_end, end))
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pos_stack.append((start, new_end))
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chain[new_end] = True
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if len(pos_stack) == 0:
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end_of_chain = True
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return coords[chain, :]
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# B-Spline subdivision
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_SUBDIVISION_MASKS = {
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# degree: (mask_even, mask_odd)
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# extracted from (degree + 2)th row of Pascal's triangle
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1: ([1, 1], [1, 1]),
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2: ([3, 1], [1, 3]),
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3: ([1, 6, 1], [0, 4, 4]),
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4: ([5, 10, 1], [1, 10, 5]),
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5: ([1, 15, 15, 1], [0, 6, 20, 6]),
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6: ([7, 35, 21, 1], [1, 21, 35, 7]),
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7: ([1, 28, 70, 28, 1], [0, 8, 56, 56, 8]),
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}
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def subdivide_polygon(coords, degree=2, preserve_ends=False):
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"""Subdivision of polygonal curves using B-Splines.
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Note that the resulting curve is always within the convex hull of the
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original polygon. Circular polygons stay closed after subdivision.
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Parameters
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----------
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coords : (N, 2) array
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Coordinate array.
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degree : {1, 2, 3, 4, 5, 6, 7}, optional
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Degree of B-Spline. Default is 2.
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preserve_ends : bool, optional
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Preserve first and last coordinate of non-circular polygon. Default is
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False.
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Returns
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-------
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coords : (M, 2) array
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Subdivided coordinate array.
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References
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----------
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.. [1] http://mrl.nyu.edu/publications/subdiv-course2000/coursenotes00.pdf
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"""
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if degree not in _SUBDIVISION_MASKS:
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raise ValueError("Invalid B-Spline degree. Only degree 1 - 7 is "
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"supported.")
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circular = np.all(coords[0, :] == coords[-1, :])
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method = 'valid'
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if circular:
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# remove last coordinate because of wrapping
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coords = coords[:-1, :]
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# circular convolution by wrapping boundaries
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method = 'same'
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mask_even, mask_odd = _SUBDIVISION_MASKS[degree]
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# divide by total weight
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mask_even = np.array(mask_even, np.float) / (2 ** degree)
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mask_odd = np.array(mask_odd, np.float) / (2 ** degree)
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even = signal.convolve2d(coords.T, np.atleast_2d(mask_even), mode=method,
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boundary='wrap')
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odd = signal.convolve2d(coords.T, np.atleast_2d(mask_odd), mode=method,
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boundary='wrap')
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out = np.zeros((even.shape[1] + odd.shape[1], 2))
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out[1::2] = even.T
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out[::2] = odd.T
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if circular:
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# close polygon
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out = np.vstack([out, out[0, :]])
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if preserve_ends and not circular:
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out = np.vstack([coords[0, :], out, coords[-1, :]])
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return out
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