2

我需要将一些图像转换为 OCR 的二进制文件。

以下是我正在使用的功能:

Mat binarize(Mat & Img, Mat& res, float blocksize, bool inverse)
{
    Img.convertTo(Img,CV_32FC1,1.0/255.0);
    CalcBlockMeanVariance(Img,res, blocksize, inverse);
    res=1.0-res;
    res=Img+res;
    if (inverse) {
        cv::threshold(res,res,0.85,1,cv::THRESH_BINARY_INV);
    } else {
        cv::threshold(res,res,0.85,1,cv::THRESH_BINARY);
    }
    cv::resize(res,res,cv::Size(res.cols/2,res.rows/2));
    
    return res;
}

哪里CalcBlockMeanVariance

void CalcBlockMeanVariance(Mat& Img,Mat& Res,float blockSide, bool inverse) //21 blockSide - the parameter (set greater for larger font on image)
{
    Mat I;
    Img.convertTo(I,CV_32FC1);
    Res=Mat::zeros(Img.rows/blockSide,Img.cols/blockSide,CV_32FC1);
    Mat inpaintmask;
    Mat patch;
    Mat smallImg;
    Scalar m,s;
    
    for(int i=0;i<Img.rows-blockSide;i+=blockSide)
    {
        for (int j=0;j<Img.cols-blockSide;j+=blockSide)
        {
            patch=I(Range(i,i+blockSide+1),Range(j,j+blockSide+1));
            cv::meanStdDev(patch,m,s);
            if(s[0]>0.01) // Thresholding parameter (set smaller for lower contrast image)
            {
                Res.at<float>(i/blockSide,j/blockSide)=m[0];
            }else
            {
                Res.at<float>(i/blockSide,j/blockSide)=0;
            }
        }
    }
    
    cv::resize(I,smallImg,Res.size());
    
    if (inverse) {
        cv::threshold(Res,inpaintmask,0.02,1.0,cv::THRESH_BINARY_INV);
    } else {
        cv::threshold(Res,inpaintmask,0.02,1.0,cv::THRESH_BINARY);
    }
    
    
    Mat inpainted;
    smallImg.convertTo(smallImg,CV_8UC1,255);
    
    inpaintmask.convertTo(inpaintmask,CV_8UC1);
    inpaint(smallImg, inpaintmask, inpainted, 5, INPAINT_TELEA);
    
    cv::resize(inpainted,Res,Img.size());
    Res.convertTo(Res,CV_32FC1,1.0/255.0);
    
}

当我1得到CalcBlockMeanVariance这个blockSide结果时,我试图提高,blockSide但它只会导致更糟糕的结果。

前:

在此处输入图像描述

后:

在此处输入图像描述

谁能建议一种不同的方法将此图像转换为二进制文件作为 OCR 的准备工作?

谢谢。

4

1 回答 1

7

我认为您可以使用Otsu方法进行阈值处理。您可以将其应用于整个图像或图像块。我做了以下步骤:

  • Otsu使用所需输入的方法进行 阈值处理。
  • Closing结果。

Python代码

image = cv2.imread('image4.png', cv2.IMREAD_GRAYSCALE) # reading image
if image is None:
    print 'Can not find the image!'
    exit(-1)
# thresholding image using ostu method
ret, thresh = cv2.threshold(image, 0, 255, cv2.THRESH_BINARY_INV | cv2.THRESH_OTSU) 
# applying closing operation using ellipse kernel
N = 3
kernel = cv2.getStructuringElement(cv2.MORPH_ELLIPSE, (N, N))
thresh = cv2.morphologyEx(thresh, cv2.MORPH_CLOSE, kernel)
# showing the result
cv2.imshow('thresh', thresh)
cv2.waitKey(0)
cv2.destroyAllWindows()

解释

在第一部分中,我使用读取输入图像imread并检查图像是否正确打开!。

image = cv2.imread('image4.png', cv2.IMREAD_GRAYSCALE) # reading image
if image is None:
    print 'Can not find the image!'
    exit(-1)

现在otsu通过将thresh方法THRESH_BINARY_INV | THRESH_OTSU作为其参数来对图像进行阈值处理。该otsu方法基于一个优化问题来寻找阈值的最佳值。所以我通过给它一个下限0和一个上限来提供阈值的可能值范围255

ret, thresh = cv2.threshold(image, 0, 255, cv2.THRESH_BINARY_INV | cv2.THRESH_OTSU)

Ellipse并且使用内核完成关闭操作以去除图像中的黑洞。

kernel = cv2.getStructuringElement(cv2.MORPH_ELLIPSE, (N, N))
thresh = cv2.morphologyEx(thresh, cv2.MORPH_CLOSE, kernel)

结果

图1

于 2014-04-24T05:43:31.403 回答