由我们上一章所学,导入图片将其转化为灰度图并定义显示图片函数cv_show()。
import cv2 #opencv读取的格式是BGR
import numpy as np
import matplotlib.pyplot as plt#Matplotlib是RGB
%matplotlib inline
def cv_show(name,img):
cv2.imshow(name,img)
cv2.waitKey(0)
cv2.destroyAllWindows()
img = cv2.imread('./data/gd01.jpg')
img_gray = cv2.cvtColor(img,cv2.COLOR_BGR2GRAY)
# img_gray.shape 为 (300,400)cv_show('win1',img_gray)
HSV:
hsv = cv2.cvtColor(img,cv2.COLOR_BGR2RGB) # 转换成RGB
cv_show('win',hsv)
上章所学我们得知,矩阵中unit8值(0-255)越大表示越亮,我们可以设定一个阈值thresh,比它大的做什么什么操作,比它小的做什么什么操作。
ret, dst = cv2.threshold(src, thresh, maxval, type) src: 输入图,只能输入单通道图像,通常来说为灰度图
ret, thresh1 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_BINARY)
ret, thresh2 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_BINARY_INV)
ret, thresh3 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_TRUNC)
ret, thresh4 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_TOZERO)
ret, thresh5 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_TOZERO_INV)
# ps: ret为127 thresh1-5为图片矩阵
titles = ['Original Image', 'BINARY', 'BINARY_INV', 'TRUNC', 'TOZERO', 'TOZERO_INV']
images = [img, thresh1, thresh2, thresh3, thresh4, thresh5]
for i in range(6):
plt.subplot(2, 3, i + 1), plt.imshow(images[i], 'gray')
plt.title(titles[i])
plt.xticks([]), plt.yticks([])
plt.show()
可以看到,与原始图片对比,(阈值127)情况下BINARY在亮的地方更亮了(变为255),暗的地方更暗了(变为了0)。BINART_INV与其相反。后三种方法同理如上面所解释。
对图像数据进行滤波操作。
在这之前我们先来学习一下如何给图片加入噪声,变成以下这种。
可以看到其实就是在这个矩阵随机位置的像素点变成了白色,255。
img = cv2.imread('./data/gd07.jpg')
#获取图片行、列、通道数
rows,cols,channels = img.shape
for i in range(0,5000):
#根据在0和行-1之间获取随机整数
x = np.random.randint(0,rows-1)
#根据在0和列-1之间获取随机整数
y = np.random.randint(0,cols-1)
#将通道颜色改为255, (255,255,255)
img[x,y][0] = 255
img[x,y][1] = 255
img[x,y][2] = 255
cv_show('win',img)那么现在我们有了这种图像,该学习如何去掉噪音点了~
均值滤波--简单的平均卷积操作(卷积核大小3*3内部值都是1,下方参数是3*3矩阵均值)
blur = cv2.blur(img, (3, 3))
cv_show('win',blur)
方框滤波--基本和均值一样,可以选择归一化(-1表示颜色通道一致,3*3同上,normalize=True做归一化,此时与上方均值滤波是一样的。)
box = cv2.boxFilter(img,-1,(3,3), normalize=True)
cv_show('win',box)
方框滤波--基本和均值一样,可以选择归一化,容易越界。(不再均值除以9,和大于255按255赋值。)
box = cv2.boxFilter(img,-1,(3,3), normalize=False)
cv_show('win',box)
高斯滤波--高斯模糊的卷积核里的数值是满足高斯分布,相当于更重视中间的。(此时卷积核不再全是1,而是离的近的相对较大,离得远的相对较小。)
aussian = cv2.GaussianBlur(img, (5, 5), 1)
cv_show('win',aussian)
中值滤波--相当于用中值代替(5*5的矩阵25个数,中间值为处理结果。)
median = cv2.medianBlur(img, 5) # 中值滤波
cv_show('win',median)
均值、高斯、中值滤波对比:
res = np.hstack((blur,aussian,median))
#print (res)
cv_show('median vs average', res)
所谓腐蚀操作,就是一点点侵蚀图片中的内容,如我刚刚挥笔写下的“帅”字,它长了很多“毛”,我们要把他侵蚀掉:
img = cv2.imread('./data/s.jpg', cv2.IMREAD_GRAYSCALE)
kernel = np.ones((3,3),np.uint8)
erosion = cv2.erode(img,kernel,iterations = 1)
cv_show('win',erosion)erosion = cv2.erode(img,kernel,iterations = 1)
这不比之前更帅了(被腐蚀得线条也变瘦了)
关于卷积核选取和迭代次数:
上面选用3*3,以帅字为例,当3*3区域出现不同值(如这里0和255),那么就把这个点腐蚀掉。
卷积核如果选择太大,可能会直接被侵蚀没掉。
pie = cv2.imread('./data/pie.png')
kernel = np.ones((30,30),np.uint8)
erosion_1 = cv2.erode(pie,kernel,iterations = 1)
erosion_2 = cv2.erode(pie,kernel,iterations = 3)
erosion_3 = cv2.erode(pie,kernel,iterations = 5)
res = np.hstack((erosion_1,erosion_2,erosion_3))
cv_show('win',res)
我们上面不仅把“帅”边上长的“毛”去掉了,由于我们选择3*3卷积核,还顺便让它变瘦了,我们就以它变瘦之后的图片为例,再让它胖起来。
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
kernel = np.ones((3,3),np.uint8)
shuai = cv2.erode(img,kernel,iterations = 1)
kernel = np.ones((3,3),np.uint8)
shuai_PLUS = cv2.dilate(shuai,kernel,iterations = 1)
cv_show('win',shuai_PLUS )shuai_PLUS = cv2.dilate(shuai,kernel,iterations = 1)
同理
pie = cv2.imread('./data/pie.png')
kernel = np.ones((30,30),np.uint8)
dilate_1 = cv2.dilate(pie,kernel,iterations = 1)
dilate_2 = cv2.dilate(pie,kernel,iterations = 2)
dilate_3 = cv2.dilate(pie,kernel,iterations = 3)
res = np.hstack((dilate_1,dilate_2,dilate_3))
cv_show('win',res)
开:先腐蚀,再膨胀
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
kernel = np.ones((5,5),np.uint8)
opening = cv2.morphologyEx(img, cv2.MORPH_OPEN, kernel)
cv_show('win',opening)opening = cv2.morphologyEx(img, cv2.MORPH_OPEN, kernel)
闭:先膨胀,再腐蚀
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
kernel = np.ones((5,5),np.uint8)
closing = cv2.morphologyEx(img, cv2.MORPH_CLOSE, kernel)
cv_show('win',closing)closing = cv2.morphologyEx(img, cv2.MORPH_CLOSE, kernel)
梯度=膨胀-腐蚀
pie = cv2.imread('./data/pie.png',cv2.IMREAD_GRAYSCALE)
kernel = np.ones((7,7),np.uint8)
dilate = cv2.dilate(pie,kernel,iterations = 5)
erosion = cv2.erode(pie,kernel,iterations = 5)
res = np.hstack((dilate,erosion))
cv_show('win',res)以下是经过5次腐蚀和5次膨胀后的图像:
获得边界信息:梯度运算
gradient = cv2.morphologyEx(pie, cv2.MORPH_GRADIENT, kernel)
cv_show('win',gradient)gradient = cv2.morphologyEx(pie, cv2.MORPH_GRADIENT, kernel)
# 礼帽
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
tophat = cv2.morphologyEx(img, cv2.MORPH_TOPHAT, kernel)
cv_show('win',tophat)(只剩下“毛”了 )
# 黑帽
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
blackhat = cv2.morphologyEx(img,cv2.MORPH_BLACKHAT, kernel)
cv_show('win',blackhat)(只剩下小轮廓了)
我们依旧引入图像pie
img = cv2.imread('./data/pie.png',cv2.IMREAD_GRAYSCALE)
cv_show('win',img)
可见在边缘部分(黑白交界),梯度比较大。
定义Gx,Gy处理水平和竖直方向上的梯度。
sobelx = cv2.Sobel(img,cv2.CV_64F,1,0,ksize=3)
cv_show('sobelx',sobelx)dst = cv2.Sobel(src, ddepth, dx, dy, ksize)
为什么只有一半呢?
我们定义的矩阵计算时是右-左,白-黑>0正常显示,黑-白<0进行了截断为0,
白到黑是正数,黑到白就是负数了,所有的负数会被截断成0,所以要取绝对值。
我们需要对其进行一下转换:
sobelx = cv2.Sobel(img,cv2.CV_64F,1,0,ksize=3)
sobelx = cv2.convertScaleAbs(sobelx)
cv_show('sobelx',sobelx)sobelx = cv2.convertScaleAbs(sobelx)
上面是水平方向,下面是竖直方向:
sobely = cv2.Sobel(img,cv2.CV_64F,0,1,ksize=3)
sobely = cv2.convertScaleAbs(sobely)
cv_show('sobelx',sobely)
分别计算x和y,再求和:
sobelxy = cv2.addWeighted(sobelx,0.5,sobely,0.5,0)
cv_show('sobelxy',sobelxy)
但不建议都是设置成1,效果可能不好。
sobelxy=cv2.Sobel(img,cv2.CV_64F,1,1,ksize=3)
sobelxy = cv2.convertScaleAbs(sobelxy)
cv_show('sobelxy',sobelxy)
建议:分别算Gx,Gy自己进行求和操作:
img = cv2.imread('./data/gd01.jpg',cv2.IMREAD_GRAYSCALE)
sobelx = cv2.Sobel(img,cv2.CV_64F,1,0,ksize=3)
sobelx = cv2.convertScaleAbs(sobelx)
sobely = cv2.Sobel(img,cv2.CV_64F,0,1,ksize=3)
sobely = cv2.convertScaleAbs(sobely)
sobelxy = cv2.addWeighted(sobelx,0.5,sobely,0.5,0)
sobelxy2=cv2.Sobel(img,cv2.CV_64F,1,1,ksize=3)
sobelxy2 = cv2.convertScaleAbs(sobelxy2)
res = np.hstack((sobelxy,sobelxy2))
cv_show('res',res)
Scharr算子
laplacian算子
核中数值有差异,Scharr敏感些。
laplacian算子涉及二阶导,更加敏感同时对噪声也更加敏感,一般和其他方法配合使用。
原理同上,我们来对比一下这三种算子效果:
img = cv2.imread('./data/gd01.jpg',cv2.IMREAD_GRAYSCALE)
sobelx = cv2.Sobel(img,cv2.CV_64F,1,0,ksize=3)
sobely = cv2.Sobel(img,cv2.CV_64F,0,1,ksize=3)
sobelx = cv2.convertScaleAbs(sobelx)
sobely = cv2.convertScaleAbs(sobely)
sobelxy = cv2.addWeighted(sobelx,0.5,sobely,0.5,0)
scharrx = cv2.Scharr(img,cv2.CV_64F,1,0)
scharry = cv2.Scharr(img,cv2.CV_64F,0,1)
scharrx = cv2.convertScaleAbs(scharrx)
scharry = cv2.convertScaleAbs(scharry)
scharrxy = cv2.addWeighted(scharrx,0.5,scharry,0.5,0)
laplacian = cv2.Laplacian(img,cv2.CV_64F)
laplacian = cv2.convertScaleAbs(laplacian)
res = np.hstack((sobelxy,scharrxy,laplacian))
cv_show('res',res)scharrx = cv2.Scharr(img,cv2.CV_64F,1,0)
laplacian = cv2.Laplacian(img,cv2.CV_64F)
图像阈值:
ret, thresh1 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_BINARY)
ret, thresh2 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_BINARY_INV)
ret, thresh3 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_TRUNC)
ret, thresh4 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_TOZERO)
ret, thresh5 = cv2.threshold(img_gray, 127, 255, cv2.THRESH_TOZERO_INV)
# ps: ret为127 thresh1-5为图片矩阵
titles = ['Original Image', 'BINARY', 'BINARY_INV', 'TRUNC', 'TOZERO', 'TOZERO_INV']
images = [img, thresh1, thresh2, thresh3, thresh4, thresh5]
for i in range(6):
plt.subplot(2, 3, i + 1), plt.imshow(images[i], 'gray')
plt.title(titles[i])
plt.xticks([]), plt.yticks([])
plt.show()图像平滑
# 加入噪声
img = cv2.imread('./data/gd07.jpg')
#获取图片行、列、通道数
rows,cols,channels = img.shape
for i in range(0,5000):
#根据在0和行-1之间获取随机整数
x = np.random.randint(0,rows-1)
#根据在0和列-1之间获取随机整数
y = np.random.randint(0,cols-1)
#将通道颜色改为255, (255,255,255)
img[x,y][0] = 255
img[x,y][1] = 255
img[x,y][2] = 255
cv_show('win',img)blur = cv2.blur(img, (3, 3))
box = cv2.boxFilter(img,-1,(3,3), normalize=True)
aussian = cv2.GaussianBlur(img, (5, 5), 1)
median = cv2.medianBlur(img, 5)
res = np.hstack((blur,aussian,median))
cv_show('median vs average', res)形态学-腐蚀
img = cv2.imread('./data/s.jpg', cv2.IMREAD_GRAYSCALE)
kernel = np.ones((3,3),np.uint8)
erosion = cv2.erode(img,kernel,iterations = 1)
cv_show('win',erosion)形态学-膨胀
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
kernel = np.ones((3,3),np.uint8)
shuai = cv2.erode(img,kernel,iterations = 1)
kernel = np.ones((3,3),np.uint8)
shuai_PLUS = cv2.dilate(shuai,kernel,iterations = 1)
cv_show('win',shuai_PLUS )开运算与闭运算
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
kernel = np.ones((5,5),np.uint8)
opening = cv2.morphologyEx(img, cv2.MORPH_OPEN, kernel)
cv_show('win',opening)梯度运算
gradient = cv2.morphologyEx(pie, cv2.MORPH_GRADIENT, kernel)
cv_show('win',gradient)礼帽与黑帽
# 礼帽
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
tophat = cv2.morphologyEx(img, cv2.MORPH_TOPHAT, kernel)
cv_show('win',tophat)
# 黑帽
img = cv2.imread('./data/s.jpg',cv2.IMREAD_GRAYSCALE)
blackhat = cv2.morphologyEx(img,cv2.MORPH_BLACKHAT, kernel)
cv_show('win',blackhat)Sobel、Scharr、Laplacian算子
img = cv2.imread('./data/gd01.jpg',cv2.IMREAD_GRAYSCALE)
sobelx = cv2.Sobel(img,cv2.CV_64F,1,0,ksize=3)
sobely = cv2.Sobel(img,cv2.CV_64F,0,1,ksize=3)
sobelx = cv2.convertScaleAbs(sobelx)
sobely = cv2.convertScaleAbs(sobely)
sobelxy = cv2.addWeighted(sobelx,0.5,sobely,0.5,0)
scharrx = cv2.Scharr(img,cv2.CV_64F,1,0)
scharry = cv2.Scharr(img,cv2.CV_64F,0,1)
scharrx = cv2.convertScaleAbs(scharrx)
scharry = cv2.convertScaleAbs(scharry)
scharrxy = cv2.addWeighted(scharrx,0.5,scharry,0.5,0)
laplacian = cv2.Laplacian(img,cv2.CV_64F)
laplacian = cv2.convertScaleAbs(laplacian)
res = np.hstack((sobelxy,scharrxy,laplacian))
cv_show('res',res)
