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Issue:Clustering stock price volatility using intuitionistic fuzzy sets: Difference between revisions

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| conference      = 25<sup>th</sup> [[ICIFS]], Sofia, 9—10 September 2022
  | issue          = [[Notes on Intuitionistic Fuzzy Sets/28/3|Notes on Intuitionistic Fuzzy Sets, Volume 28 (2022), Number 3]], pages 343–352
  | issue          = [[Notes on Intuitionistic Fuzzy Sets/28/3|Notes on Intuitionistic Fuzzy Sets, Volume 28 (2022), Number 3]], pages 343–352
  | doi            = https://doi.org/10.7546/nifs.2022.28.3.343-352
  | doi            = https://doi.org/10.7546/nifs.2022.28.3.343-352
  | file            = NIFS-28-3-343-352.pdf
  | file            = NIFS-28-3-343-352.pdf
  | format          = PDF
  | format          = PDF
  | size            = 937
  | size            = 914
  | abstract        = Clustering involves gathering a collection of objects into homogeneous groups or clusters, such that objects in the same cluster are more similar when compared to objects present in other groups. Clustering algorithms that generate a tree of clusters called dendrogram which can be either divisive or agglomerative. The partitional clustering gives a single partition of objects, with a predefined K number of clusters. The most popular partition clustering approaches are: ''k''-means and fuzzy C-means (FCM). In ''k''-means clustering, data are divided into a number of clusters where data elements belong to exactly one cluster. The ''k''-means clustering works well when data elements are well separable. To overcome the problem of non-separability, FCM and IFCM clustering algorithm were proposed. Here we review the use of FCM/IFCM with reference to the problem of market volatility.
  | abstract        = Clustering involves gathering a collection of objects into homogeneous groups or clusters, such that objects in the same cluster are more similar when compared to objects present in other groups. Clustering algorithms that generate a tree of clusters called dendrogram which can be either divisive or agglomerative. The partitional clustering gives a single partition of objects, with a predefined K number of clusters. The most popular partition clustering approaches are: ''k''-means and fuzzy C-means (FCM). In ''k''-means clustering, data are divided into a number of clusters where data elements belong to exactly one cluster. The ''k''-means clustering works well when data elements are well separable. To overcome the problem of non-separability, FCM and IFCM clustering algorithm were proposed. Here we review the use of FCM/IFCM with reference to the problem of market volatility.
  | keywords        = K-Means, FCM, IFCM, Intuitionistic fuzzy sets, Volatility of Volatility.
  | keywords        = K-Means, FCM, IFCM, Intuitionistic fuzzy sets, Volatility of Volatility.

Latest revision as of 15:44, 7 September 2022

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Title of paper: Clustering stock price volatility using intuitionistic fuzzy sets
Author(s):
Georgy Urumov
School of Computer Science and Engineering, University of Westminster, 115 New Cavendish Street, London W1W 6UW
w1767944@westminster.ac.uk
Panagiotis Chountas
School of Computer Science and Engineering, University of Westminster, 115 New Cavendish Street, London W1W 6UW
p.i.chountas@westminster.ac.uk
Presented at: 25th ICIFS, Sofia, 9—10 September 2022
Published in: Notes on Intuitionistic Fuzzy Sets, Volume 28 (2022), Number 3, pages 343–352
DOI: https://doi.org/10.7546/nifs.2022.28.3.343-352
Download:  PDF (914  Kb, File info)
Abstract: Clustering involves gathering a collection of objects into homogeneous groups or clusters, such that objects in the same cluster are more similar when compared to objects present in other groups. Clustering algorithms that generate a tree of clusters called dendrogram which can be either divisive or agglomerative. The partitional clustering gives a single partition of objects, with a predefined K number of clusters. The most popular partition clustering approaches are: k-means and fuzzy C-means (FCM). In k-means clustering, data are divided into a number of clusters where data elements belong to exactly one cluster. The k-means clustering works well when data elements are well separable. To overcome the problem of non-separability, FCM and IFCM clustering algorithm were proposed. Here we review the use of FCM/IFCM with reference to the problem of market volatility.
Keywords: K-Means, FCM, IFCM, Intuitionistic fuzzy sets, Volatility of Volatility.
AMS Classification: 03E72, 68T20.
References:
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  2. Atanassov, K. T. (1999). Intuitionistic Fuzzy Sets: Past, Present and Future. In: Wagenknecht, M., & Hampel, R. (eds) 3rd Conference of the European Society for Fuzzy Logic and Technology, Zittau, Germany (10.09.2013–12.09.2003), 12–19.
  3. Atanassov, K. T. (1999). Intuitionistic Fuzzy Sets: Theory and Applications. PhysicaVerlag, New York.352
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  13. Szmidt, E., & Kacprzyk, J. (2001). Intuitionistic fuzzy sets in some medical applications. Notes on Intuitionistic Fuzzy Sets, 7(4), 58–64.
  14. Van Lung, H., & Kim, J.-M. (2009). A generalized spatial fuzzy C-means algorithm for medical image segmentation. In: FUZZ-IEEE'09: Proceedings of the 18th international conference on Fuzzy Systems, Jeju Island, Korea, 20.08.2009 – 24.08.2009, 409–414.
  15. Wang, W., & Zhang, Y. (2007). On fuzzy cluster validity indices. Fuzzy Sets and Systems, 158(19), 2095–2117.
  16. Wang, Z., Xu, Z., Liu, S., & Tang, J. (2011). A netting clustering analysis method under intuitionistic fuzzy environment. Applied Soft Computing, 11(8), 5558–5564.
  17. Wang, Z., Xu, Z., Liu, S., & Yao, Z. (2014). Direct clustering analysis based on intuitionistic fuzzy implication. Applied Soft Computing, 23, 1–8.
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