Application of the Hough Transform to Dispersion Control of Overlapping Particles and Their Agglomerates

IF 0.2 Q4 INSTRUMENTS & INSTRUMENTATION

Devices and Methods of Measurements Pub Date : 2023-10-06 DOI:10.21122/2220-9506-2023-14-3-199-206

P. V. Gulyaev

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Abstract

The dispersion control of micro- and nanoparticles by their images is of great importance for ensuring the specified properties of the particles themselves and materials based on them. The aim of this article was to consider the possibilities of using the Hough transform for dispersion control of overlapping particles and their agglomerates. Analysis of the application of the Hough transform for overlapping particles and their agglomerates showed the following. The particularities of the conventional implementation lead to the preferred registration of large particles, the shift of the centers of overlapping particles, and the distortion of the size values. To use the Hough transform correctly, fine-tuning of all its parameters is required. To automate this process, the dependences of the number and size of particles recorded in the image on the parameters of the Hough transform was investigated. The studies were carried out on test images with a known number and size of particles. The results showed that when the threshold parameters of the Hough transform change, the number of detected particles stabilizes near their optimal values. When the size range of particles detected by the Hough transform changes, the histogram of the particle size distribution changes. In this case, the optimal width of the range is determined by the most stable extremes of the histogram. The maximum center-to-center distance is set at least half of the optimal range. The configuration algorithm is described and implemented. It implies repeatedly running the Hough transform with different combinations of parameters. The algorithm includes stages of coarse and fine-tuning, which allows to getting closer to the optimal parameters. The efficiency of the algorithm has been confirmed on test and real images. Tests have shown that the errors in determining the size and number of particles of the multi-pass Hough transform are on the same level or exceed these indicators for analog methods.

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Hough变换在重叠粒子及其团聚体色散控制中的应用

利用微粒子和纳米粒子的图像对其进行分散控制，对于保证粒子本身及其材料的特定性能具有重要意义。本文的目的是考虑利用霍夫变换对重叠粒子及其团聚体的色散控制的可能性。霍夫变换在重叠粒子及其团聚体中的应用分析如下:传统实现的特殊性导致了大粒子的优先配准、重叠粒子中心的偏移以及尺寸值的畸变。为了正确地使用霍夫变换，需要对其所有参数进行微调。为了使这一过程自动化，研究了图像中记录的颗粒数量和大小对霍夫变换参数的依赖性。这些研究是在已知颗粒数量和大小的测试图像上进行的。结果表明，当霍夫变换的阈值参数发生变化时，检测到的粒子数稳定在其最优值附近。当Hough变换检测到的颗粒大小范围发生变化时，颗粒大小分布的直方图也会发生变化。在这种情况下，范围的最佳宽度由直方图中最稳定的极值决定。最大中心到中心距离设置为至少为最佳距离的一半。描述并实现了组态算法。它意味着用不同的参数组合反复运行霍夫变换。该算法包括粗调和微调阶段，使其更接近最优参数。实验和实际图像验证了该算法的有效性。试验表明，在确定多道霍夫变换的粒子大小和数目时，误差与模拟方法相同或超过这些指标。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Devices and Methods of Measurements INSTRUMENTS & INSTRUMENTATION-

自引率

25.00%

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审稿时长

8 weeks