(编辑:jimmy 日期: 2024/12/28 浏览:2)
原理:将RGB图像转换到YCRCB空间,肤色像素点会聚集到一个椭圆区域。先定义一个椭圆模型,然后将每个RGB像素点转换到YCRCB空间比对是否再椭圆区域,是的话判断为皮肤。
YCRCB颜色空间
椭圆模型
代码
def ellipse_detect(image): """ :param image: 图片路径 :return: None """ img = cv2.imread(image,cv2.IMREAD_COLOR) skinCrCbHist = np.zeros((256,256), dtype= np.uint8 ) cv2.ellipse(skinCrCbHist ,(113,155),(23,15),43,0, 360, (255,255,255),-1) YCRCB = cv2.cvtColor(img,cv2.COLOR_BGR2YCR_CB) (y,cr,cb)= cv2.split(YCRCB) skin = np.zeros(cr.shape, dtype=np.uint8) (x,y)= cr.shape for i in range(0,x): for j in range(0,y): CR= YCRCB[i,j,1] CB= YCRCB[i,j,2] if skinCrCbHist [CR,CB]>0: skin[i,j]= 255 cv2.namedWindow(image, cv2.WINDOW_NORMAL) cv2.imshow(image, img) dst = cv2.bitwise_and(img,img,mask= skin) cv2.namedWindow("cutout", cv2.WINDOW_NORMAL) cv2.imshow("cutout",dst) cv2.waitKey()
效果
原理
针对YCRCB中CR分量的处理,将RGB转换为YCRCB,对CR通道单独进行otsu处理,otsu方法opencv里用threshold
代码
def cr_otsu(image): """YCrCb颜色空间的Cr分量+Otsu阈值分割 :param image: 图片路径 :return: None """ img = cv2.imread(image, cv2.IMREAD_COLOR) ycrcb = cv2.cvtColor(img, cv2.COLOR_BGR2YCR_CB) (y, cr, cb) = cv2.split(ycrcb) cr1 = cv2.GaussianBlur(cr, (5, 5), 0) _, skin = cv2.threshold(cr1,0,255,cv2.THRESH_BINARY+cv2.THRESH_OTSU) cv2.namedWindow("image raw", cv2.WINDOW_NORMAL) cv2.imshow("image raw", img) cv2.namedWindow("image CR", cv2.WINDOW_NORMAL) cv2.imshow("image CR", cr1) cv2.namedWindow("Skin Cr+OTSU", cv2.WINDOW_NORMAL) cv2.imshow("Skin Cr+OTSU", skin) dst = cv2.bitwise_and(img, img, mask=skin) cv2.namedWindow("seperate", cv2.WINDOW_NORMAL) cv2.imshow("seperate", dst) cv2.waitKey()
效果
原理
类似于第二种方法,只不过是对CR和CB两个通道综合考虑
代码
def crcb_range_sceening(image): """ :param image: 图片路径 :return: None """ img = cv2.imread(image,cv2.IMREAD_COLOR) ycrcb=cv2.cvtColor(img,cv2.COLOR_BGR2YCR_CB) (y,cr,cb)= cv2.split(ycrcb) skin = np.zeros(cr.shape,dtype= np.uint8) (x,y)= cr.shape for i in range(0,x): for j in range(0,y): if (cr[i][j]>140)and(cr[i][j])<175 and (cr[i][j]>100) and (cb[i][j])<120: skin[i][j]= 255 else: skin[i][j] = 0 cv2.namedWindow(image,cv2.WINDOW_NORMAL) cv2.imshow(image,img) cv2.namedWindow(image+"skin2 cr+cb",cv2.WINDOW_NORMAL) cv2.imshow(image+"skin2 cr+cb",skin) dst = cv2.bitwise_and(img,img,mask=skin) cv2.namedWindow("cutout",cv2.WINDOW_NORMAL) cv2.imshow("cutout",dst) cv2.waitKey()
效果
原理
还是转换空间然后每个通道设置一个阈值综合考虑,进行二值化操作。
代码
def hsv_detect(image): """ :param image: 图片路径 :return: None """ img = cv2.imread(image,cv2.IMREAD_COLOR) hsv=cv2.cvtColor(img,cv2.COLOR_BGR2HSV) (_h,_s,_v)= cv2.split(hsv) skin= np.zeros(_h.shape,dtype=np.uint8) (x,y)= _h.shape for i in range(0,x): for j in range(0,y): if(_h[i][j]>7) and (_h[i][j]<20) and (_s[i][j]>28) and (_s[i][j]<255) and (_v[i][j]>50 ) and (_v[i][j]<255): skin[i][j] = 255 else: skin[i][j] = 0 cv2.namedWindow(image, cv2.WINDOW_NORMAL) cv2.imshow(image, img) cv2.namedWindow(image + "hsv", cv2.WINDOW_NORMAL) cv2.imshow(image + "hsv", skin) dst = cv2.bitwise_and(img, img, mask=skin) cv2.namedWindow("cutout", cv2.WINDOW_NORMAL) cv2.imshow("cutout", dst) cv2.waitKey()
效果
示例
import cv2 import numpy as np def ellipse_detect(image): """ :param image: img path :return: None """ img = cv2.imread(image, cv2.IMREAD_COLOR) skinCrCbHist = np.zeros((256, 256), dtype=np.uint8) cv2.ellipse(skinCrCbHist, (113, 155), (23, 15), 43, 0, 360, (255, 255, 255), -1) YCRCB = cv2.cvtColor(img, cv2.COLOR_BGR2YCR_CB) (y, cr, cb) = cv2.split(YCRCB) skin = np.zeros(cr.shape, dtype=np.uint8) (x, y) = cr.shape for i in range(0, x): for j in range(0, y): CR = YCRCB[i, j, 1] CB = YCRCB[i, j, 2] if skinCrCbHist[CR, CB] > 0: skin[i, j] = 255 cv2.namedWindow(image, cv2.WINDOW_NORMAL) cv2.imshow(image, img) dst = cv2.bitwise_and(img, img, mask=skin) cv2.namedWindow("cutout", cv2.WINDOW_NORMAL) cv2.imshow("cutout", dst) cv2.waitKey() if __name__ == '__main__': ellipse_detect('./test.png')
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