Volume 25 , Issue 2 , PP: 303-312, 2025 | Cite this article as | XML | Html | PDF | Full Length Article
Vishwanadham Mandala 1 * , Rajiv Avacharmal 2 , Pradeep Chintale 3 , Rajesh Kumar Malviya 4 , Manoj Kumar Vandanapu 5 , Venkata Nagesh Boddapati 6
Doi: https://doi.org/10.54216/IJNS.250226
As a generalization of fuzzy set (FS) and intuitionistic FS (IFS), neutrosophic sets (NS) were proposed to signify imprecise, uncertain, inconsistent and imperfect data present in real-time. Moreover, the interval NS (INSs) were developed just to find out the problems with an array of statistics in the actual unit interval. Then, there are least consistent processes for INSs, along with the decision-making process and INS aggregation operator. The vital operations are presented on n-valued interval NSs like intersection, union, multiplication, addition, scalar division, scalar multiplication, false-favorite and truth favorite. Bankruptcy prediction was a major concern in the areas of finance and management science that appealed to the attention of practitioners and researchers. With the great progress of up-to-date information technology, it has been developed to utilize machine learning (ML) or deep learning (DL) techniques to perform the prediction, from the primary analysis of financial statements. If ML methods have adequate interpretability, they might be employed as effectual analytical methods in bankruptcy calculation. This manuscript presents a Bankruptcy Prediction using Cutting-Edge N-Valued Interval Neutrosophic Sets (BP-CENVINS) mechanism. The projected BP-CENVINS method is a complicated approach to bankruptcy forecast that affects radical data preprocessing, classification, and hyper parameter optimization approaches. Initially, the Z-score normalization regularizes the fiscal details to increase the comparability and stability throughout the information. Next, it employs the CENVINS for the classification, skillfully detecting the subtle communication amongst variables to differentiate between creditworthy and bankrupt organizations. Finally, the Grasshopper Optimization Algorithm (GOA) is applied for parameter tuning to improve the predictive outcomes of the CENVINS classifiers, systematically purifying design parameters to achieve finest efficiency. An extensive experiments is made to illustrate the betterment of the BP-CENVINS technique. The simulation outcomes of the BP-CENVINS method have exhibited better performances than other existing methodologies.
Bankruptcy Prediction , Interval Neutrosophic Sets , N-Valued Neutrosophic Sets , Grasshopper Optimization Algorithm , Fuzzy Set
[1] Al-Hamido, R.K., Salha, L. and Gharibah, T., 2020. Pre Separation Axioms In Neutrosophic Crisp Topological Spaces. International Journal of Neutrosophic Science, 8(2), pp.72-79.
[2] Salama, A.A., Henawy, M.B. and Alhabib, R., 2020. Online Analytical Processing Operations via Neutrosophic Systems. International Journal of Neutrosophic Science, 8(2), pp.87-109.
[3] Saha, A. and Paul, A., 2019. Generalized Weighted Exponential Similarity Measures of Single Valued Neutrosophic Sets. Int. J. Neutrosophic Sci, pp.57-66.
[4] Al-Hamido, R.K., Salha, L. and Gharibah, T., 2020. Neutrosophic crisp semi separation axioms in neutrosophic crisp topological spaces. International Journal of Neutrosophic Science, 6(1), pp.32-40.
[5] Abobala, M., 2020. Classical homomorphisms between refined neutrosophic rings and neutrosophic rings. International Journal of Neutrosophic Science, 5, pp.72-75.
[6] Ainan, U.H., Por, L.Y., Chen, Y.L., Yang, J. and Ku, C.S., 2024. Advancing bankruptcy forecasting with hybrid machine learning techniques: Insights from an unbalanced Polish dataset. IEEE Access.
[7] Paraschiv, F., Schmid, M. and Wahlstrøm, R.R., 2023. Bankruptcy prediction of privately held SMEs using feature selection methods. Available at SSRN 3911490.
[8] Gholampoor, H. and Asadi, M., 2024. Risk Analysis of Bankruptcy in the US Healthcare Industries Based on Financial Ratios: A Machine Learning Analysis. Journal of Theoretical and Applied Electronic Commerce Research, 19(2), pp.1303-1320.
[9] Khemka, D., Kaippada, R., Nikhil, P.S. and Suseela, S., 2023, November. Machine Learning based efficient Bankruptcy Prediction Model. In 2023 International Conference on Research Methodologies in Knowledge Management, Artificial Intelligence and Telecommunication Engineering (RMKMATE) (pp. 1-10). IEEE.
[10] Olatunji, S.O., Musleh, D., Rahman, A.U., Salih, I.A., Salem, A.M., Dash, S., Fares, M.O., Bokir, A.S., Al-Qahtani, O., Mallik, S. and Shah, M.A., 2024. Ensemble Machine Learning Approach to Bankruptcy Prediction.
[11] Khashei, M., Etemadi, S. and Bakhtiarvand, N., 2024. A New Discrete Learning-Based Logistic Regression Classifier for Bankruptcy Prediction. Wireless Personal Communications, 134(2), pp.1075-1092.
[12] Liashenko, O., Kravets, T. and Kostovetskyi, Y., 2023. Machine learning and data balancing methods for bankruptcy prediction. Ekonomika, 102(2), pp.28-46.
[13] Smiti, S., Soui, M. and Ghedira, K., 2024. Tri-XGBoost model improved by BLSmote-ENN: an interpretable semi-supervised approach for addressing bankruptcy prediction. Knowledge and Information Systems, pp.1-38.
[14] Enkhtuya, T. and Kang, D.K., 2023. Bankruptcy Prediction with Explainable Artificial Intelligence for Early-Stage Business Models. International Journal of Internet, Broadcasting and Communication, 15(3), pp.58-65.
[15] Singla, M., Gill, K.S., Kumar, M., Rawat, R. and Aluvala, S., 2024, April. Incorporating the CatBoost Classification Method in Machine Learning Applications for Smote Analysis and Bankruptcy Data Equalisation. In 2024 International Conference on E-mobility, Power Control and Smart Systems (ICEMPS) (pp. 1-5). IEEE.
[16] Adisa, J.A., Ojo, S., Owolawi, P.A., Pretorius, A. and Ojo, S.O., 2023. Application of an improved optimization using learning strategies and long short term-memory for bankruptcy prediction. IAENG International Journal of Computer Science, 50(2), pp.512-524.
[17] Al-Faiz, M.Z., Ibrahim, A.A. and Hadi, S.M., 2018. The effect of Z-Score standardization (normalization) on binary input due the speed of learning in back-propagation neural network. Iraqi Journal of Information and Communication Technology, 1(3), pp.42-48.
[18] Broumi, S., Deli, I. and Smarandache, F., 2015. N-valued interval neutrosophic sets and their application in medical diagnosis. Critical Review, Center for Mathematics of Uncertainty, Creighton University, Omaha, NE, USA, 10, pp.45-69.
[19] Bakro, M., Kumar, R.R., Husain, M., Ashraf, Z., Ali, A., Yaqoob, S.I., Ahmed, M.N. and Parveen, N., 2024. Building a Cloud-IDS by Hybrid Bio-Inspired Feature Selection Algorithms along with Random Forest Model. IEEE Access.
[20] https://archive.ics.uci.edu/dataset/281/qualitative+bankruptcy
[21] Uthayakumar, J., Vengattaraman, T. and Dhavachelvan, P., 2020. Swarm intelligence based classification rule induction (CRI) framework for qualitative and quantitative approach: An application of bankruptcy prediction and credit risk analysis. Journal of King Saud University-Computer and Information Sciences, 32(6), pp.647-657.