标签：机器 img 数字图像 cv2 range shape 视觉 imgArray cv

目录

一、图像灰度处理

 1.使用OpenCV转换灰度文件

2. 不使用OpenCV进行灰度转换

二、将彩色图像转化为HSV、HSI 格式

1. HSV格式转换

2. HSI格式转换

三、将车牌数字分割为单个的字符图片

四、总结

五、参考链接

---

一、图像灰度处理

 1.使用OpenCV转换灰度文件

import cv2 as cv
img = cv.imread('C:/Users/86199/Pictures/lena/lena.jpg',1)
img_1 = cv.cvtColor(img,cv.COLOR_BGR2GRAY)
cv.imshow('gray',img_1)
cv.imshow('colour',img)
cv.waitKey(0)

 

2. 不使用OpenCV进行灰度转换

from PIL import Image
I = Image.open('C:/Users/86199/Pictures/lena/lena.jpg')
L = I.convert('L')
L.show()

 

二、将彩色图像转化为HSV、HSI 格式

1. HSV格式转换

将彩色图像（RGB）转换为HSV格式

# open-cv library is installed as cv2 in python
# import cv2 library into this program
import cv2 as cv
 
# read an image using imread() function of cv2
# we have to  pass only the path of the image
img = cv.imread('C:/Users/86199/Pictures/lena/lena.jpg',1)
 
# displaying the image using imshow() function of cv2
# In this : 1st argument is name of the frame
# 2nd argument is the image matrix

cv.imshow('original image',img)
 
# converting the colourfull image into HSV format image
# using cv2.COLOR_BGR2HSV argument of
# the cvtColor() function of cv2
# in this :
# ist argument is the image matrix
# 2nd argument is the attribute
hsv = cv.cvtColor(img, cv.COLOR_BGR2HSV)

 
# displaying the Hsv format image
cv.imshow('HSV format image',hsv)

cv.waitKey(0)

 

2. HSI格式转换

将彩色图像（RGB）转换为HSI格式

import cv2
import numpy as np

def rgbtohsi(rgb_lwpImg):
  rows = int(rgb_lwpImg.shape[0])
  cols = int(rgb_lwpImg.shape[1])
  b, g, r = cv2.split(rgb_lwpImg)
  # 归一化到[0,1]
  b = b / 255.0
  g = g / 255.0
  r = r / 255.0
  hsi_lwpImg = rgb_lwpImg.copy()
  H, S, I = cv2.split(hsi_lwpImg)
  for i in range(rows):
    for j in range(cols):
      num = 0.5 * ((r[i, j]-g[i, j])+(r[i, j]-b[i, j]))
      den = np.sqrt((r[i, j]-g[i, j])**2+(r[i, j]-b[i, j])*(g[i, j]-b[i, j]))
      theta = float(np.arccos(num/den))

      if den == 0:
          H = 0
      elif b[i, j] <= g[i, j]:
        H = theta
      else:
        H = 2*3.14169265 - theta

      min_RGB = min(min(b[i, j], g[i, j]), r[i, j])
      sum = b[i, j]+g[i, j]+r[i, j]
      if sum == 0:
        S = 0
      else:
        S = 1 - 3*min_RGB/sum

      H = H/(2*3.14159265)
      I = sum/3.0
      # 输出HSI图像，扩充到255以方便显示，一般H分量在[0,2pi]之间，S和I在[0,1]之间
      hsi_lwpImg[i, j, 0] = H*255
      hsi_lwpImg[i, j, 1] = S*255
      hsi_lwpImg[i, j, 2] = I*255
  return hsi_lwpImg
if __name__ == '__main__':
  rgb_lwpImg = cv2.imread("C:/Users/86199/Pictures/lena/lena.jpg")
  hsi_lwpImg = rgbtohsi(rgb_lwpImg)
  cv2.imshow('lena.jpg', rgb_lwpImg)
  cv2.imshow('hsi_lwpImg', hsi_lwpImg)
  key = cv2.waitKey(0) & 0xFF
  if key == ord('q'):
    cv2.destroyAllWindows()

 

三、将车牌数字分割为单个的字符图片

 

 

 

 

 代码：

import cv2
import numpy as np
import os


def stackImages(scale, imgArray):
    """
        将多张图像压入同一个窗口显示
        :param scale:float类型，输出图像显示百分比，控制缩放比例，0.5=图像分辨率缩小一半
        :param imgArray:元组嵌套列表，需要排列的图像矩阵
        :return:输出图像
    """
    rows = len(imgArray)
    cols = len(imgArray[0])

    rowsAvailable = isinstance(imgArray[0], list)

    # 用空图片补齐
    for i in range(rows):
        tmp = cols - len(imgArray[i])
        for j in range(tmp):
            img = np.zeros((imgArray[0][0].shape[0], imgArray[0][0].shape[1]), dtype='uint8')
            imgArray[i].append(img)

    # 判断维数
    if rows>=2:
        width = imgArray[0][0].shape[1]
        height = imgArray[0][0].shape[0]

    else:
        width = imgArray[0].shape[1]
        height = imgArray[0].shape[0]

    if rowsAvailable:
        for x in range(0, rows):
            for y in range(0, cols):
                if imgArray[x][y].shape[:2] == imgArray[0][0].shape[:2]:
                    imgArray[x][y] = cv2.resize(imgArray[x][y], (0, 0), None, scale, scale)
                else:
                    imgArray[x][y] = cv2.resize(imgArray[x][y], (imgArray[0][0].shape[1], imgArray[0][0].shape[0]),
                                                None, scale, scale)
                if len(imgArray[x][y].shape) == 2:
                    imgArray[x][y] = cv2.cvtColor(imgArray[x][y], cv2.COLOR_GRAY2BGR)
        imageBlank = np.zeros((height, width, 3), np.uint8)
        hor = [imageBlank] * rows
        hor_con = [imageBlank] * rows
        for x in range(0, rows):
            hor[x] = np.hstack(imgArray[x])
        ver = np.vstack(hor)
    else:
        for x in range(0, rows):
            if imgArray[x].shape[:2] == imgArray[0].shape[:2]:
                imgArray[x] = cv2.resize(imgArray[x], (0, 0), None, scale, scale)
            else:
                imgArray[x] = cv2.resize(imgArray[x], (imgArray[0].shape[1], imgArray[0].shape[0]), None, scale, scale)
            if len(imgArray[x].shape) == 2: imgArray[x] = cv2.cvtColor(imgArray[x], cv2.COLOR_GRAY2BGR)
        hor = np.hstack(imgArray)
        ver = hor
    return ver
# 分割结果输出路径
output_dir = "./output"
# 车牌路径
file_path="./car/"
# 读取所有车牌
cars = os.listdir(file_path)
cars.sort()

# 循环操作每一张车牌
for car in cars:
    # 读取图片
    print("正在处理"+file_path+car)
    src = cv2.imread(file_path+car)
    img = src.copy()

    # 预处理去除螺丝点
    cv2.circle(img, (145, 20), 10, (255, 0, 0), thickness=-1)
    cv2.circle(img, (430, 20), 10, (255, 0, 0), thickness=-1)
    cv2.circle(img, (145, 170), 10, (255, 0, 0), thickness=-1)
    cv2.circle(img, (430, 170), 10, (255, 0, 0), thickness=-1)
    cv2.circle(img, (180, 90), 10, (255, 0, 0), thickness=-1)

    # 转灰度
    gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)

    # 二值化
    adaptive_thresh = cv2.adaptiveThreshold(gray, 255, cv2.ADAPTIVE_THRESH_MEAN_C, cv2.THRESH_BINARY_INV, 333, 1)

    # 闭运算
    kernel = np.ones((5, 5), int)
    morphologyEx = cv2.morphologyEx(adaptive_thresh, cv2.MORPH_CLOSE, kernel)

    # 找边界
    contours, hierarchy = cv2.findContours(morphologyEx, cv2.RETR_LIST, cv2.CHAIN_APPROX_SIMPLE)

    # 画边界
    img_1 = img.copy()
    cv2.drawContours(img_1, contours, -1, (0, 0, 0), -1)

    imgStack = stackImages(0.7, ([src, img, gray], [adaptive_thresh, morphologyEx, img_1]))
    cv2.imshow("imgStack", imgStack)
    cv2.waitKey(0)

    # 转灰度为了方便切割
    gray_1 = cv2.cvtColor(img_1, cv2.COLOR_BGR2GRAY)

    # 每一列的白色数量
    white = []
    # 每一列的黑色数量
    black = []
    # 区域高度取决于图片高
    height = gray_1.shape[0]
    # 区域宽度取决于图片宽
    width = gray_1.shape[1]
    # 最大白色数量
    white_max = 0
    # 最大黑色数量
    black_max = 0
    # 计算每一列的黑白色像素总和
    for i in range(width):
        s = 0  # 这一列白色总数
        t = 0  # 这一列黑色总数
        for j in range(height):
            if gray_1[j][i] == 255:
                s += 1
            if gray_1[j][i] == 0:
                t += 1
        white_max = max(white_max, s)
        black_max = max(black_max, t)
        white.append(s)
        black.append(t)


    # 找到右边界
    def find_end(start):
        end = start + 1
        for m in range(start + 1, width - 1):
            # 基本全黑的列视为边界
            if black[m] >= black_max * 0.95:  # 0.95这个参数请多调整，对应下面的0.05
                end = m
                break
        return end


    # 临时变量
    n = 1

    # 起始位置
    start = 1

    # 结束位置
    end = 2

    # 分割结果数量
    num=0

    # 分割结果
    res = []

    # 保存分割结果路径,以图片名命名
    output_path= output_dir + car.split('.')[0]
    if not os.path.exists(output_path):
        os.makedirs(output_path)
    # 从左边网右边遍历
    while n < width - 2:
        n += 1

        # 找到白色即为确定起始地址
        # 不可以直接 white[n] > white_max
        if white[n] > 0.05 * white_max:
            start = n
            # 找到结束坐标
            end = find_end(start)
            # 下一个的起始地址
            n = end

            # 确保找到的是符合要求的,过小不是车牌号
            if end - start > 10:
                # 分割
                char = gray_1[1:height, start - 5:end + 5]
                # 保存分割结果到文件
                cv2.imwrite(output_path+'/' + str(num) + '.jpg',char)
                num+=1
                # 重新绘制大小
                char = cv2.resize(char, (300, 300), interpolation=cv2.INTER_CUBIC)
                # 添加到结果集合
                res.append(char)

                # cv2.imshow("imgStack", char)
                # cv2.waitKey(0)

    # 构造结果元祖方便结果展示
    res2 = (res[:2], res[2:4], res[4:6], res[6:])
    # 显示结果
    imgStack = stackImages(0.5, res2)
    cv2.imshow("imgStack", imgStack)
    cv2.waitKey(0)
cv2.destroyAllWindows()

 

 

 

 

 

四、总结

本文简单运用OpenCV对彩色图像进行各种操作，包括转化为灰度文件、HSV、HSI格式。并将车牌数字分割为单个字符图片HSI和HSV格式的组成， HSI 与 HSV非常相似，不同的是仅用HSI用亮度替代了明度。

五、参考链接

OpenCV相关操作_Baker的博客-CSDN博客

标签：机器,img,数字图像,cv2,range,shape,视觉,imgArray,cv
来源： https://blog.csdn.net/qq_52445967/article/details/122136079

本站声明： 1. iCode9 技术分享网（下文简称本站）提供的所有内容，仅供技术学习、探讨和分享；
2. 关于本站的所有留言、评论、转载及引用，纯属内容发起人的个人观点，与本站观点和立场无关；
3. 关于本站的所有言论和文字，纯属内容发起人的个人观点，与本站观点和立场无关；
4. 本站文章均是网友提供，不完全保证技术分享内容的完整性、准确性、时效性、风险性和版权归属；如您发现该文章侵犯了您的权益，可联系我们第一时间进行删除；
5. 本站为非盈利性的个人网站，所有内容不会用来进行牟利，也不会利用任何形式的广告来间接获益，纯粹是为了广大技术爱好者提供技术内容和技术思想的分享性交流网站。