Scalable and Adaptive Fuzzy Grid Partitioning for Enhanced Rule Generation in Complex Decision-Making Systems

Authors

  • Abubakar Gwarzo Ɗambatta Maryam Abacha American University of Niger, Niger

DOI:

https://doi.org/10.35335/emod.v13i3.14

Keywords:

Scalable, Adaptive, Fuzzy grid partitioning, Rule generation, Complex decision-making systems

Abstract

This research focuses on addressing the challenges of rule generation in complex decision-making systems by proposing a scalable and adaptive fuzzy grid partitioning approach. Traditional rule generation methods often struggle to handle large datasets and dynamic environments, leading to decreased accuracy and computational inefficiencies. In this study, we present a novel approach that integrates scalable and adaptive techniques to enhance the accuracy, efficiency, and interpretability of rule-based frameworks. The scalable fuzzy grid partitioning algorithm efficiently partitions the attribute space, allowing for the generation of rules in decision-making systems with a large number of data points. By incorporating data parallelization and dimensionality reduction techniques, the approach mitigates computational complexity while maintaining rule generation accuracy. Furthermore, the adaptive fuzzy grid partitioning algorithm dynamically adjusts the partitioning structure based on changing conditions, capturing evolving patterns and ensuring the relevancy and reliability of the generated rules over time. The generated rules are evaluated using fuzzy rule evaluation functions, which consider the degree of membership in the corresponding fuzzy grid cells. This evaluation process ranks and selects the rules based on their firing strengths, providing an interpretable decision-making framework for complex systems. The approach enhances the interpretability of the generated rules by capturing the uncertainties and complexities inherent in decision-making processes. To validate the effectiveness of the proposed approach, we conducted experiments using a credit risk assessment case example. The results demonstrate improved accuracy and efficiency compared to traditional rule generation methods. The generated rules offer transparency and insight into the factors influencing credit risk assessments, enabling informed decision-making. However, this research has some limitations, including potential dataset dependencies, the choice of fuzzy membership functions, computational complexity, and the need for further evaluation metrics and real-world implementation considerations. Future research should focus on addressing these limitations and exploring the applicability of the proposed approach in diverse domains. In conclusion, the scalable and adaptive fuzzy grid partitioning approach presented in this research offers a promising solution to the challenges of rule generation in complex decision-making systems. By addressing scalability, adaptability, and interpretability, this approach enhances the accuracy and efficiency of rule-based frameworks, paving the way for more effective decision support systems in various domains.

References

Abraham, A. (2005). Hybrid intelligent systems: evolving intelligence in hierarchical layers. Do Smart Adaptive Systems Exist? Best Practice for Selection and Combination of Intelligent Methods, 159-179.

Abraham, A., Jain, R., Thomas, J., & Han, S. Y. (2007). D-SCIDS: Distributed soft computing intrusion detection system. Journal of Network and Computer Applications, 30(1), 81-98.

Alcalá, R., Gacto, M. J., & Herrera, F. (2011). A fast and scalable multiobjective genetic fuzzy system for linguistic fuzzy modeling in high-dimensional regression problems. IEEE Transactions on Fuzzy Systems, 19(4), 666-681.

Arabnejad, H., Pahl, C., Jamshidi, P., & Estrada, G. (2017, May). A comparison of reinforcement learning techniques for fuzzy cloud auto-scaling. In 2017 17th IEEE/ACM international symposium on cluster, cloud and grid computing (CCGRID) (pp. 64-73). IEEE.

Asghar, A. B., & Liu, X. (2017). Estimation of wind turbine power coefficient by adaptive neuro-fuzzy methodology. Neurocomputing, 238, 227-233.

Asghar, A. B., & Liu, X. (2018). Adaptive neuro-fuzzy algorithm to estimate effective wind speed and optimal rotor speed for variable-speed wind turbine. Neurocomputing, 272, 495-504.

Chen, H. L., Yang, B., Wang, G., Liu, J., Xu, X., Wang, S. J., & Liu, D. Y. (2011). A novel bankruptcy prediction model based on an adaptive fuzzy k-nearest neighbor method. Knowledge-Based Systems, 24(8), 1348-1359.

Cheu, E. Y., Ng, S. K., & Quek, C. (2010). Enhancing decision support system with neural fuzzy model and simple model visualizations. Handbook on Decision Making: Vol 1: Techniques and Applications, 85-116.

De Santis, E., Rizzi, A., & Sadeghian, A. (2017). Hierarchical genetic optimization of a fuzzy logic system for energy flows management in microgrids. Applied Soft Computing, 60, 135-149.

De Santis, E., Rizzi, A., Sadeghiany, A., & Mascioli, F. M. F. (2013, June). Genetic optimization of a fuzzy control system for energy flow management in micro-grids. In 2013 Joint IFSA World Congress and NAFIPS Annual Meeting (IFSA/NAFIPS) (pp. 418-423). IEEE.

Deo, R. C., Downs, N. J., Adamowski, J. F., & Parisi, A. V. (2019). Adaptive Neuro‐Fuzzy Inference System integrated with solar zenith angle for forecasting sub‐tropical Photosynthetically Active Radiation. Food and Energy Security, 8(1), e00151.

Dettori, S., Iannino, V., Colla, V., & Signorini, A. (2018). An adaptive Fuzzy logic-based approach to PID control of steam turbines in solar applications. Applied Energy, 227, 655-664.

Esfahanipour, A., & Aghamiri, W. (2010). Adapted neuro-fuzzy inference system on indirect approach TSK fuzzy rule base for stock market analysis. Expert Systems with Applications, 37(7), 4742-4748.

Fattahi, H. (2016). Indirect estimation of deformation modulus of an in situ rock mass: an ANFIS model based on grid partitioning, fuzzy c-means clustering and subtractive clustering. Geosciences Journal, 20(5), 681-690.

Fujii, S., Nakashima, T., & Ishibuchi, H. (2008, June). A study on constructing fuzzy systems for high-level decision making in a car racing game. In 2008 IEEE International Conference on Fuzzy Systems (IEEE World Congress on Computational Intelligence) (pp. 2299-2306). IEEE.

Gacto, M. J., Galende, M., Alcalá, R., & Herrera, F. (2014). METSK-HDe: A multiobjective evolutionary algorithm to learn accurate TSK-fuzzy systems in high-dimensional and large-scale regression problems. Information Sciences, 276, 63-79.

Gadaras, I., & Mikhailov, L. (2009). An interpretable fuzzy rule-based classification methodology for medical diagnosis. Artificial intelligence in medicine, 47(1), 25-41.

Gao, C., Ge, Q., & Jian, L. (2013). Rule extraction from fuzzy-based blast furnace SVM multiclassifier for decision-making. IEEE Transactions on Fuzzy Systems, 22(3), 586-596.

Gerek, I. H. (2014). House selling price assessment using two different adaptive neuro-fuzzy techniques. Automation in Construction, 41, 33-39.

Ghanbari, A., Abbasian-Naghneh, S., & Hadavandi, E. (2011, April). An intelligent load forecasting expert system by integration of ant colony optimization, genetic algorithms and fuzzy logic. In 2011 IEEE symposium on computational intelligence and data mining (CIDM) (pp. 246-251). IEEE.

Ghanbari, A., Kazemi, S. M., Mehmanpazir, F., & Nakhostin, M. M. (2013). A cooperative ant colony optimization-genetic algorithm approach for construction of energy demand forecasting knowledge-based expert systems. Knowledge-Based Systems, 39, 194-206.

Haider, A. A., Nadeem, A., & Akram, S. (2016, December). Regression test suite optimization using adaptive neuro fuzzy inference system. In 2016 International Conference on Frontiers of Information Technology (FIT) (pp. 52-56). IEEE.

Han, M., Sun, Y., & Fan, Y. (2008). An improved fuzzy neural network based on T–S model. Expert Systems with Applications, 34(4), 2905-2920.

He, Y., Tang, Y., Zhang, Y. Q., & Sunderraman, R. (2006). Adaptive Fuzzy Association Rule mining for effective decision support in biomedical applications. International journal of data mining and bioinformatics, 1(1), 3-18.

Hiremath, S., & Patra, S. K. (2010, July). Transmission rate prediction for cognitive radio using adaptive neural fuzzy inference system. In 2010 5th International Conference on Industrial and Information Systems (pp. 92-97). IEEE.

Ibrahim, S., Chowriappa, P., Dua, S., Acharya, U. R., Noronha, K., Bhandary, S., & Mugasa, H. (2015). Classification of diabetes maculopathy images using data-adaptive neuro-fuzzy inference classifier. Medical & biological engineering & computing, 53, 1345-1360.

Jamshidi, P., Sharifloo, A., Pahl, C., Arabnejad, H., Metzger, A., & Estrada, G. (2016, April). Fuzzy self-learning controllers for elasticity management in dynamic cloud architectures. In 2016 12th International ACM SIGSOFT Conference on Quality of Software Architectures (QoSA) (pp. 70-79). IEEE.

Jiao, L., Denoeux, T., & Pan, Q. (2015). A hybrid belief rule-based classification system based on uncertain training data and expert knowledge. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 46(12), 1711-1723.

Jin, Y. (2003). Advanced fuzzy systems design and applications (Vol. 112). Springer Science & Business Media.

Juuso, E. K. (2004). Integration of intelligent systems in development of smart adaptive systems. International journal of approximate reasoning, 35(3), 307-337.

Khan, S. S., & Quadri, S. M. K. (2017). Structure identification and IO space partitioning in a nonlinear fuzzy system for prediction of patient survival after surgery. International Journal of Intelligent Computing and Cybernetics.

Mohamed, A., Refaat, S. S., & Abu-Rub, H. (2019). A review on big data management and decision-making in smart grid. Power Electronics and Drives, 4(1), 1-13.

Moustafa, N., Creech, G., & Slay, J. (2017). Big data analytics for intrusion detection system: Statistical decision-making using finite dirichlet mixture models. Data Analytics and Decision Support for Cybersecurity: Trends, Methodologies and Applications, 127-156.

Nakashima, T., & Fujii, S. (2010). Designing high-level decision making systems based on fuzzy if–then rules for a point-to-point car racing game. Soft Computing, 14, 517-528.

Poli, J. P., & Boudet, L. (2018). A fuzzy expert system architecture for data and event stream processing. Fuzzy Sets and systems, 343, 20-34.

Rajaram, T., & Das, A. (2010). Modeling of interactions among sustainability components of an agro-ecosystem using local knowledge through cognitive mapping and fuzzy inference system. Expert Systems with Applications, 37(2), 1734-1744.

Rezaee, B., & Zarandi, M. F. (2010). Data-driven fuzzy modeling for Takagi–Sugeno–Kang fuzzy system. Information Sciences, 180(2), 241-255.

Ruben, R. B., Asokan, P., & Vinodh, S. (2017). Performance evaluation of lean sustainable systems using adaptive neuro fuzzy inference system: a case study. International Journal of Sustainable Engineering, 10(3), 158-175.

Salleh, M. N. M., Talpur, N., & Talpur, K. H. (2018). A modified neuro-fuzzy system using metaheuristic approaches for data classification. Artificial intelligence–emerging trends and applications’.(Ed. MAA Fernandez) pp, 29-45.

Sancho-Asensio, A., Navarro, J., Arrieta-Salinas, I., Armendáriz-Iñigo, J. E., Jiménez-Ruano, V., Zaballos, A., & Golobardes, E. (2014). Improving data partition schemes in Smart Grids via clustering data streams. Expert Systems with Applications, 41(13), 5832-5842.

Setnes, M., Babuska, R., Kaymak, U., & van Nauta Lemke, H. R. (1998). Similarity measures in fuzzy rule base simplification. IEEE Transactions on Systems, Man, and Cybernetics, Part B (Cybernetics), 28(3), 376-386.

Seyedhoseini, S. M., Jassbi, J., & Pilevari, N. (2010). Application of adaptive neuro fuzzy inference system in measurement of supply chain agility: Real case study of a manufacturing company. African Journal of Business Management, 4(1), 83.

Shukla, P. K., & Tripathi, S. P. (2012). A review on the interpretability-accuracy trade-off in evolutionary multi-objective fuzzy systems (EMOFS). Information, 3(3), 256-277.

Su, M. C., Liu, C. W., & Tsay, S. S. (1999). Neural-network-based fuzzy model and its application to transient stability prediction in power systems. IEEE Transactions on Systems, Man, and Cybernetics, Part C (Applications and Reviews), 29(1), 149-157.

Sun, C. T. (1994). Rule-base structure identification in an adaptive-network-based fuzzy inference system. IEEE Transactions on Fuzzy Systems, 2(1), 64-73.

Tooy, D., & Murase, H. (2007). NEURO-FUZZY APPROACH IN DETERMINING HUMAN INTEREST FOR DECISION MAKING. The International Journal of Applied Management and Technology, 186.

Tuan, T. M., Duc, N. T., & Van Hai, P. (2017). Dental diagnosis from X-ray images using fuzzy rule-based systems. International Journal of Fuzzy System Applications (IJFSA), 6(1), 1-16.

Zaman, M., & Hassan, A. (2019). Improved statistical features-based control chart patterns recognition using ANFIS with fuzzy clustering. Neural Computing and Applications, 31(10), 5935-5949.

Zhang, D., Wang, Y., & Huang, H. (2009). Rough neural network modeling based on fuzzy rough model and its application to texture classification. Neurocomputing, 72(10-12), 2433-2443.

Downloads

Published

2019-09-30

How to Cite

Ɗambatta, A. G. (2019). Scalable and Adaptive Fuzzy Grid Partitioning for Enhanced Rule Generation in Complex Decision-Making Systems. International Journal of Enterprise Modelling, 13(3), 109–118. https://doi.org/10.35335/emod.v13i3.14

Issue

Vol. 13 No. 3 (2019): Sep: Enterprise Modelling

Section

Articles

License

Copyright (c) 2019 Abubakar Gwarzo Ɗambatta

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.