338 lines
12 KiB
Python
338 lines
12 KiB
Python
import numpy as np
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from scipy.ndimage import distance_transform_edt as distance
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def _cv_curvature(phi):
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"""Returns the 'curvature' of a level set 'phi'.
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"""
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P = np.pad(phi, 1, mode='edge')
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fy = (P[2:, 1:-1] - P[:-2, 1:-1]) / 2.0
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fx = (P[1:-1, 2:] - P[1:-1, :-2]) / 2.0
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fyy = P[2:, 1:-1] + P[:-2, 1:-1] - 2*phi
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fxx = P[1:-1, 2:] + P[1:-1, :-2] - 2*phi
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fxy = .25 * (P[2:, 2:] + P[:-2, :-2] - P[:-2, 2:] - P[2:, :-2])
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grad2 = fx**2 + fy**2
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K = ((fxx*fy**2 - 2*fxy*fx*fy + fyy*fx**2) /
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(grad2*np.sqrt(grad2) + 1e-8))
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return K
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def _cv_calculate_variation(image, phi, mu, lambda1, lambda2, dt):
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"""Returns the variation of level set 'phi' based on algorithm parameters.
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"""
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eta = 1e-16
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P = np.pad(phi, 1, mode='edge')
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phixp = P[1:-1, 2:] - P[1:-1, 1:-1]
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phixn = P[1:-1, 1:-1] - P[1:-1, :-2]
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phix0 = (P[1:-1, 2:] - P[1:-1, :-2]) / 2.0
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phiyp = P[2:, 1:-1] - P[1:-1, 1:-1]
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phiyn = P[1:-1, 1:-1] - P[:-2, 1:-1]
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phiy0 = (P[2:, 1:-1] - P[:-2, 1:-1]) / 2.0
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C1 = 1. / np.sqrt(eta + phixp**2 + phiy0**2)
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C2 = 1. / np.sqrt(eta + phixn**2 + phiy0**2)
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C3 = 1. / np.sqrt(eta + phix0**2 + phiyp**2)
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C4 = 1. / np.sqrt(eta + phix0**2 + phiyn**2)
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K = (P[1:-1, 2:] * C1 + P[1:-1, :-2] * C2 +
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P[2:, 1:-1] * C3 + P[:-2, 1:-1] * C4)
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Hphi = 1 * (phi > 0)
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(c1, c2) = _cv_calculate_averages(image, Hphi)
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difference_from_average_term = (- lambda1 * (image-c1)**2 +
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lambda2 * (image-c2)**2)
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new_phi = (phi + (dt*_cv_delta(phi)) *
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(mu*K + difference_from_average_term))
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return new_phi / (1 + mu * dt * _cv_delta(phi) * (C1+C2+C3+C4))
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def _cv_heavyside(x, eps=1.):
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"""Returns the result of a regularised heavyside function of the
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input value(s).
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"""
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return 0.5 * (1. + (2./np.pi) * np.arctan(x/eps))
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def _cv_delta(x, eps=1.):
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"""Returns the result of a regularised dirac function of the
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input value(s).
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"""
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return eps / (eps**2 + x**2)
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def _cv_calculate_averages(image, Hphi):
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"""Returns the average values 'inside' and 'outside'.
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"""
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H = Hphi
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Hinv = 1. - H
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Hsum = np.sum(H)
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Hinvsum = np.sum(Hinv)
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avg_inside = np.sum(image * H)
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avg_oustide = np.sum(image * Hinv)
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if Hsum != 0:
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avg_inside /= Hsum
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if Hinvsum != 0:
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avg_oustide /= Hinvsum
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return (avg_inside, avg_oustide)
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def _cv_difference_from_average_term(image, Hphi, lambda_pos, lambda_neg):
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"""Returns the 'energy' contribution due to the difference from
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the average value within a region at each point.
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"""
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(c1, c2) = _cv_calculate_averages(image, Hphi)
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Hinv = 1. - Hphi
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return (lambda_pos * (image-c1)**2 * Hphi +
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lambda_neg * (image-c2)**2 * Hinv)
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def _cv_edge_length_term(phi, mu):
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"""Returns the 'energy' contribution due to the length of the
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edge between regions at each point, multiplied by a factor 'mu'.
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"""
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toret = _cv_curvature(phi)
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return mu * toret
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def _cv_energy(image, phi, mu, lambda1, lambda2):
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"""Returns the total 'energy' of the current level set function.
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"""
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H = _cv_heavyside(phi)
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avgenergy = _cv_difference_from_average_term(image, H, lambda1, lambda2)
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lenenergy = _cv_edge_length_term(phi, mu)
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return np.sum(avgenergy) + np.sum(lenenergy)
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def _cv_reset_level_set(phi):
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"""This is a placeholder function as resetting the level set is not
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strictly necessary, and has not been done for this implementation.
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"""
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return phi
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def _cv_checkerboard(image_size, square_size):
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"""Generates a checkerboard level set function.
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According to Pascal Getreuer, such a level set function has fast convergence.
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"""
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yv = np.arange(image_size[0]).reshape(image_size[0], 1)
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xv = np.arange(image_size[1])
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return (np.sin(np.pi/square_size*yv) *
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np.sin(np.pi/square_size*xv))
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def _cv_large_disk(image_size):
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"""Generates a disk level set function.
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The disk covers the whole image along its smallest dimension.
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"""
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res = np.ones(image_size)
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centerY = int((image_size[0]-1) / 2)
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centerX = int((image_size[1]-1) / 2)
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res[centerY, centerX] = 0.
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radius = float(min(centerX, centerY))
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return (radius-distance(res)) / radius
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def _cv_small_disk(image_size):
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"""Generates a disk level set function.
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The disk covers half of the image along its smallest dimension.
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"""
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res = np.ones(image_size)
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centerY = int((image_size[0]-1) / 2)
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centerX = int((image_size[1]-1) / 2)
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res[centerY, centerX] = 0.
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radius = float(min(centerX, centerY)) / 2.0
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return (radius-distance(res)) / (radius*3)
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def _cv_init_level_set(init_level_set, image_shape):
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"""Generates an initial level set function conditional on input arguments.
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"""
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if type(init_level_set) == str:
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if init_level_set == 'checkerboard':
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res = _cv_checkerboard(image_shape, 5)
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elif init_level_set == 'disk':
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res = _cv_large_disk(image_shape)
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elif init_level_set == 'small disk':
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res = _cv_small_disk(image_shape)
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else:
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raise ValueError("Incorrect name for starting level set preset.")
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else:
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res = init_level_set
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return res
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def chan_vese(image, mu=0.25, lambda1=1.0, lambda2=1.0, tol=1e-3, max_iter=500,
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dt=0.5, init_level_set='checkerboard',
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extended_output=False):
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"""Chan-Vese segmentation algorithm.
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Active contour model by evolving a level set. Can be used to
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segment objects without clearly defined boundaries.
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Parameters
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----------
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image : (M, N) ndarray
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Grayscale image to be segmented.
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mu : float, optional
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'edge length' weight parameter. Higher `mu` values will
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produce a 'round' edge, while values closer to zero will
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detect smaller objects.
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lambda1 : float, optional
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'difference from average' weight parameter for the output
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region with value 'True'. If it is lower than `lambda2`, this
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region will have a larger range of values than the other.
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lambda2 : float, optional
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'difference from average' weight parameter for the output
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region with value 'False'. If it is lower than `lambda1`, this
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region will have a larger range of values than the other.
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tol : float, positive, optional
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Level set variation tolerance between iterations. If the
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L2 norm difference between the level sets of successive
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iterations normalized by the area of the image is below this
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value, the algorithm will assume that the solution was
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reached.
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max_iter : uint, optional
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Maximum number of iterations allowed before the algorithm
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interrupts itself.
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dt : float, optional
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A multiplication factor applied at calculations for each step,
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serves to accelerate the algorithm. While higher values may
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speed up the algorithm, they may also lead to convergence
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problems.
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init_level_set : str or (M, N) ndarray, optional
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Defines the starting level set used by the algorithm.
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If a string is inputted, a level set that matches the image
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size will automatically be generated. Alternatively, it is
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possible to define a custom level set, which should be an
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array of float values, with the same shape as 'image'.
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Accepted string values are as follows.
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'checkerboard'
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the starting level set is defined as
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sin(x/5*pi)*sin(y/5*pi), where x and y are pixel
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coordinates. This level set has fast convergence, but may
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fail to detect implicit edges.
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'disk'
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the starting level set is defined as the opposite
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of the distance from the center of the image minus half of
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the minimum value between image width and image height.
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This is somewhat slower, but is more likely to properly
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detect implicit edges.
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'small disk'
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the starting level set is defined as the
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opposite of the distance from the center of the image
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minus a quarter of the minimum value between image width
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and image height.
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extended_output : bool, optional
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If set to True, the return value will be a tuple containing
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the three return values (see below). If set to False which
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is the default value, only the 'segmentation' array will be
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returned.
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Returns
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-------
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segmentation : (M, N) ndarray, bool
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Segmentation produced by the algorithm.
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phi : (M, N) ndarray of floats
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Final level set computed by the algorithm.
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energies : list of floats
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Shows the evolution of the 'energy' for each step of the
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algorithm. This should allow to check whether the algorithm
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converged.
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Notes
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-----
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The Chan-Vese Algorithm is designed to segment objects without
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clearly defined boundaries. This algorithm is based on level sets
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that are evolved iteratively to minimize an energy, which is
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defined by weighted values corresponding to the sum of differences
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intensity from the average value outside the segmented region, the
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sum of differences from the average value inside the segmented
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region, and a term which is dependent on the length of the
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boundary of the segmented region.
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This algorithm was first proposed by Tony Chan and Luminita Vese,
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in a publication entitled "An Active Contour Model Without Edges"
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[1]_.
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This implementation of the algorithm is somewhat simplified in the
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sense that the area factor 'nu' described in the original paper is
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not implemented, and is only suitable for grayscale images.
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Typical values for `lambda1` and `lambda2` are 1. If the
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'background' is very different from the segmented object in terms
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of distribution (for example, a uniform black image with figures
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of varying intensity), then these values should be different from
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each other.
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Typical values for mu are between 0 and 1, though higher values
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can be used when dealing with shapes with very ill-defined
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contours.
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The 'energy' which this algorithm tries to minimize is defined
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as the sum of the differences from the average within the region
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squared and weighed by the 'lambda' factors to which is added the
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length of the contour multiplied by the 'mu' factor.
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Supports 2D grayscale images only, and does not implement the area
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term described in the original article.
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References
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----------
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.. [1] An Active Contour Model without Edges, Tony Chan and
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Luminita Vese, Scale-Space Theories in Computer Vision,
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1999, :DOI:`10.1007/3-540-48236-9_13`
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.. [2] Chan-Vese Segmentation, Pascal Getreuer Image Processing On
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Line, 2 (2012), pp. 214-224,
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:DOI:`10.5201/ipol.2012.g-cv`
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.. [3] The Chan-Vese Algorithm - Project Report, Rami Cohen, 2011
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:arXiv:`1107.2782`
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"""
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if len(image.shape) != 2:
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raise ValueError("Input image should be a 2D array.")
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phi = _cv_init_level_set(init_level_set, image.shape)
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if type(phi) != np.ndarray or phi.shape != image.shape:
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raise ValueError("The dimensions of initial level set do not "
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"match the dimensions of image.")
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image = image - np.min(image)
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if np.max(image) != 0:
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image = image / np.max(image)
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i = 0
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old_energy = _cv_energy(image, phi, mu, lambda1, lambda2)
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energies = []
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phivar = tol + 1
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segmentation = phi > 0
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while(phivar > tol and i < max_iter):
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# Save old level set values
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oldphi = phi
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# Calculate new level set
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phi = _cv_calculate_variation(image, phi, mu, lambda1, lambda2, dt)
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phi = _cv_reset_level_set(phi)
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phivar = np.sqrt(((phi-oldphi)**2).mean())
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# Extract energy and compare to previous level set and
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# segmentation to see if continuing is necessary
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segmentation = phi > 0
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new_energy = _cv_energy(image, phi, mu, lambda1, lambda2)
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# Save old energy values
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energies.append(old_energy)
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old_energy = new_energy
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i += 1
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if extended_output:
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return (segmentation, phi, energies)
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else:
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return segmentation
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