Pioneer21/Lecture03

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This page serves as a supplement to the third group meeting of the Summer 2021 Pioneer program for image processing.

Python Requirements

The programs from this lecture will require several modules:

The start of any script we use in this lecture will be:

import numpy as np
import matplotlib.pyplot as plt
import skimage as ski
import scipy.signal as sig

scikit-image commands

The main command for this session is:

  • DATA = ski.data.NAME() where DATA is a variable name you give to store the information from a built-in image and NAME is the name of a built-in image from scikit-image; the built-in images can be found in the Data section of the General Examples page.

Starting on July 26, 2021, we will be using AXIS.imshow(DATA) instead of ski.io.imshow(DATA) to display an image.

Depending on the nature of an image, its DATA variable will be different shapes and contain different data types. Here is how scikit-image and imshow() interpret things:

  • A 2D-array will either be black and white, grayscale, or it will be mapped to a colormap
  • A 3D-array will be interpreted as an RGB-based color image
  • For a 2D-array, the following data types and sizes might be useful:
    • An array of boolean (True or False) values or integer values with only integers 0 or 1 will produce an image with values at the extreme edges of the colormap. By default in Python with matplotlib this is purple and gold. You can add some keyword arguments to the command to get black and white as follows:
      • Default case with booleans
        fig, ax = plt.subplots(num=1, clear=True)
        bwimage = ski.data.binary_blobs()
        ax.imshow(bwimage)
        
      • Black and white with booleans
        fig, ax = plt.subplots(num=1, clear=True)
        bwimage = ski.data.binary_blobs()
        ax.imshow(bwimage, cmap=plt.cm.gray)
        
      • Black and white and no axis ticks with booleans
        fig, ax = plt.subplots(num=1, clear=True)
        bwimage = ski.data.binary_blobs()
        ax.imshow(bwimage, cmap=plt.cm.gray)
        ax.set_axis_off()
        
        For each of the above, you can replace the array of booleans with an array of integers 0 or 1 by replacing the bwimage line with:
        bwimage = np.random.choice([0,1], (50,100))
        
        or
        bwimage = np.random.randint(0, 2, (50, 100))
        
    • An array of integer values will produce an image with values mapped to the default Viridis (purple - green - blue - yellow) colormap. You can add some keyword arguments to the command to get shades of gray as above:
      • Default case with integers
        fig, ax = plt.subplots(num=1, clear=True)
        grayimage = ski.data.coins()
        ax.imshow(grayimage)
        
      • Gray with integers
        fig, ax = plt.subplots(num=1, clear=True)
        grayimage = ski.data.coins()
        ax.imshow(grayimage, cmap=plt.cm.gray)
        
      • Gray and no axis ticks with integers
        fig, ax = plt.subplots(num=1, clear=True)
        grayimage = ski.data.coins()
        ax.imshow(grayimage, cmap=plt.cm.gray)
        ax.set_axis_off()
        
        *Note 1 - the addition of the colormap is required for using the axis version of imshow versus the scikit-image version of imshow. *Note 2 - by default, imshow will stratch the range of integers to cover the whole map. If you want to specifically map to a certain range - for instance, have 0 as pure black and 255 as pure white, you need to add vmin and vmax keyword arguments to explicitly give the values that map to the low and high end of the volormap. For instance:
        fig, ax = plt.subplots(num=1, clear=True)
        grayimage = ski.data.coins()
        ax.imshow(grayimage, cmap=plt.cm.gray, vmin=0, vmax=255))
        ax.set_axis_off()
        
        will produce the exact same image that ski.io.imshow(grayimage) would have produced.