1. 图片加载、灰度图、 显示和保存

from PIL import Image

img = Image.open("01.jpg")
imgGrey = img.convert("L")

img.show()
imgGrey.show()

img.save("img_copy.jpg")
imgGrey.save("img_gray.jpg")

2. 图片宽、高、通道模式、平均值获取

from PIL import Image
import numpy as np

img = Image.open("01.jpg")

width, height = img.size
channel_mode = img.mode
mean_value = np.mean(img)

print(width)
print(height)
print(channel_mode)
print(mean_value)

3. 创建指定大小，指定通道类型的空图像

from PIL import Image

width = 200
height = 100

img_white = Image.new("RGB", (width,height), (255,255,255))
img_black = Image.new("RGB", (width,height), (0,0,0))
img_L = Image.new("L", (width, height), (255))

img_white.show()
img_black.show()
img_L.show()

4. 访问和操作图像像素

from PIL import Image

img = Image.open("01.jpg")

width, height = img.size

# 获取指定坐标位置像素值
pixel_value = img.getpixel((width/2, height/2))
print(pixel_value)

# 或者使用load方法
pim = img.load()
pixel_value1 = pim[width/2, height/2]
print(pixel_value1)

# 设置指定坐标位置像素的值
pim[width/2, height/2] = (0, 0, 0)

# 或使用putpixel方法
img.putpixel((w//2, h//2), (255,255,255))

# 设置指定区域像素的值
for w in range(int(width/2) - 40, int(width/2) + 40):
for h in range(int(height/2) - 20, int(height/2) + 20):
pim[w, h] = (255, 0, 0)
# img.putpixel((w, h), (255,255,255))
img.show()

5. 图像通道分离和合并

from PIL import Image

img = Image.open("01.jpg")

# 通道分离
R, G, B = img.split()

R.show)
G.show()
B.show()

# 通道合并
img_RGB = Image.merge("RGB", (R, G, B))
img_BGR = Image.merge("RGB", (B, G, R))
img_RGB.show()
img_BGR.show()

6. 在图像上输出文字

from PIL import Image, ImageDraw, ImageFont

img = Image.open("01.jpg")

# 创建Draw对象:
draw = ImageDraw.Draw(img)
# 字体颜色
fillColor = (255, 0, 0)

text = "print text on PIL Image"
position = (200,100)

draw.text(position, text, fill=fillColor)
img.show()

7. 图像缩放

from PIL import Image

img = Image.open("01.jpg")

width, height = img.size

img_NEARESET = img.resize((width//2, height//2)) # 缩放默认模式是NEARESET(最近邻插值)
img_BILINEAR = img.resize((width//2, height//2), Image.BILINEAR) # BILINEAR 2x2区域的双线性插值
img_BICUBIC = img.resize((width//2, height//2), Image.BICUBIC) # BICUBIC 4x4区域的双三次插值
img_ANTIALIAS = img.resize((width//2, height//2), Image.ANTIALIAS) # ANTIALIAS 高质量下采样滤波

8. 图像遍历操作

from PIL import Image

img = Image.open("01.jpg").convert("L")

width, height = img.size

pim = img.load()

for w in range(width):
for h in range(height):
if pim[w, h] > 100:
img.putpixel((w, h), 255)
# pim[w, h] = 255
else:
img.putpixel((w, h), 0)
# pim[w, h] = 0

img.show()

9. 图像阈值分割、 二值化

from PIL import Image

img = Image.open("01.jpg").convert("L")

width, height = img.size

threshold = 125

for w in range(width):
for h in range(height):
if img.getpixel((w, h)) > threshold:
img.putpixel((w, h), 255)
else:
img.putpixel((w, h), 0)

img.save("binary.jpg")

10. 图像裁剪

from PIL import Image

img = Image.open("01.jpg")

width, height = img.size

# 前两个坐标点是左上角坐标
# 后两个坐标点是右下角坐标
# width在前， height在后
box = (100, 100, 550, 350)

region = img.crop(box)

region.save("crop.jpg")

11. 图像边界扩展

# 边界扩展
from PIL import Image

img = Image.open("test.png")

width, height = img.size
channel_mode = img.mode

img_makeBorder_full = Image.new(channel_mode, (2*width, height))
img_makeBorder_part = Image.new(channel_mode, (width+200, height))

# 图像水平扩展整个图像
img_makeBorder_full.paste(img, (0, 0, width, height))
img_makeBorder_full.paste(img, (width, 0, 2*width, height))

# 前两个坐标点是左上角坐标
# 后两个坐标点是右下角坐标
# width在前， height在后
box = (width-200, 0, width, height)
region = img.crop(box)

# 图像水平右侧扩展一个ROI
img_makeBorder_part.paste(img, (0, 0, width, height))
img_makeBorder_part.paste(region, (width, 0, width+200, height))
img_makeBorder_part.show()
img_makeBorder_full.show()

12. PIL.Image 和 numpy 格式相互转换

from PIL import Image
import numpy as np

img = Image.open("01.jpg")

array = np.array(img) # PIL.Image 转 numpy

img1 = Image.fromarray(array) # numpy转 PIL.Image
img1 = Image.fromarray(array.astype("uint8"))

img1.save("from_array.jpg")

更多关于Python PIL Image图像处理基本操作实例请查看下面的相关链接

关键词： 图像处理 基本操作 通道模式 相互转换 通道类型