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edges.py
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edges.py
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"""
Sobel and Prewitt filters originally part of CellProfiler, code licensed under
both GPL and BSD licenses.
Website: http://www.cellprofiler.org
Copyright (c) 2003-2009 Massachusetts Institute of Technology
Copyright (c) 2009-2011 Broad Institute
All rights reserved.
Original author: Lee Kamentsky
"""
import numpy as np
from .. import img_as_float
from .._shared.utils import check_nD
from scipy.ndimage import convolve, binary_erosion, generate_binary_structure
from ..restoration.uft import laplacian
EROSION_SELEM = generate_binary_structure(2, 2)
HSOBEL_WEIGHTS = np.array([[1, 2, 1],
[0, 0, 0],
[-1, -2, -1]]) / 4.0
VSOBEL_WEIGHTS = HSOBEL_WEIGHTS.T
HSCHARR_WEIGHTS = np.array([[3, 10, 3],
[0, 0, 0],
[-3, -10, -3]]) / 16.0
VSCHARR_WEIGHTS = HSCHARR_WEIGHTS.T
HPREWITT_WEIGHTS = np.array([[1, 1, 1],
[0, 0, 0],
[-1, -1, -1]]) / 3.0
VPREWITT_WEIGHTS = HPREWITT_WEIGHTS.T
ROBERTS_PD_WEIGHTS = np.array([[1, 0],
[0, -1]], dtype=np.double)
ROBERTS_ND_WEIGHTS = np.array([[0, 1],
[-1, 0]], dtype=np.double)
# These filter weights can be found in Farid & Simoncelli (2004),
# Table 1 (3rd and 4th row). Additional decimal places were computed
# using the code found at https://www.cs.dartmouth.edu/farid/
p = np.array([[0.0376593171958126, 0.249153396177344, 0.426374573253687,
0.249153396177344, 0.0376593171958126]])
d1 = np.array([[0.109603762960254, 0.276690988455557, 0, -0.276690988455557,
-0.109603762960254]])
HFARID_WEIGHTS = d1.T * p
VFARID_WEIGHTS = np.copy(HFARID_WEIGHTS.T)
def _mask_filter_result(result, mask):
"""Return result after masking.
Input masks are eroded so that mask areas in the original image don't
affect values in the result.
"""
if mask is None:
result[0, :] = 0
result[-1, :] = 0
result[:, 0] = 0
result[:, -1] = 0
return result
else:
mask = binary_erosion(mask, EROSION_SELEM, border_value=0)
return result * mask
def sobel(image, mask=None):
"""Find the edge magnitude using the Sobel transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Sobel edge map.
See also
--------
scharr, prewitt, roberts, feature.canny
Notes
-----
Take the square root of the sum of the squares of the horizontal and
vertical Sobels to get a magnitude that's somewhat insensitive to
direction.
The 3x3 convolution kernel used in the horizontal and vertical Sobels is
an approximation of the gradient of the image (with some slight blurring
since 9 pixels are used to compute the gradient at a given pixel). As an
approximation of the gradient, the Sobel operator is not completely
rotation-invariant. The Scharr operator should be used for a better
rotation invariance.
Note that ``scipy.ndimage.sobel`` returns a directional Sobel which
has to be further processed to perform edge detection.
Examples
--------
>>> from skimage import data
>>> camera = data.camera()
>>> from skimage import filters
>>> edges = filters.sobel(camera)
"""
check_nD(image, 2)
out = np.sqrt(sobel_h(image, mask) ** 2 + sobel_v(image, mask) ** 2)
out /= np.sqrt(2)
return out
def sobel_h(image, mask=None):
"""Find the horizontal edges of an image using the Sobel transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Sobel edge map.
Notes
-----
We use the following kernel::
1 2 1
0 0 0
-1 -2 -1
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, HSOBEL_WEIGHTS)
return _mask_filter_result(result, mask)
def sobel_v(image, mask=None):
"""Find the vertical edges of an image using the Sobel transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Sobel edge map.
Notes
-----
We use the following kernel::
1 0 -1
2 0 -2
1 0 -1
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, VSOBEL_WEIGHTS)
return _mask_filter_result(result, mask)
def scharr(image, mask=None):
"""Find the edge magnitude using the Scharr transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Scharr edge map.
See also
--------
sobel, prewitt, canny
Notes
-----
Take the square root of the sum of the squares of the horizontal and
vertical Scharrs to get a magnitude that is somewhat insensitive to
direction. The Scharr operator has a better rotation invariance than
other edge filters such as the Sobel or the Prewitt operators.
References
----------
.. [1] D. Kroon, 2009, Short Paper University Twente, Numerical
Optimization of Kernel Based Image Derivatives.
.. [2] https://en.wikipedia.org/wiki/Sobel_operator#Alternative_operators
Examples
--------
>>> from skimage import data
>>> camera = data.camera()
>>> from skimage import filters
>>> edges = filters.scharr(camera)
"""
out = np.sqrt(scharr_h(image, mask) ** 2 + scharr_v(image, mask) ** 2)
out /= np.sqrt(2)
return out
def scharr_h(image, mask=None):
"""Find the horizontal edges of an image using the Scharr transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Scharr edge map.
Notes
-----
We use the following kernel::
3 10 3
0 0 0
-3 -10 -3
References
----------
.. [1] D. Kroon, 2009, Short Paper University Twente, Numerical
Optimization of Kernel Based Image Derivatives.
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, HSCHARR_WEIGHTS)
return _mask_filter_result(result, mask)
def scharr_v(image, mask=None):
"""Find the vertical edges of an image using the Scharr transform.
Parameters
----------
image : 2-D array
Image to process
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Scharr edge map.
Notes
-----
We use the following kernel::
3 0 -3
10 0 -10
3 0 -3
References
----------
.. [1] D. Kroon, 2009, Short Paper University Twente, Numerical
Optimization of Kernel Based Image Derivatives.
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, VSCHARR_WEIGHTS)
return _mask_filter_result(result, mask)
def prewitt(image, mask=None):
"""Find the edge magnitude using the Prewitt transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Prewitt edge map.
See also
--------
sobel, scharr
Notes
-----
Return the square root of the sum of squares of the horizontal
and vertical Prewitt transforms. The edge magnitude depends slightly
on edge directions, since the approximation of the gradient operator by
the Prewitt operator is not completely rotation invariant. For a better
rotation invariance, the Scharr operator should be used. The Sobel operator
has a better rotation invariance than the Prewitt operator, but a worse
rotation invariance than the Scharr operator.
Examples
--------
>>> from skimage import data
>>> camera = data.camera()
>>> from skimage import filters
>>> edges = filters.prewitt(camera)
"""
check_nD(image, 2)
out = np.sqrt(prewitt_h(image, mask) ** 2 + prewitt_v(image, mask) ** 2)
out /= np.sqrt(2)
return out
def prewitt_h(image, mask=None):
"""Find the horizontal edges of an image using the Prewitt transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Prewitt edge map.
Notes
-----
We use the following kernel::
1 1 1
0 0 0
-1 -1 -1
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, HPREWITT_WEIGHTS)
return _mask_filter_result(result, mask)
def prewitt_v(image, mask=None):
"""Find the vertical edges of an image using the Prewitt transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Prewitt edge map.
Notes
-----
We use the following kernel::
1 0 -1
1 0 -1
1 0 -1
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, VPREWITT_WEIGHTS)
return _mask_filter_result(result, mask)
def roberts(image, mask=None):
"""Find the edge magnitude using Roberts' cross operator.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Roberts' Cross edge map.
See also
--------
sobel, scharr, prewitt, feature.canny
Examples
--------
>>> from skimage import data
>>> camera = data.camera()
>>> from skimage import filters
>>> edges = filters.roberts(camera)
"""
check_nD(image, 2)
out = np.sqrt(roberts_pos_diag(image, mask) ** 2 +
roberts_neg_diag(image, mask) ** 2)
out /= np.sqrt(2)
return out
def roberts_pos_diag(image, mask=None):
"""Find the cross edges of an image using Roberts' cross operator.
The kernel is applied to the input image to produce separate measurements
of the gradient component one orientation.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Robert's edge map.
Notes
-----
We use the following kernel::
1 0
0 -1
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, ROBERTS_PD_WEIGHTS)
return _mask_filter_result(result, mask)
def roberts_neg_diag(image, mask=None):
"""Find the cross edges of an image using the Roberts' Cross operator.
The kernel is applied to the input image to produce separate measurements
of the gradient component one orientation.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Robert's edge map.
Notes
-----
We use the following kernel::
0 1
-1 0
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, ROBERTS_ND_WEIGHTS)
return _mask_filter_result(result, mask)
def laplace(image, ksize=3, mask=None):
"""Find the edges of an image using the Laplace operator.
Parameters
----------
image : ndarray
Image to process.
ksize : int, optional
Define the size of the discrete Laplacian operator such that it
will have a size of (ksize,) * image.ndim.
mask : ndarray, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : ndarray
The Laplace edge map.
Notes
-----
The Laplacian operator is generated using the function
skimage.restoration.uft.laplacian().
"""
image = img_as_float(image)
# Create the discrete Laplacian operator - We keep only the real part of
# the filter
_, laplace_op = laplacian(image.ndim, (ksize,) * image.ndim)
result = convolve(image, laplace_op)
return _mask_filter_result(result, mask)
def farid(image, *, mask=None):
"""Find the edge magnitude using the Farid transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Farid edge map.
See also
--------
sobel, prewitt, canny
Notes
-----
Take the square root of the sum of the squares of the horizontal and
vertical derivatives to get a magnitude that is somewhat insensitive to
direction. Similar to the Scharr operator, this operator is designed with
a rotation invariance constraint.
References
----------
.. [1] Farid, H. and Simoncelli, E. P., "Differentiation of discrete
multidimensional signals", IEEE Transactions on Image Processing
13(4): 496-508, 2004. :DOI:`10.1109/TIP.2004.823819`
.. [2] Wikipedia, "Farid and Simoncelli Derivatives." Available at:
<https://en.wikipedia.org/wiki/Image_derivatives#Farid_and_Simoncelli_Derivatives>
Examples
--------
>>> from skimage import data
>>> camera = data.camera()
>>> from skimage import filters
>>> edges = filters.farid(camera)
"""
check_nD(image, 2)
out = np.sqrt(farid_h(image, mask=mask) ** 2
+ farid_v(image, mask=mask) ** 2)
out /= np.sqrt(2)
return out
def farid_h(image, *, mask=None):
"""Find the horizontal edges of an image using the Farid transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Farid edge map.
Notes
-----
The kernel was constructed using the 5-tap weights from [1].
References
----------
.. [1] Farid, H. and Simoncelli, E. P., "Differentiation of discrete
multidimensional signals", IEEE Transactions on Image Processing
13(4): 496-508, 2004. :DOI:`10.1109/TIP.2004.823819`
.. [2] Farid, H. and Simoncelli, E. P. "Optimally rotation-equivariant
directional derivative kernels", In: 7th International Conference on
Computer Analysis of Images and Patterns, Kiel, Germany. Sep, 1997.
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, HFARID_WEIGHTS)
return _mask_filter_result(result, mask)
def farid_v(image, *, mask=None):
"""Find the vertical edges of an image using the Farid transform.
Parameters
----------
image : 2-D array
Image to process.
mask : 2-D array, optional
An optional mask to limit the application to a certain area.
Note that pixels surrounding masked regions are also masked to
prevent masked regions from affecting the result.
Returns
-------
output : 2-D array
The Farid edge map.
Notes
-----
The kernel was constructed using the 5-tap weights from [1].
References
----------
.. [1] Farid, H. and Simoncelli, E. P., "Differentiation of discrete
multidimensional signals", IEEE Transactions on Image Processing
13(4): 496-508, 2004. :DOI:`10.1109/TIP.2004.823819`
"""
check_nD(image, 2)
image = img_as_float(image)
result = convolve(image, VFARID_WEIGHTS)
return _mask_filter_result(result, mask)