CAJ | 학술논문

为了有效克服果穗形状畸变和穗粒颜色差异对穗粒分割的影响，该文提出一种准确、鲁棒的玉米果穗穗粒分割方法。该方法利用果穗三维形状特征校正果穗径向畸变以最大程度恢复图像上果穗表面信息；采用分级阈值分割策略确定每颗穗粒最佳阈值范围，并利用穗粒几何特征实现穗粒初次筛分，消除穗粒间粘连效应；结合主成份分析和支持向量模型完成穗粒的二次筛分，生成果穗表面穗粒分布图。该方法整合了果穗径向畸变－分级阈值－穗粒多级筛分，实现果穗穗粒的精准分割，为玉米果穗自动化考种提供了基础方法。试验结果表明提出方法在穗粒分割准确性和鲁棒性上具有显著优势，平均计算效率达15 s/果穗。
위료유효극복과수형상기변화수립안색차이대수립분할적영향，해문제출일충준학、로봉적옥미과수수립분할방법。해방법이용과수삼유형상특정교정과수경향기변이최대정도회복도상상과수표면신식；채용분급역치분할책략학정매과수립최가역치범위，병이용수립궤하특정실현수립초차사분，소제수립간점련효응；결합주성빈분석화지지향량모형완성수립적이차사분，생성과수표면수립분포도。해방법정합료과수경향기변－분급역치－수립다급사분，실현과수수립적정준분할，위옥미과수자동화고충제공료기출방법。시험결과표명제출방법재수립분할준학성화로봉성상구유현저우세，평균계산효솔체15 s/과수。
The phenotypic characteristics of corn ear are closely related with kernels information of corn ear. For example, ear rows, kernels in row, total kernel number and kernel shape are directly determined by kernels distribution in the surface of corn ear. However, the quantitative analysis of kernels based on images of corn ears is a challenging task owing to shape distortion and color difference. In this paper, we presented a novel segmentation method to extract kernels from the image of corn ear, which was effective to overcome the shape distortion and color differences of kernels. The shape distortion of kernels in images manifests that kernel shape was highly sensitive to the imaging angle and orientation of corn ears, i.e. kernels in the different positions of the same image showed completely different shape characteristics, such as area and aspect ratio etc. Thus, the shape information of kernels needed to be recovered from the image of corn ear. Considering the diversities of corn ears, especially variegated ears, common segmentation methods based on color and threshold parameters were difficult to exactly extract all kernels since the threshold values of variegated kernels were located in the large distribution range. Hence it was necessary to find the local threshold for each kernel in the image of corn ear. The proposed method consisted of three main steps: radial distortion correction of corn ear, hierarchical threshold, and multilevel screening of kernels. In the first step, a radial distortion correction method was developed to recover the surface information of corn ear, which unfolded the surface of corn ear along its radical direction according to the three-dimensional shape characteristics, and generated a corrected image in which the edges of corn ear were extended and the shapes of kernels were restored for the subsequent analysis. In the second step, a hierarchical threshold strategy was applied to iteratively segment kernels from the image of corn ear. Following each threshold process, the geometrical properties (area and perimeter etc.) of segmented objects were respectively calculated and further used to evaluate if they can be used to classify valid kernels. By hierarchical thresholds, the adaptive local threshold for each kernel can be detected. Therefore it was useful for elimination of adhesion effect between kernels. In the last step, feature extraction, principal component analysis (PCA) and support vector machine (SVM) were combined to investigate the validness of segmented kernels. For each kernel, 115 shape, color and texture feature descriptors were extracted, and a 19-dimentional vector was generated based on PCA. Then, a SVM model of kernels was trained and tested using the training samples with 2164 images of kernels. This model was used to filter out invalid segmented objects, e.g. abortive, vacant, or bare area. Finally, segmented objects which were determined as valid kernels were collected to build a distribution image of kernels, which represented kernel information of half corn surface and were quite appropriate for calculating the phenotypic characteristics of corn ear and its kernels. Experimental results demonstrated the proposed method has significant advantages than those that already existing in accuracy and robustness for kernel segmentation of various types of corn ears, thus it can be used as fundamental method for automated trait analysis of corn ear. Under the mode of the highest accuracy, the average computation efficiency was 15 second per ear. In the future work, parallel computation and parameters templates techniques are needed to improve the algorithm efficiency.