No Access

1DCAE-TSSAMC: Two-Stage Multi-Dimensional Spatial Features Based Multi-View Deep Clustering for Time Series Data

Jianglong Chen

Faculty of Land Resources Engineering, Kunming University of Science and Technology, KunMing 650500, P. R. China

E-mail Address: 15342660205@163.com

Search for more papers by this author

Weiwei Song

Faculty of Land Resources Engineering, Kunming University of Science and Technology, KunMing 650500, P. R. China

E-mail Address: songweiwei1007@163.com

Corresponding author.

Search for more papers by this author

Xiaoqing Zuo

Faculty of Land Resources Engineering, Kunming University of Science and Technology, KunMing 650500, P. R. China

E-mail Address: zxq@kust.edu.cn

Search for more papers by this author

Kang Zhao

Department of Natural Resources of Yunnan Province, Kunming 650224, P. R. China

E-mail Address: kzhao@whu.edu.cn

Search for more papers by this author

Baoxuan Jin

Department of Natural Resources of Yunnan Province, Kunming 650224, P. R. China

E-mail Address: jbx@yngc.org

Search for more papers by this author

Daming Zhu

Faculty of Land Resources Engineering, Kunming University of Science and Technology, KunMing 650500, P. R. China

E-mail Address: 11301066@kust.edu.cn

Search for more papers by this author

, and

Bolan Dai

722 Research Institute of China Shipbuilding Corporation, Wuhan, Hubei, 430079, P. R. China

E-mail Address: daibolan@126.com

Search for more papers by this author

https://doi.org/10.1142/S0218488524400105Cited by:0 (Source: Crossref)

This article is part of the issue:

Special Issue on Exploring the Potential of Fuzzy-Based Systems in Statistical Learning Theory

Abstract

At present, as a research hotspot for time series data (TSD), the deep clustering analysis of TSD has huge research value and practical significance. However, there still exist the following three problems: (1) For deep clustering based on joint optimization, the inevitably mutual interference existing between deep feature representation learning progress and clustering progress leads to difficult model training especially in the initial stage, the possible feature space distortion, inaccurate and weak feature representation; (2) Existing deep clustering methods are difficult to intuitively define the similarity of time series and rely heavily on complex feature extraction networks and clustering algorithms. (3) Multidimensional time series have the characteristics of high dimensions, complex relationships between dimensions, and variable data forms, thus generating a huge feature space. It is difficult for existing methods to select discriminative features, resulting in generally low accuracy of methods. Accordingly, to address the above three problems, we proposed a novel general two-stage multi-dimensional spatial features based multi-view deep clustering method 1DCAE-TSSAMC (One-dimensional deep convolutional auto-encoder based two-stage stepwise amplification multi-clustering). We conducted verification and analysis based on real-world important multi-scenario, and compared with many other benchmarks ranging from the most classic approaches such as K-means and Hierarchical to the state-of-the-art approaches based on deep learning such as Deep Temporal Clustering (DTC) and Temporal Clustering Network (TCN). Experimental results show that the new method outperforms the other benchmarks, and provides more accurate, richer, and more reliable analysis results, more importantly, with significant improvement in accuracy and spatial linear separability.

Keywords:

References

1. T. W. Liao , Clustering of time series data—a survey, Pattern Recognition 38(11) (2005) 1857–1874. Crossref, Web of Science, Google Scholar
2. J. Kim and N. Moon , CNN-GRU-based feature extraction model of multivariate time-series data for regional clustering, Advances in Computer Science and Ubiquitous Computing: CSA-CUTE 2019, (Springer, Singapore, 2021), pp. 401–405. Crossref, Google Scholar
3. D. Malandrino, R. De Prisco, M. Ianulardo et al., An adaptive meta-heuristic for music plagiarism detection based on text similarity and clustering, Data Mining and Knowledge Discovery 36(4) (2022) 1301–1334. Crossref, Web of Science, Google Scholar
4. A. Alqahtani, M. Ali, X. Xie et al., Deep time-series clustering: A review, Electronics 10(23) (2021) 3001. Crossref, Web of Science, Google Scholar
5. S. Zhou, H. Xu, Z. Zheng et al., A comprehensive survey on deep clustering: Taxonomy, challenges, and future directions, arXiv preprint arXiv:2206.07579, 2022. Google Scholar
6. X. Li, J. Lin and L. Zhao , Time series clustering in linear time complexity, Data Mining and Knowledge Discovery 35 (2021) 2369–2388. Crossref, Web of Science, Google Scholar
7. S. Rani and G. Sikka , Recent techniques of clustering of time series data: A survey, International Journal of Computer Applications 52(15) (2012) Crossref, Google Scholar
8. B. Lafabregue, J. Weber, P. Gançarski et al., End-to-end deep representation learning for time series clustering: A comparative study, Data Mining and Knowledge Discovery 36(1) (2022) 29–81. Crossref, Web of Science, Google Scholar
9. E. Min, X. Guo, Q. Liu et al., A survey of clustering with deep learning: From the perspective of network architecture, IEEE Access 6 (2018) 39501–39514. Crossref, Web of Science, Google Scholar
10. C. Xu, H. Huang and S. Yoo , A deep neural network for multivariate time series clustering with result interpretation, 2021 International Joint Conference on Neural Networks (IJCNN), (IEEE, 2021), pp. 1–8. Crossref, Google Scholar
11. T. A. O. Wenbin, Q. Yurong, Z. Yiyang et al., Survey of deep clustering algorithm based on autoencoder, Journal of Computer Engineering & Applications 58(18) (2022) Google Scholar
12. A. Graves, A. Mohamed and G. Hinton , Speech recognition with deep recurrent neural networks, 2013 IEEE international Conference on Acoustics, Speech and Signal Processing (IEEE, 2013), pp. 6645-6649. Crossref, Google Scholar
13. Y. Bengio, A. Courville and P. Vincent , Representation learning: A review and new perspectives, IEEE Transactions on Pattern Analysis and Machine Intelligence 35(8) (2013) 1798–1828. Crossref, Web of Science, Google Scholar
14. M. Sun, Y. Wang, F. Teng et al., Clustering-based residential baseline estimation: A probabilistic perspective, IEEE Transactions on Smart Grid 10(6) (2019) 6014–6028. Crossref, Web of Science, Google Scholar
15. R. Asadi and A. Regan , Spatio-temporal clustering of traffic data with deep embedded clustering, Proceedings of the 3rd ACM SIGSPATIAL International Workshop on Prediction of Human Mobility (2019) 45–52. Crossref, Google Scholar
16. T. Thinsungnoen, K. Kerdprasop and N. Kerdprasop , Deep autoencoder networks optimized with genetic algorithms for efficient ECG clustering, International Journal of Machine Learning and Computing 8(2) (2018) 112–116. Crossref, Google Scholar
17. M. P. Wachowiak, J. J. Moggridge and R. Wachowiak-Smolikova , Deep embedded clustering for data-driven ecg exploration using continuous wavelet transforms, 2019 International Conference on Information and Digital Technologies (IDT) (IEEE, 2019), pp. 551–556. Crossref, Google Scholar
18. S. M. Mousavi, W. Zhu, W. Ellsworth et al., Unsupervised clustering of seismic signals using deep convolutional autoencoders, IEEE Geoscience and Remote Sensing Letters 16(11) (2019) 1693–1697. Crossref, Web of Science, Google Scholar
19. P. Wolf, A. Chin and B. Baker , Unsupervised data-driven automotive diagnostics with improved deep temporal clustering, 2019 IEEE 90th Vehicular Technology Conference (VTC2019-Fall) (IEEE, 2019), pp. 1–6. Crossref, Google Scholar
20. M. Ali, R. Borgo and M. W. Jones , Concurrent time-series selections using deep learning and dimension reduction, Knowledge-Based Systems 233 (2021) 107507. Crossref, Web of Science, Google Scholar
21. K. Greff, R. K. Srivastava, J. Koutník et al., LSTM: A search space odyssey, IEEE Transactions on Neural Networks and Learning Systems 28(10) (2016) 2222–2232. Crossref, Web of Science, Google Scholar
22. C. Lee and M. Van Der Schaar , Temporal phenotyping using deep predictive clustering of disease progression, International Conference on Machine Learning (PMLR, 2020), pp. 5767–5777. Google Scholar
23. D. Ienco and R. Interdonato , Deep multivariate time series embedding clustering via attentive-gated autoencoder, Advances in Knowledge Discovery and Data Mining: 24th Pacific-Asia Conference, PAKDD 2020, Singapore, May 11–14, 2020, Proceedings, Part I 24 (Springer International Publishing, 2020), pp. 318–329. Crossref, Google Scholar
24. K. Luxem, P. Mocellin, F. Fuhrmann et al., Identifying behavioral structure from deep variational embeddings of animal motion, Communications Biology 5(1) (2022) 1267. Crossref, Web of Science, Google Scholar
25. A. Abedin, F. Motlagh, Q. Shi et al., Towards deep clustering of human activities from wearables, Proceedings of the 2020 ACM International Symposium on Wearable Computers (2020) 1–6. Crossref, Google Scholar
26. Q. Ma, J. Zheng, S. Li et al., Learning representations for time series clustering, Advances in Neural Information Processing Systems (2019) 32. Google Scholar
27. N. Khan, M. Ahmed and N. Roy , Temporal clustering based thermal condition monitoring in building, Sustainable Computing: Informatics and Systems 29 (2021) 100441. Crossref, Web of Science, Google Scholar
28. S. Ryu, H. Choi, H. Lee et al., Residential load profile clustering via deep convolutional autoencoder, 2018 IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (SmartGridComm) (IEEE, 2018), pp. 1–6. Crossref, Google Scholar
29. J. Che, L. Wang, X. Bai et al., Spatial-temporal hybrid feature extraction network for few-shot automatic modulation classification, IEEE Transactions on Vehicular Technology 71(12) (2022) 13387–13392. Crossref, Web of Science, Google Scholar
30. G. Richard, B. Grossin, G. Germaine et al., Autoencoder-based time series clustering with energy applications, arXiv 2020[J], arXiv preprint arXiv:2002.03624, 2002. Google Scholar
31. T. Thinsungnoen, K. Kerdprasop and N. Kerdprasop , Deep autoencoder networks optimized with genetic algorithms for efficient ECG clustering, International Journal of Machine Learning and Computing 8(2) (2018) 112–116. Crossref, Google Scholar
32. J. de Jong, M. A. Emon, P. Wu et al., Deep learning for clustering of multivariate clinical patient trajectories with missing values, GigaScience 8(11) (2019) giz134. Crossref, Web of Science, Google Scholar
33. N. S. Madiraju, Deep temporal clustering: Fully unsupervised learning of time-domain features, Arizona State University, 2018. Google Scholar
34. Q. Ma, J. Zheng, S. Li et al., Learning representations for time series clustering, Advances in Neural Information Processing Systems 32 (2019) Google Scholar
35. L. Han, K. Zheng, L. Zhao et al., Short-term traffic prediction based on deepcluster in large-scale road networks, IEEE Transactions on Vehicular Technology 68(12) (2019) 12301–12313. Crossref, Web of Science, Google Scholar
36. X. Yang, C. Deng, K. Wei et al., Adversarial learning for robust deep clustering, Advances in Neural Information Processing Systems 33 (2020) 9098–9108. Google Scholar
37. J. Xie, R. Girshick and A. Farhadi , Unsupervised deep embedding for clustering analysis, International Conference on Machine Learning (PMLR, 2016), pp. 478–487. Google Scholar
38. X. Guo, L. Gao, X. Liu et al., Improved deep embedded clustering with local structure preservation, Ijcai 17 (2017) 1753–1759. Google Scholar
39. JI Qiang, SUN Yanfeng, HU Yongli, YIN Baocai , Review of clustering with deep learning, Journal of Beijing University of Technology 47(8) (2021) 912–924. https://doi.org/10.11936/bjutxb2021010013 Google Scholar
40. X. Yang, C. Deng, F. Zheng et al., Deep spectral clustering using dual autoencoder network, Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition (2019) 4066–4075. Crossref, Google Scholar
41. Q. Ma, J. Zheng, S. Li et al., Learning representations for time series clustering, Advances in Neural Information Processing Systems 32 (2019) Google Scholar
42. B. Yang, X. Fu, N. D. Sidiropoulos et al., Towards k-means-friendly spaces: Simultaneous deep learning and clustering, International Conference on Machine Learning (PMLR, 2017), pp. 3861–3870. Google Scholar
43. X. Guo, X. Liu, E. Zhu et al., Deep clustering with convolutional autoencoders, Neural Information Processing: 24th International Conference, ICONIP 2017, Guangzhou, China, November 14–18, 2017, Proceedings, Part II 24. (Springer International Publishing, 2017), pp. 373–382. Crossref, Google Scholar
44. J. Cai, S. Wang and W. Guo , Unsupervised embedded feature learning for deep clustering with stacked sparse auto-encoder, Expert Systems with Applications 186 (2021) 115729. Crossref, Web of Science, Google Scholar
45. G. Zhang, A. R. Singer and N. Vlahopoulos, Temporal clustering network for self-diagnosing faults from vibration measurements, arXiv preprint arXiv:2006.09505, 2020. Google Scholar
46. C. Liu, C. Liu, F. Liu et al., Clustering analysis of urban fabric detection based on mobile traffic data, Journal of Physics: Conference Series IOP Publishing 1453(1) (2020) 012158. Crossref, Google Scholar
47. J. Xie, R. Girshick and A. Farhadi , Unsupervised deep embedding for clustering analysis, International Conference on Machine Learning (PMLR, 2016), pp. 478–487. Google Scholar
48. J. Y. Park, D. J. Ryu, K. W. Nam et al., DeepDBSCAN: Deep density-based clustering for geo-tagged photos, ISPRS International Journal of Geo-Information 10(8) (2021) 548. Crossref, Web of Science, Google Scholar
49. W. Xia, X. Zhang, Q. Gao et al., Adversarial self-supervised clustering with cluster-specificity distribution, Neurocomputing 449 (2021) 38–47. Crossref, Web of Science, Google Scholar
50. M. Jogin, M. S. Madhulika, G. D. Divya et al., Feature extraction using convolution neural networks (CNN) and deep learning, 2018 3rd IEEE International Conference on Recent Trends in Electronics, Information & Communication Technology (RTEICT) (IEEE, 2018), pp. 2319–2323. Crossref, Google Scholar
51. A. Alqahtani, X. Xie, J. Deng et al., A deep convolutional auto-encoder with embedded clustering, 2018 25th IEEE International Conference on Image Processing (ICIP) (IEEE, 2018), pp. 4058–4062. Crossref, Google Scholar
52. P. Huang, Y. Huang, W. Wang et al., Deep embedding network for clustering, 2014 22nd International Conference on Pattern Recognition (IEEE, 2014), pp. 1532–1537. Crossref, Google Scholar
53. H. Zhang, T. Zhan, S. Basu et al., A framework for deep constrained clustering, Data Mining and Knowledge Discovery 35 (2021) 593–620. Crossref, Web of Science, Google Scholar
54. A. Alqahtani, M. Ali, X. Xie et al., Deep time-series clustering: A review, Electronics 10(23) (2021) 3001. Crossref, Web of Science, Google Scholar
55. M. Tschannen, O. Bachem and M. Lucic, Recent advances in autoencoder-based representation learning, arXiv preprint arXiv:1812.05069, 2018. Google Scholar
56. D. Snover, C. W. Johnson, M. J. Bianco et al., Deep clustering to identify sources of urban seismic noise in Long Beach, California, Seismological Society of America 92(2A) (2021) 1011–1022. Google Scholar
57. H. Hu, Z. Li, X. Li et al., ScCAEs: Deep clustering of single-cell RNA-seq via convolutional autoencoder embedding and soft K-means, Briefings in Bioinformatics 23(1) (2022) bbab321. Crossref, Web of Science, Google Scholar
58. N. Tavakoli, S. Siami-Namini, M. Adl Khanghah et al., An autoencoder-based deep learning approach for clustering time series data, SN Applied Sciences 2 (2020) 1–25. Crossref, Web of Science, Google Scholar
59. M. Katebi, A. Rezakhani and S. Joudaki , ADCAS: Adversarial deep clustering of Android streams, Computers and Electrical Engineering 95 (2021) 107443. Crossref, Web of Science, Google Scholar
60. N. S. Madiraju, Deep temporal clustering: Fully unsupervised learning of time-domain features, Arizona State University, 2018. Google Scholar
61. L. Chen, W. Wang, Y. Zhai et al., Deep soft K-means clustering with self-training for single-cell RNA sequence data, NAR Genomics and Bioinformatics 2(2) (2020) lqaa039. Crossref, Google Scholar
62. S. Dara and P. Tumma , Feature extraction by using deep learning: A survey, 2018 Second International Conference on Electronics, Communication and Aerospace Technology (ICECA) (IEEE, 2018), pp. 1795–1801. Crossref, Google Scholar
63. Q. Meng, D. Catchpoole, D. Skillicom et al., Relational autoencoder for feature extraction, 2017 International Joint Conference on Neural Networks (IJCNN) (IEEE, 2017), pp. 364–371. Crossref, Google Scholar
64. T. Mori , Information gain ratio as term weight: the case of summarization of ir results, Coling 2002: The 19th International Conference on Computational Linguistics, 2002. Crossref, Google Scholar
65. J. Dai and Q. Xu , Attribute selection based on information gain ratio in fuzzy rough set theory with application to tumor classification, Applied Soft Computing 13(1) (2013) 211–221. Crossref, Web of Science, Google Scholar
66. M. Mongillo , Choosing basis functions and shape parameters for radial basis function methods, SIAM Undergraduate Research Online 4(190–209) (2011) 2–6. Google Scholar
67. Z. Y. Wang, X. H. Qin, J. H. Li et al., Highly reproducible periodic electrical potential changes associated with salt tolerance in wheat plants, Environmental and Experimental Botany 160 (2019) 120–130. Crossref, Web of Science, Google Scholar
68. X. H. Qin, Z. Y. Wang, J. P. Yao et al., Using a one-dimensional convolutional neural network with a conditional generative adversarial network to classify plant electrical signals, Computers and Electronics in Agriculture 174 (2020) 105464. Crossref, Web of Science, Google Scholar
69. J. P. Yao, Z. Y. Wang, F. R. de Oliveira et al., A deep learning method for the long-term prediction of plant electrical signals under salt stress to identify salt tolerance, Computers and Electronics in Agriculture 190 (2021) 106435. Crossref, Web of Science, Google Scholar
70. Z. Wang, L. Fan, Y. Wang et al., Selection of recording pattern of plant surface electrical signal based on analysis of electrical characteristics, Transactions of the Chinese Society of Agricultural Engineering 34(5) (2018) 137–143. Google Scholar
71. https://physionet.org/cgi-bin/atm/ATM. Google Scholar
72. F. Fang and T. Shinozaki , Electrooculography-based continuous eye-writing recognition system for efficient assistive communication systems, PloS One 13(2) (2018) e0192684. Crossref, Web of Science, Google Scholar
73. G. Hamerly and C. Elkan , Learning the k in k-means, Advances in Neural Information Processing Systems 2003, 16. Google Scholar
74. S. C. Johnson , Hierarchical clustering schemes, Psychometrika 32(3) (1967) 241–254. Crossref, Web of Science, Google Scholar