the python skimage gallery image to RGB color space conversion gradation; RGB to HSV

RGB to grayscale

from skimage.color import rgb2gray
grayscale = rgb2gray(original)

"""
================
RGB to grayscale
================

This example converts an image with RGB channels into an image with a single
grayscale channel.

The value of each grayscale pixel is calculated as the weighted sum of the
corresponding red, green and blue pixels as::

        Y = 0.2125 R + 0.7154 G + 0.0721 B

"""
import matplotlib.pyplot as plt

from skimage import data
from skimage.color import rgb2gray

original = data.astronaut()
grayscale = rgb2gray(original)

fig, axes = plt.subplots(1, 2, figsize=(8, 4))
ax = axes.ravel()

ax[0].imshow(original)
ax[0].set_title("Original")
ax[1].imshow(grayscale, cmap=plt.cm.gray)
ax[1].set_title("Grayscale")

fig.tight_layout()
plt.show()

Left: the RGB image; right: image gradation

RGB to HSV

from skimage.color import rgb2hsv
hsv_img = rgb2hsv(rgb_img)

Experiment: The simple separation of the cup from the background

"""
==========
RGB to HSV
==========

This example illustrates how RGB to HSV (Hue, Saturation, Value) conversion 
can be used to facilitate segmentation processes.

Usually, objects in images have distinct colors (hues) and luminosities, so
that these features can be used to separate different areas of the image.
In the RGB representation the hue and the luminosity are expressed as a linear
combination of the R,G,B channels, whereas they correspond to single channels
of the HSV image (the Hue and the Value channels). A simple segmentation of the
image can then be effectively performed by a mere thresholding of the HSV
channels.

"""


import matplotlib.pyplot as plt

from skimage import data
from skimage.color import rgb2hsv

##############################################################################
# We first load the RGB image and extract the Hue and Value channels:

rgb_img = data.coffee()
hsv_img = rgb2hsv(rgb_img)
hue_img = hsv_img[:, :, 0]
value_img = hsv_img[:, :, 2]

fig, (ax0, ax1, ax2) = plt.subplots(ncols=3, figsize=(8, 2))

ax0.imshow(rgb_img)
ax0.set_title("RGB image")
ax0.axis('off')
ax1.imshow(hue_img, cmap='hsv')
ax1.set_title("Hue channel")
ax1.axis('off')
ax2.imshow(value_img)
ax2.set_title("Value channel")
ax2.axis('off')

fig.tight_layout()

##############################################################################
# We then set a threshold on the Hue channel to separate the cup from the
# background:

hue_threshold = 0.04
binary_img = hue_img > hue_threshold
# print(hue_img) # 图像数值矩阵
# print(binary_img) # True or False 的一个矩阵

fig, (ax0, ax1) = plt.subplots(ncols=2, figsize=(8, 3))

# 参数2:bins
ax0.hist(hue_img.ravel(), 512)
ax0.set_title("Histogram of the Hue channel with threshold")
# 设置1条垂直于x轴的红色的虚线
ax0.axvline(x=hue_threshold, color='r', linestyle='dashed', linewidth=2)
# 设置x轴范围
ax0.set_xbound(0, 0.12)
ax1.imshow(binary_img)
ax1.set_title("Hue-thresholded image")
ax1.axis('off')

fig.tight_layout()

##############################################################################
# We finally perform an additional thresholding on the Value channel to partly
# remove the shadow of the cup:

fig, ax0 = plt.subplots(figsize=(4, 3))

value_threshold = 0.10
binary_img = (hue_img > hue_threshold) | (value_img < value_threshold)

ax0.imshow(binary_img)
ax0.set_title("Hue and value thresholded image")
ax0.axis('off')

fig.tight_layout()
plt.show()

figure 1
figure 2
figure 3

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Origin www.cnblogs.com/wojianxin/p/12638205.html