Research on the Region-Growing and Segmentation Technology of Micro-Particle Microscopic Images Based on Color Features
Abstract
:1. Introduction
2. Characteristic Analysis of the Micro-Particle Image
3. Pre-Segmentation of Micro-Particle Images Based on the Color Features
3.1. Fuzzy Enhancement Preprocessing of Color Micro-Particle Images
- 1.
- Determination of the fuzzy membership function.
- 2.
- Enhancement processing of fuzzy domain images.
- 3.
- Restore the fuzzy domain to the spatial domain:
- (1)
- When using the fuzzy contrast enhancement algorithm, the light green color feature of the micro-particles can be effectively enhanced in the image compared with the original image Figure 3a.
- (2)
- When using traditional contrast enhancement, the background color of Figure 3b is also enhanced during the enhancement process. Using color information for image segmentation processing can easily cause mis-segmentation of the background impurity images.
- (3)
- When using the global fuzzy contrast enhancement algorithm (as shown in Figure 3c), the background color also changes greatly while the particle color information is enhanced. Compared with Figure 3b, it has better discrimination and is convenient for extracting the micro-particle target image by using the color features to prepare for subsequent image segmentation.
3.2. Color Target Extraction from Silkworm Micro-Particle Images
3.2.1. Color Feature Space Selection of Micro-Particle Images
- (1)
- In the HSV space, as shown in Figure 3a, the color of the micro-particle target is significantly different from the background, indicating that the color feature can effectively segment the micro-particle target.
- (2)
- (3)
- In the image with enhanced color information (Figure 4c), the color of the micro-particle target is well distinguished from the background, and the particle target is complete and has clear edges.
3.2.2. Determination of the Color Feature Extraction Criterion of Micro-Particle Images
- (1)
- In the HSV space, as long as the H component fluctuated up and down at 65, the variation of the S component was mainly 60 < S < 140. The numerical values were relatively concentrated, and it was feasible to extract micro-particle images by using the color features.
- (2)
- The value of the brightness component V fluctuated stably above 200, indicating that the high gray feature brought about by particle refraction was reliable.
- (3)
- Since the luminance component V had nothing to do with the micro-particle color information, the range of the V component was not set when formulating the color extraction criteria.
4. Research on the Improved Micro-Particle Image Segmentation Algorithm Based on Region Growing
4.1. Automatic Selection of Multiple Sub-Points
4.2. Improved Growing Criteria
4.2.1. Growing Image Determination Based on the G Component
4.2.2. Determination of the Growing Criteria Based on the Grayscale Enhanced Images
5. Experimental Results and Analysis
- Comparison of Color Pre-Segmentation Effects
- For microscopic micro-particle images with uneven illumination, low contrast and complex backgrounds, HSV-based color information extraction could effectively extract micro-particle targets.
- After color enhancement, the micro-particle image segmented according to the color range can remove a large number of impurity targets compared with the original image, and the effect is better and more accurate.
- There was a performance comparison of the improved area-growing algorithm.
- Comparison of Different Region-Growing Algorithms
- Growing Algorithm Comparison
6. Conclusions
- In the extraction of color information, the use of global fuzzy contrast enhancement can improve the problem of microparticle targets not clearly being distinguished in the image, and the extraction of microparticle targets combined with the color-stabilized HSV color space can filter out most of the impurity target points.
- After the results of color pre-segmentation, the subsequent segmentation of the image using the joint improved the gamma transform-enhanced grayscale image using the region growth algorithm was able to segment the complete and clear microparticle targets. The growth time for an image was only 0.792 s, and the IOU accuracy was 83.1%.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
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Algorithm | Visual Field 1 | Visual Field 2 | Visual Field 3 |
---|---|---|---|
Traditional algorithm | Total points: 1318 | 1113 | 906 |
Average points: 94 | 92 | 100 | |
Average IOU: 81.76% | 83.69% | 83.81% | |
Algorithm from [14] | Total points: 717 | 628 | 471 |
Average points: 51 | 52 | 52 | |
Average IOU: 74.11% | 77.39% | 78.6% | |
This paper’s algorithm | Total points: 1037 | 1067 | 723 |
Average points: 74 | 88 | 80 | |
Average IOU: 80.58% | 83.31% | 85.41% |
Algorithm | Growing Image | Growing Time |
---|---|---|
Traditional algorithm | Original grayscale | 0.087 s |
Algorithm from [14] | Original grayscale | 2.416 s |
This paper’s algorithm | Enhanced grayscale | 0.792 s |
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Hu, X.; Chen, Q.; Ye, X.; Zhang, D.; Tang, Y.; Ye, J. Research on the Region-Growing and Segmentation Technology of Micro-Particle Microscopic Images Based on Color Features. Symmetry 2021, 13, 2325. https://doi.org/10.3390/sym13122325
Hu X, Chen Q, Ye X, Zhang D, Tang Y, Ye J. Research on the Region-Growing and Segmentation Technology of Micro-Particle Microscopic Images Based on Color Features. Symmetry. 2021; 13(12):2325. https://doi.org/10.3390/sym13122325
Chicago/Turabian StyleHu, Xinyu, Qi Chen, Xuhui Ye, Daode Zhang, Yuxuan Tang, and Jun Ye. 2021. "Research on the Region-Growing and Segmentation Technology of Micro-Particle Microscopic Images Based on Color Features" Symmetry 13, no. 12: 2325. https://doi.org/10.3390/sym13122325
APA StyleHu, X., Chen, Q., Ye, X., Zhang, D., Tang, Y., & Ye, J. (2021). Research on the Region-Growing and Segmentation Technology of Micro-Particle Microscopic Images Based on Color Features. Symmetry, 13(12), 2325. https://doi.org/10.3390/sym13122325