HAMMING DISTANCE OF GENERALISED L-R INTUITIONISTIC FUZZY NUMBER AND ITS APPLICATION

Authors

  • MUHAMMAD ASYRAN SHAFIE Universiti Teknologi MARA
  • Nor Hanimah Kamis
  • Daud Mohamad
  • Seripah a

DOI:

https://doi.org/10.24191/mjoc.v10i2.4602

Keywords:

Hamming Distance, Intuitionistic Fuzzy Number, L-R Type, Water Pollution

Abstract

This paper proposes a distance measure for generalised L-R intuitionistic fuzzy number (GLRIFN) which is Hamming distance, aiming to enhance the theoretical and practical tools available for decision-making under uncertainty. The properties of the Hamming distance of generalised L-R intuitionistic fuzzy number are also discussed in this study. GLRIFN extends traditional L-R intuitionistic fuzzy number by incorporating confidence level for both membership and non-membership functions, making them more reliable in the evaluation process. To demonstrate the practical utility of the proposed measure, it is applied within the Generalised L-R Intuitionistic Fuzzy Technique for Order of Preference by Similarity to Ideal Solution (GLRIF-TOPSIS), a multi-criteria decision-making (MCDM) method. A real-world case study on river water pollution classification is conducted, wherein the proposed model effectively evaluates the pollution levels of different rivers by capturing the nuances of imprecise, vague, and conflicting environmental data. The results show that the River  is the cleanest river, while the River  is the most polluted river. The integration of the Hamming distance with GLRIF-TOPSIS offers a structured and adaptable decision-making framework, capable of addressing complex multi-criteria problems across domains characterised by high levels of ambiguity. This contribution not only enriches the existing body of fuzzy set theory but also opens avenues for further applications in environmental assessment and other areas that require robust fuzzy modeling.

References

Aguilar-Peña, C., Roldán-López de Hierro, A.-F., Roldán-López de Hierro, C., & Martínez-Moreno, J. (2016). A family of fuzzy distance measures of fuzzy numbers. Soft Computing, 20, 237-250. https://doi.org/10.1007/s00500-014-1497-0

Aikhuele, D. O. (2021). Intuitionistic fuzzy hamming distance model for failure detection in a slewing gear system. International Journal of System Assurance Engineering and Management, 12(5), 884-894. https://doi.org/10.1007/s13198-021-01132-9

Ameen, A. O., Alarape, M. A., & Adewole, K. S. (2019). STUDENTS’ACADEMIC PERFORMANCE AND DROPOUT PREDICTION. Malaysian Journal of Computing, 4(2), 278-303.

Ardil, C. (2023). Aircraft Supplier Selection using Multiple Criteria Group Decision Making Process with Proximity Measure Method for Determinate Fuzzy Set Ranking Analysis. International Journal of Industrial and Systems Engineering, 17(3), 127-135.

Atanassov, K. T. (1986). Intuitionistic fuzzy sets. Fuzzy Sets and Systems, 20(1), 87-96.

Deli, İ., & Keleş, M. A. (2021). Distance measures on trapezoidal fuzzy multi-numbers and application to multi-criteria decision-making problems. Soft Computing, 25, 5979-5992. https://doi.org/10.1007/s00500-021-05588-6

Guha, D., & Chakraborty, D. (2010). A theoretical development of distance measure for intuitionistic fuzzy numbers. International Journal of Mathematics and Mathematical Sciences, 2010.

Izadikhah, M. (2009). Using the Hamming distance to extend TOPSIS in a fuzzy environment. Journal of Computational and Applied Mathematics, 231(1), 200-207. https://doi.org/10.1016/j.cam.2009.02.102

Keikha, A., & Sabeghi, N. (2024). Optimized distance measures on hesitant fuzzy numbers: An application. Journal of Intelligent & Fuzzy Systems(Preprint), 1-13. https://doi.org/10.3233/JIFS-234619

Khan, Z., Hussain, F., Rahim, T., Jan, R., & Boulaaras, S. (2024). Distance measure and its application to decision making, medical diagnosis, and pattern recognition problems under complex picture fuzzy sets. The European Physical Journal Plus, 139(3), 243. https://doi.org/10.1140/epjp/s13360-024-04996-5

Klir, G. (2006). Uncertainty and information. John Wiley & Sons, Inc.

Klir, G., & Yuan, B. (1995). Fuzzy sets and fuzzy logic (Vol. Vol. 4). Prentice hall New Jersey.

Kumar, T., & Sharma, M. (2023). Particle-Based Swarm Fuzzy Optimization Approach in Vague Measurement of the Distance in Transportation Problems. International Conference on Soft Computing: Theories and Applications,

Naranjo, R., Santos, M., & Garmendia, L. (2021). A convolution-based distance measure for fuzzy singletons and its application in a pattern recognition problem. Integrated Computer-Aided Engineering, 28(1), 51-63. https://doi.org/10.3233/ICA-200629

Norouzi, M., Fleet, D. J., & Salakhutdinov, R. R. (2012). Hamming distance metric learning. Advances in neural information processing systems, 25.

Sahu, R., Dash, S. R., & Das, S. (2021). Career selection of students using hybridized distance measure based on picture fuzzy set and rough set theory. Decision Making: Applications in Management and Engineering, 4(1), 104-126. https://doi.org/10.31181/dmame2104104s

Shafie, M. A., Mohamad, D., & Awang Kechil, S. (2023). A Multi-Criteria Generalised L-R Intuitionistic Fuzzy TOPSIS with CRITIC for River Water Pollution Classification. Malaysian Journal of Fundamental and Applied Sciences, 19(6), 1152-1175. https://doi.org/10.11113/mjfas.v19n6.3105

Tarmudi, Z., Nahar Ahmad, S., Mohammad, S. A., Ghazali, A. F., Abd Rahman, M., & Triana, Y. S. (2024). VIKOR method with Z-number approach for portfolio selection decision. Malaysian Journal of Computing (MJoC), 9(1), 1759-1767.

Wan, S.-p., Lin, L.-L., & Dong, J.-y. (2017). MAGDM based on triangular Atanassov’s intuitionistic fuzzy information aggregation. Neural Computing and Applications, 28, 2687-2702. https://doi.org/10.1007/s00521-016-2196-9

Wang, R., Li, W., Zhang, T., & Han, Q. (2020). New distance measures for dual hesitant fuzzy sets and their application to multiple attribute decision making. Symmetry, 12(2), 191. https://doi.org/10.3390/sym12020191

Yazid, N. A., Sabtu, N. I., Azmiral, N. U. S., & Mahad, N. F. (2023). The application of critic-topsis method in solving the material handling equipment selection problem. Malaysian Journal of Computing (MJoC), 8(1), 1311-1330.

Zhang, L., Zhang, Y., Tang, J., Lu, K., & Tian, Q. (2013). Binary code ranking with weighted hamming distance. Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition.

Zhi, W., Feng, D., Tsai, W.-P., Sterle, G., Harpold, A., Shen, C., & Li, L. (2021). From hydrometeorology to river water quality: can a deep learning model predict dissolved oxygen at the continental scale? Environmental science & technology, 55(4), 2357-2368.

Zhu, S., Liu, Z., Letchmunan, S., Ulutagay, G., & Ullah, K. (2024). Novel distance measures on complex picture fuzzy environment: applications in pattern recognition, medical diagnosis and clustering. Journal of Applied Mathematics and Computing, 1-33. https://doi.org/10.1007/s12190-024-02293-z

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Published

2025-10-23

How to Cite

SHAFIE, M. A., Kamis, N. H. ., Mohamad, D., & a, S. . (2025). HAMMING DISTANCE OF GENERALISED L-R INTUITIONISTIC FUZZY NUMBER AND ITS APPLICATION. Malaysian Journal of Computing, 10(2), 2234–2247. https://doi.org/10.24191/mjoc.v10i2.4602

Issue

Vol. 10 No. 2 (2025): MJoC Volume 10(2) 2025

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Articles

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