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        Click :ref:`here <sphx_glr_download_auto_examples_filters_plot_attribute_operators.py>`
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.. rst-class:: sphx-glr-example-title

.. _sphx_glr_auto_examples_filters_plot_attribute_operators.py:


===================
Attribute operators
===================

Attribute operators (or connected operators) [1]_ is a family of contour
preserving filtering operations in mathematical morphology. They can be
implemented by max-trees [2]_, a compact hierarchical representation of the
image.

Here, we show how to use diameter closing [3]_ [4]_, which is compared to
morphological closing. Comparing the two results, we observe that the
difference between image and morphological closing also extracts the long line.
A thin but long line cannot contain the structuring element. The diameter
closing stops the filling as soon as a maximal extension is reached. The line
is therefore not filled and therefore not extracted by the difference.

.. GENERATED FROM PYTHON SOURCE LINES 18-97

.. code-block:: default


    import numpy as np
    import matplotlib.pyplot as plt
    from skimage.morphology import diameter_closing
    from skimage import data
    from skimage.morphology import closing
    from skimage.morphology import square

    datasets = {
        'retina': {'image': data.microaneurysms(),
                   'figsize': (15, 9),
                   'diameter': 10,
                   'vis_factor': 3,
                   'title': 'Detection of microaneurysm'},
        'page': {'image': data.page(),
                 'figsize': (15, 7),
                 'diameter': 23,
                 'vis_factor': 1,
                 'title': 'Text detection'}
    }

    for dataset in datasets.values():
        # image with printed letters
        image = dataset['image']
        figsize = dataset['figsize']
        diameter = dataset['diameter']

        fig, ax = plt.subplots(2, 3, figsize=figsize)
        # Original image
        ax[0, 0].imshow(image, cmap='gray', aspect='equal',
                        vmin=0, vmax=255)
        ax[0, 0].set_title('Original', fontsize=16)
        ax[0, 0].axis('off')

        ax[1, 0].imshow(image, cmap='gray', aspect='equal',
                        vmin=0, vmax=255)
        ax[1, 0].set_title('Original', fontsize=16)
        ax[1, 0].axis('off')

        # Diameter closing : we remove all dark structures with a maximal
        # extension of less than <diameter> (12 or 23). I.e. in closed_attr, all
        # local minima have at least a maximal extension of <diameter>.
        closed_attr = diameter_closing(image, diameter, connectivity=2)

        # We then calculate the difference to the original image.
        tophat_attr = closed_attr - image

        ax[0, 1].imshow(closed_attr, cmap='gray', aspect='equal',
                        vmin=0, vmax=255)
        ax[0, 1].set_title('Diameter Closing', fontsize=16)
        ax[0, 1].axis('off')

        ax[0, 2].imshow(dataset['vis_factor'] * tophat_attr, cmap='gray',
                        aspect='equal', vmin=0, vmax=255)
        ax[0, 2].set_title('Tophat (Difference)', fontsize=16)
        ax[0, 2].axis('off')

        # A morphological closing removes all dark structures that cannot
        # contain a structuring element of a certain size.
        closed = closing(image, square(diameter))

        # Again we calculate the difference to the original image.
        tophat = closed - image

        ax[1, 1].imshow(closed, cmap='gray', aspect='equal',
                        vmin=0, vmax=255)
        ax[1, 1].set_title('Morphological Closing', fontsize=16)
        ax[1, 1].axis('off')

        ax[1, 2].imshow(dataset['vis_factor'] * tophat, cmap='gray',
                        aspect='equal', vmin=0, vmax=255)
        ax[1, 2].set_title('Tophat (Difference)', fontsize=16)
        ax[1, 2].axis('off')
        fig.suptitle(dataset['title'], fontsize=18)
        fig.tight_layout(rect=(0, 0, 1, 0.88))

    plt.show()





.. rst-class:: sphx-glr-horizontal


    *

      .. image-sg:: /auto_examples/filters/images/sphx_glr_plot_attribute_operators_001.png
         :alt: Detection of microaneurysm, Original, Diameter Closing, Tophat (Difference), Original, Morphological Closing, Tophat (Difference)
         :srcset: /auto_examples/filters/images/sphx_glr_plot_attribute_operators_001.png
         :class: sphx-glr-multi-img

    *

      .. image-sg:: /auto_examples/filters/images/sphx_glr_plot_attribute_operators_002.png
         :alt: Text detection, Original, Diameter Closing, Tophat (Difference), Original, Morphological Closing, Tophat (Difference)
         :srcset: /auto_examples/filters/images/sphx_glr_plot_attribute_operators_002.png
         :class: sphx-glr-multi-img





.. GENERATED FROM PYTHON SOURCE LINES 98-119

References
----------
.. [1] Salembier, P., Oliveras, A., & Garrido, L. (1998). Antiextensive
       Connected Operators for Image and Sequence Processing.
       IEEE Transactions on Image Processing, 7(4), 555-570.
       :DOI:`10.1109/83.663500`
.. [2] Carlinet, E., & Geraud, T. (2014). A Comparative Review of
       Component Tree Computation Algorithms. IEEE Transactions on Image
       Processing, 23(9), 3885-3895.
       :DOI:`10.1109/TIP.2014.2336551`
.. [3] Vincent L., Proc. "Grayscale area openings and closings,
       their efficient implementation and applications",
       EURASIP Workshop on Mathematical Morphology and its
       Applications to Signal Processing, Barcelona, Spain, pp.22-27,
       May 1993.
.. [4] Walter, T., & Klein, J.-C. (2002). Automatic Detection of
       Microaneurysms in Color Fundus Images of the Human Retina by Means
       of the Bounding Box Closing. In A. Colosimo, P. Sirabella,
       A. Giuliani (Eds.), Medical Data Analysis. Lecture Notes in Computer
       Science, vol 2526, pp. 210-220. Springer Berlin Heidelberg.
       :DOI:`10.1007/3-540-36104-9_23`


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