Documentation¶
ipfml.metrics¶
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ipfml.metrics.
get_LAB
(image)¶ Transforms RGB Image into Lab
Parameters: image – image to convert Returns: Lab information Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> Lab = metrics.get_LAB(img) >>> Lab.shape (200, 200, 3)
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ipfml.metrics.
get_LAB_L
(image)¶ Transforms RGB Image into Lab and returns L
Parameters: image – image to convert Returns: The L chanel from Lab information >>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> L = metrics.get_LAB_L(img) >>> L.shape (200, 200)
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ipfml.metrics.
get_LAB_a
(image)¶ Transforms RGB Image into LAB and returns a
Parameters: image – image to convert Returns: The a chanel from Lab information Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> a = metrics.get_LAB_a(img) >>> a.shape (200, 200)
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ipfml.metrics.
get_LAB_b
(image)¶ Transforms RGB Image into LAB and returns b
Parameters: image – image to convert Returns: The b chanel from Lab information Usage :
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> b = metrics.get_LAB_b(img) >>> b.shape (200, 200)
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ipfml.metrics.
get_SVD
(image)¶ Transforms Image using SVD compression
Parameters: image – image to convert into SVD compression Returns: U, s, V obtained from SVD compression Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> U, s, V = metrics.get_SVD(img) >>> U.shape (200, 200, 3) >>> len(s) 200 >>> V.shape (200, 3, 3)
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ipfml.metrics.
get_SVD_U
(image)¶ Transforms Image into SVD and returns only ‘U’ part
Parameters: image – image to convert Returns: U matrix from SVD compression Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> U = metrics.get_SVD_U(img) >>> U.shape (200, 200, 3)
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ipfml.metrics.
get_SVD_V
(image)¶ Transforms Image into SVD and returns only ‘V’ part
Parameters: image – image to convert Returns: V matrix obtained from SVD compression Usage :
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> V = metrics.get_SVD_V(img) >>> V.shape (200, 3, 3)
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ipfml.metrics.
get_SVD_s
(image)¶ Transforms Image into SVD and returns only ‘s’ part
Parameters: image – image to convert Returns: vector of singular values obtained from SVD compression Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> s = metrics.get_SVD_s(img) >>> len(s) 200
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ipfml.metrics.
get_XYZ
(image)¶ Transforms RGB Image into XYZ
Parameters: image – image to convert Returns: XYZ information obtained from transformation Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> metrics.get_XYZ(img).shape (200, 200, 3)
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ipfml.metrics.
get_XYZ_X
(image)¶ Transforms RGB Image into XYZ and returns X
Parameters: image – image to convert Returns: The X chanel from XYZ information Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> x = metrics.get_XYZ_X(img) >>> x.shape (200, 200)
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ipfml.metrics.
get_XYZ_Y
(image)¶ Transforms RGB Image into XYZ and returns Y
Parameters: image – image to convert Returns: The Y chanel from XYZ information Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> y = metrics.get_XYZ_Y(img) >>> y.shape (200, 200)
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ipfml.metrics.
get_XYZ_Z
(image)¶ Transforms RGB Image into XYZ and returns Z
Parameters: image – image to convert Returns: The Z chanel from XYZ information Raises: ValueError
– If nb_bits has unexpected value. nb_bits needs to be in interval [1, 8].Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> z = metrics.get_XYZ_Z(img) >>> z.shape (200, 200)
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ipfml.metrics.
get_bits_img
(image, interval)¶ Returns only bits specified into the interval
Parameters: - image – image to convert using this interval of bits value to keep
- interval – (begin, end) of bits values
Returns: Numpy array with reduced values
Raises: ValueError
– If min value from interval is not >= 1.ValueError
– If max value from interval is not <= 8.ValueError
– If min value from interval >= max value.
Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> bits_img = metrics.get_bits_img(img, (2, 5)) >>> bits_img.shape (200, 200, 3)
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ipfml.metrics.
get_low_bits_img
(image, nb_bits=4)¶ Returns Image or Numpy array with data information reduced using only low bits
Parameters: - image – image to convert
- nb_bits – optional parameter which indicates the number of bits to keep
Returns: Numpy array with reduced values
Usage:
>>> from PIL import Image >>> from ipfml import metrics >>> img = Image.open('./images/test_img.png') >>> low_bits_img = metrics.get_low_bits_img(img, 5) >>> low_bits_img.shape (200, 200, 3)
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ipfml.metrics.
gray_to_mscn
(image)¶ Convert Grayscale Image into Mean Subtracted Contrast Normalized (MSCN)
Parameters: image – grayscale image Returns: MSCN matrix obtained from transformation Usage:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> img_mscn = processing.rgb_to_mscn(img) >>> img_mscn.shape (200, 200)
ipfml.processing¶
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ipfml.processing.
divide_in_blocks
(image, block_size, pil=True)¶ Divide image into equal size blocks
Parameters: - image – PIL Image or Numpy array
- block – tuple (width, height) representing the size of each dimension of the block
- pil – block type returned (default True)
Returns: list containing all 2D Numpy blocks (in RGB or not)
Raises: ValueError
– If image_width or image_heigt are not compatible to produce correct block sizesExample:
>>> import numpy as np >>> from PIL import Image >>> from ipfml import processing >>> from ipfml import metrics >>> image_values = np.random.randint(255, size=(800, 800, 3)) >>> blocks = divide_in_blocks(image_values, (20, 20)) >>> len(blocks) 1600 >>> blocks[0].width 20 >>> blocks[0].height 20 >>> img_l = Image.open('./images/test_img.png') >>> L = metrics.get_LAB_L(img_l) >>> blocks_L = divide_in_blocks(L, (100, 100)) >>> len(blocks_L) 4 >>> blocks_L[0].width 100
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ipfml.processing.
get_LAB_L_SVD
(image)¶ Returns Singular values from LAB L Image information
Parameters: image – PIL Image or Numpy array Returns: U, s, V information obtained from SVD compression using Lab Example:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> U, s, V = processing.get_LAB_L_SVD(img) >>> U.shape (200, 200) >>> len(s) 200 >>> V.shape (200, 200)
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ipfml.processing.
get_LAB_L_SVD_U
(image)¶ Returns U SVD from L of LAB Image information
Parameters: image – PIL Image or Numpy array Returns: U matrix of SVD compression Example:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> U = processing.get_LAB_L_SVD_U(img) >>> U.shape (200, 200)
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ipfml.processing.
get_LAB_L_SVD_V
(image)¶ Returns V SVD from L of LAB Image information
Parameters: image – PIL Image or Numpy array Returns: V matrix of SVD compression Example:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> V = processing.get_LAB_L_SVD_V(img) >>> V.shape (200, 200)
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ipfml.processing.
get_LAB_L_SVD_s
(image)¶ Returns s (Singular values) SVD from L of LAB Image information
Parameters: image – PIL Image or Numpy array Returns: vector of singular values Example:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> s = processing.get_LAB_L_SVD_s(img) >>> len(s) 200
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ipfml.processing.
normalize_2D_arr
(arr)¶ Return array normalize from its min and max values
Parameters: arr – 2D Numpy array Returns: Normalized 2D Numpy array Example:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> img_mscn = processing.rgb_to_mscn(img) >>> img_normalized = processing.normalize_2D_arr(img_mscn) >>> img_normalized.shape (200, 200)
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ipfml.processing.
normalize_arr
(arr)¶ Normalize data of 1D array shape
Parameters: arr – array data of 1D shape Returns: Normalized 1D array Example:
>>> from ipfml import processing >>> import numpy as np >>> arr = np.arange(11) >>> arr_normalized = processing.normalize_arr(arr) >>> arr_normalized[1] 0.1
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ipfml.processing.
normalize_arr_with_range
(arr, min, max)¶ Normalize data of 1D array shape
Parameters: arr – array data of 1D shape Returns: Normalized 1D Numpy array Example:
>>> from ipfml import processing >>> import numpy as np >>> arr = np.arange(11) >>> arr_normalized = processing.normalize_arr_with_range(arr, 0, 20) >>> arr_normalized[1] 0.05
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ipfml.processing.
rgb_to_LAB_L_bits
(image, interval)¶ Returns only bits from LAB L canal specified into the interval
Parameters: - image – image to convert using this interval of bits value to keep
- interval – (begin, end) of bits values
Returns: 2D Numpy array with reduced values
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> bits_Lab_l_img = processing.rgb_to_LAB_L_bits(img, (2, 6)) >>> bits_Lab_l_img.shape (200, 200)
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ipfml.processing.
rgb_to_LAB_L_low_bits
(image, nb_bits=4)¶ Convert RGB Image into Lab L channel image using only 4 low bits values
Parameters: - image – 3D RGB image Numpy array or PIL RGB image
- nb_bits – optional parameter which indicates the number of bits to keep (default 4)
Returns: 2D Numpy array with low bits information kept
Example:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> low_bits_Lab_l_img = processing.rgb_to_LAB_L_low_bits(img, 5) >>> low_bits_Lab_l_img.shape (200, 200)
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ipfml.processing.
rgb_to_grey_low_bits
(image, nb_bits=4)¶ Convert RGB Image into grey image using only 4 low bits values
Parameters: - image – 3D RGB image Numpy array or PIL RGB image
- nb_bits – optional parameter which indicates the number of bits to keep (default 4)
Returns: 2D Numpy array with low bits information kept
Example:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> low_bits_grey_img = processing.rgb_to_grey_low_bits(img, 5) >>> low_bits_grey_img.shape (200, 200)
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ipfml.processing.
rgb_to_mscn
(image)¶ Convert RGB Image into Mean Subtracted Contrast Normalized (MSCN)
Parameters: image – 3D RGB image Numpy array or PIL RGB image Returns: 2D Numpy array with MSCN information Example:
>>> from PIL import Image >>> from ipfml import processing >>> img = Image.open('./images/test_img.png') >>> img_mscn = processing.rgb_to_mscn(img) >>> img_mscn.shape (200, 200)
ipfml.filters¶
ipfml.filters.noise¶
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ipfml.filters.noise.
cauchy_noise
(image, n, identical=False, distribution_interval=(0, 1), k=0.0002)¶ Cauchy noise filter to apply on image
Parameters: - image – image used as input (2D or 3D image representation)
- n – used to set importance of noise [1, 999]
- identical – keep or not identical noise distribution for each canal if RGB Image (default False)
- distribution_interval – set the distribution interval of normal law distribution (default (0, 1))
- k – variable that specifies the amount of noise to be taken into account in the output image (default 0.0002)
Returns: 2D Numpy array with Cauchy noise applied
Example:
>>> from ipfml.filters.noise import cauchy_noise >>> import numpy as np >>> image = np.random.uniform(0, 255, 10000).reshape((100, 100)) >>> noisy_image = cauchy_noise(image, 10) >>> noisy_image.shape (100, 100)
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ipfml.filters.noise.
gaussian_noise
(image, n, identical=False, distribution_interval=(0, 1), k=0.1)¶ Gaussian noise filter to apply on image
Parameters: - image – image used as input (2D or 3D image representation)
- n – used to set importance of noise [1, 999]
- identical – keep or not identical noise distribution for each canal if RGB Image (default False)
- distribution_interval – set the distribution interval of normal law distribution (default (0, 1))
- k – variable that specifies the amount of noise to be taken into account in the output image (default 0.1)
Returns: 2D Numpy array with gaussian noise applied
Example:
>>> from ipfml.filters.noise import gaussian_noise >>> import numpy as np >>> image = np.random.uniform(0, 255, 10000).reshape((100, 100)) >>> noisy_image = gaussian_noise(image, 10) >>> noisy_image.shape (100, 100)
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ipfml.filters.noise.
laplace_noise
(image, n, identical=False, distribution_interval=(0, 1), k=0.1)¶ Laplace noise filter to apply on image
Parameters: - image – image used as input (2D or 3D image representation)
- n – used to set importance of noise [1, 999]
- identical – keep or not identical noise distribution for each canal if RGB Image (default False)
- distribution_interval – set the distribution interval of normal law distribution (default (0, 1))
- k – variable that specifies the amount of noise to be taken into account in the output image (default 0.1)
Returns: 2D Numpay array with Laplace noise applied
Example:
>>> from ipfml.filters.noise import laplace_noise >>> import numpy as np >>> image = np.random.uniform(0, 255, 10000).reshape((100, 100)) >>> noisy_image = laplace_noise(image, 10) >>> noisy_image.shape (100, 100)
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ipfml.filters.noise.
log_normal_noise
(image, n, identical=False, distribution_interval=(0, 1), k=0.05)¶ Log-normal noise filter to apply on image
Parameters: - image – image used as input (2D or 3D image representation)
- n – used to set importance of noise [1, 999]
- identical – keep or not identical noise distribution for each canal if RGB Image (default False)
- distribution_interval – set the distribution interval of normal law distribution (default (0, 1))
- k – variable that specifies the amount of noise to be taken into account in the output image (default 0.05)
Returns: 2D Numpy array with Log-normal noise applied
Example:
>>> from ipfml.filters.noise import log_normal_noise >>> import numpy as np >>> image = np.random.uniform(0, 255, 10000).reshape((100, 100)) >>> noisy_image = log_normal_noise(image, 10) >>> noisy_image.shape (100, 100)
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ipfml.filters.noise.
mut_white_noise
(image, n, identical=False, distribution_interval=(-0.5, 0.5), k=0.2)¶ Multiplied White noise filter to apply on image
Parameters: - image – image used as input (2D or 3D image representation)
- n – used to set importance of noise [1, 999]
- identical – keep or not identical noise distribution for each canal if RGB Image (default False)
- distribution_interval – set the distribution interval of normal law distribution (default (-0.5, 0.5))
- k – variable that specifies the amount of noise to be taken into account in the output image (default 0.2)
Returns: 2D Numpy array with multiplied white noise applied
Example:
>>> from ipfml.filters.noise import mut_white_noise >>> import numpy as np >>> image = np.random.uniform(0, 255, 10000).reshape((100, 100)) >>> noisy_image = mut_white_noise(image, 10) >>> noisy_image.shape (100, 100)
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ipfml.filters.noise.
white_noise
(image, n, identical=False, distribution_interval=(-0.5, 0.5), k=0.2)¶ White noise filter to apply on image
Parameters: - image – image used as input (2D or 3D image representation)
- n – used to set importance of noise [1, 999]
- identical – keep or not identical noise distribution for each canal if RGB Image (default False)
- distribution_interval – set the distribution interval of normal law distribution (default (-0.5, 0.5))
- k – variable that specifies the amount of noise to be taken into account in the output image (default 0.2)
Returns: 2D Numpy array with white noise applied
Example:
>>> from ipfml.filters.noise import white_noise >>> import numpy as np >>> image = np.random.uniform(0, 255, 10000).reshape((100, 100)) >>> noisy_image = white_noise(image, 10) >>> noisy_image.shape (100, 100)