Fuzzy clustering of fuzzy data considering the shape of the membership functions using a novel representation learning technique

Alireza Khastan; Elham Eskandari

Kybernetika (2025)

  • Issue: 2, page 168-184
  • ISSN: 0023-5954

Abstract

top
Most existing distance measures for fuzzy data do not capture differences in the shapes of the left and right tails of membership functions. As a result, they may calculate a distance of zero between fuzzy data even when these differences exist. Additionally, some distance measures cannot compute distances between fuzzy data when their membership functions differ in type. In this paper, inspired by human visual perception, we propose a fuzzy clustering method for fuzzy data using a novel representation technique that is capable of detecting small differences in the shapes of the left and right tails of membership functions. Moreover, it effectively clusters fuzzy data even when their membership functions differ in type. By utilizing the pre-trained ResNet50 network as a feature extractor and applying the FCM clustering method to the output from the last convolutional layer, our approach achieves high accuracy in clustering both synthetic and real data sets. Experimental results demonstrate that our method achieved a Rand Index of 0.9965, outperforming state-of-the-art methods, making it particularly suitable for applications that require high clustering accuracy.

How to cite

top

Khastan, Alireza, and Eskandari, Elham. "Fuzzy clustering of fuzzy data considering the shape of the membership functions using a novel representation learning technique." Kybernetika (2025): 168-184. <http://eudml.org/doc/299976>.

@article{Khastan2025,
abstract = {Most existing distance measures for fuzzy data do not capture differences in the shapes of the left and right tails of membership functions. As a result, they may calculate a distance of zero between fuzzy data even when these differences exist. Additionally, some distance measures cannot compute distances between fuzzy data when their membership functions differ in type. In this paper, inspired by human visual perception, we propose a fuzzy clustering method for fuzzy data using a novel representation technique that is capable of detecting small differences in the shapes of the left and right tails of membership functions. Moreover, it effectively clusters fuzzy data even when their membership functions differ in type. By utilizing the pre-trained ResNet50 network as a feature extractor and applying the FCM clustering method to the output from the last convolutional layer, our approach achieves high accuracy in clustering both synthetic and real data sets. Experimental results demonstrate that our method achieved a Rand Index of 0.9965, outperforming state-of-the-art methods, making it particularly suitable for applications that require high clustering accuracy.},
author = {Khastan, Alireza, Eskandari, Elham},
journal = {Kybernetika},
keywords = {fuzzy data; resnet; representation learning; fuzzy clustering; convolutional neural networks},
language = {eng},
number = {2},
pages = {168-184},
publisher = {Institute of Information Theory and Automation AS CR},
title = {Fuzzy clustering of fuzzy data considering the shape of the membership functions using a novel representation learning technique},
url = {http://eudml.org/doc/299976},
year = {2025},
}

TY - JOUR
AU - Khastan, Alireza
AU - Eskandari, Elham
TI - Fuzzy clustering of fuzzy data considering the shape of the membership functions using a novel representation learning technique
JO - Kybernetika
PY - 2025
PB - Institute of Information Theory and Automation AS CR
IS - 2
SP - 168
EP - 184
AB - Most existing distance measures for fuzzy data do not capture differences in the shapes of the left and right tails of membership functions. As a result, they may calculate a distance of zero between fuzzy data even when these differences exist. Additionally, some distance measures cannot compute distances between fuzzy data when their membership functions differ in type. In this paper, inspired by human visual perception, we propose a fuzzy clustering method for fuzzy data using a novel representation technique that is capable of detecting small differences in the shapes of the left and right tails of membership functions. Moreover, it effectively clusters fuzzy data even when their membership functions differ in type. By utilizing the pre-trained ResNet50 network as a feature extractor and applying the FCM clustering method to the output from the last convolutional layer, our approach achieves high accuracy in clustering both synthetic and real data sets. Experimental results demonstrate that our method achieved a Rand Index of 0.9965, outperforming state-of-the-art methods, making it particularly suitable for applications that require high clustering accuracy.
LA - eng
KW - fuzzy data; resnet; representation learning; fuzzy clustering; convolutional neural networks
UR - http://eudml.org/doc/299976
ER -

References

top
  1. Alguliyev, R. M., Aliguliyev, R. M., Alakbarov, R. G., Constrained k-means algorithm for resource allocation in mobile cloudlets., Kybernetika 59 (2023), 1, 88-109. 
  2. Bede, B., Mathematics of Fuzzy Sets and Fuzzy Logic., Springer, Berlin, Heidelberg 2013. Zbl1271.03001MR3024762
  3. Bezdek, J. C., Pattern Recognition with Fuzzy Objective Function Algorithms., Springer, New York 1981. Zbl0503.68069MR0631231
  4. Castellano, G., Vessio, G., , Int. J. Computer Vision 130 (2022), 11, 2590-2605. DOI
  5. Chen, Y., Zhou, S., Zhang, X., Liu, D., Fu, C., , Pattern Recogn. Lett. 157 (2022), 60-66. DOI
  6. Coppi, R., D'Urso, P., Giordani, P., , Comput. Statist. Data Analysis 56 (2012), 4, 915-927. MR2888734DOI
  7. Deng, J., Dong, W., Socher, R., Li, L. J., Li, K., Fei-Fei, L., Imagenet: A largescale hierarchical image database., In: IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 2009, pp. 248-255. 
  8. Ding, W., Abdel-Basset, M., Hawash, H., Pedrycz, W., , IEEE Trans. Fuzzy Systems 30 (2021), 4, 1088-1101. DOI
  9. D'Urso, P., Giovanni, L. De, , Chemometr. Intell. Labor. Systems 136 (2014), 58-80. DOI
  10. D'Urso, P., Giordani, P., , Comput. Statist. Data Analysis 50 (2006), 6, 1496-1523. MR2222055DOI
  11. D'Urso, P., Leski, J. M., , Fuzzy Sets Systems 389 (2020), 1-28. MR4090410DOI
  12. Eskandari, E., Khastan, A., A robust fuzzy clustering model for fuzzy data based on an adaptive weighted L1 norm., Iranian J. Fuzzy Systems 20 (2023), 6, 1-20. MR4685521
  13. Eskandari, E., Khastan, A., Investigating the effect of using different loss functions on the performance of the fuzzy clustering model for fuzzy data in the presence of outlier data., Fuzzy Systems Appl. 7 (2024), 1, 109-123. 
  14. Eskandari, E., Khastan, A., Tomasiello, S., Improved determination of the weights in a clustering approach based on a weighted dissimilarity measure between fuzzy data., In: IEEE International Conference on Fuzzy Systems (FUZZ-IEEE) 2022, pp. 1-6. 
  15. Feng, Q., Chen, L., Chen, C. L. P., Guo, L., , IEEE Trans. Fuzzy Systems 28 (2020), 7, 1420-1433. DOI
  16. Ferraro, M. B., Giordani, P., , Int. J. Approx. Reasoning 88 (2017), 23-38. MR3679135DOI
  17. Figueroa-Garcia, J. C., Varón-Gaviria, C. A., Barbosa-Fontecha, J. L., 10.1109/TFUZZ.2019.2956668, IEEE Trans. Fuzzy Systems 29 (2019), 3, 539-548. DOI10.1109/TFUZZ.2019.2956668
  18. Gao, Y., Wang, W., Xie, J., Pan, J., , Knowledge Based Systems 237 (2022), 107769. DOI
  19. He, K., Zhang, X., Ren, S., Sun, J., Deep residual learning for image recognition., In: IEEE Conference on Computer Vision and Pattern Recognition (CVPR) 2016, pp. 770-778. 
  20. Huang, K., Zhang, Y., Cheng, H. D., Xing, P., Zhang, B., , Neurocomputing 450 (2021), 319-335. DOI
  21. Hung, W., Yang, M., , Fuzzy Sets Systems 150 (2005), 3, 561-577. MR2119383DOI
  22. Kartli, N., Bostanci, E., Guzel, M. S., , Computing 106 (2024), 10, 3195-3227. MR4794582DOI
  23. Rand, W. M., , J. American Statist. Assoc. 66 (1971), 336, 846-850. DOI
  24. Su, L., Cao, X., , J. Appl. Remote Sensing 12 (2018), 3, 035014. DOI
  25. Wei, X., Lu, D., Cao, X., Su, L., Wang, L., Guo, H., Hou, Y., He, X., 10.1063/1.5088234, AIP Advances 9 (2019), 6, 065105. DOI10.1063/1.5088234
  26. Yang, M., Ko, C., , Fuzzy Sets Systems 84 (1996), 1, 49-60. MR1419650DOI

NotesEmbed ?

top

You must be logged in to post comments.

To embed these notes on your page include the following JavaScript code on your page where you want the notes to appear.

Only the controls for the widget will be shown in your chosen language. Notes will be shown in their authored language.

Tells the widget how many notes to show per page. You can cycle through additional notes using the next and previous controls.

    
                

                
Note: Best practice suggests putting the JavaScript code just before the closing </body> tag.