Hybrid Computational Intelligence Models for Robust Pattern Recognition and Data Analysis

Authors

  • J Jeysudha SRM INSTITUTE OF SCIENCE AND TECHNOLOGY
  • K. Deiwakumari
  • C.A. Arun Vel Tech Rangarajan Dr. Sagunthala R&D Institute of Science and Technology
  • R. Pushpavalli Paavai Engineering College
  • Ponmurugan Panneer Selvam Meenakshi Academy of Higher Education & Research (Deemed to be University),
  • S.D. Govardhan Dhanalakshmi Srinivasan College of Engineering & Technology

DOI:

https://doi.org/10.22399/ijcesen.624

Keywords:

Computational Efficiency, Pattern Recognition, Data Analysis, Convolutional Neural Networks, Genetic Algorithm (GA)

Abstract

In the era of big data, robust pattern recognition and accurate data analysis have become critical in various fields, including healthcare, finance, and industrial automation. This study presents a novel hybrid computational intelligence model that integrates deep learning techniques and evolutionary algorithms to enhance the precision and resilience of pattern recognition tasks. Our proposed model combines Convolutional Neural Networks (CNN) for high-dimensional feature extraction with a Genetic Algorithm (GA) for feature optimization and selection, providing a more efficient approach to processing complex datasets. The hybrid model achieved an accuracy of 98.7% on the MNIST dataset and outperformed conventional methods in terms of recall (95.5%) and precision (97.2%) on large-scale image classification tasks. Additionally, it demonstrated substantial improvements in computation time, reducing processing duration by 35% over traditional deep learning approaches.

Experimental results on diverse datasets, including time-series and unstructured data, confirmed the model's versatility and adaptability, achieving F1-scores of 0.92 in healthcare data analysis and 0.89 in financial anomaly detection. By incorporating a Particle Swarm Optimization (PSO) algorithm, the model further optimized hyperparameters, leading to a 25% reduction in memory consumption without compromising model performance. This approach not only enhances computational efficiency but also enables the model to perform reliably in resource-constrained environments. Our results suggest that hybrid computational intelligence models offer a promising solution for robust, scalable pattern recognition and data analysis, addressing the evolving demands of real-world applications.

References

Negoita, M. G., Neagu, D., & Palade, V. (2005). Computational intelligence: engineering of hybrid systems (Vol. 174). Springer Science & Business Media.

Zhang, J., Williams, S. O., & Wang, H. (2018). Intelligent computing system based on pattern recognition and data mining algorithms. Sustainable Computing: Informatics and Systems, 20;192-202.

Agbehadji, I. E., Awuzie, B. O., Ngowi, A. B., & Millham, R. C. (2020). Review of big data analytics, artificial intelligence and nature-inspired computing models towards accurate detection of COVID-19 pandemic cases and contact tracing. International journal of environmental research and public health, 17(15);5330. DOI: 10.3390/ijerph17155330

Anifowose, F., & Abdulraheem, A. (2011). Fuzzy logic-driven and SVM-driven hybrid computational intelligence models applied to oil and gas reservoir characterization. Journal of Natural Gas Science and Engineering, 3(3);505-517. https://doi.org/10.1016/j.jngse.2011.05.002

Kalantari, A., Kamsin, A., Shamshirband, S., Gani, A., Alinejad-Rokny, H., & Chronopoulos, A. T. (2018). Computational intelligence approaches for classification of medical data: State-of-the-art, future challenges and research directions. Neurocomputing, 276;2-22. https://doi.org/10.1016/j.neucom.2017.01.126

Abiodun, O. I., Jantan, A., Omolara, A. E., Dada, K. V., Umar, A. M., Linus, O. U., ... & Kiru, M. U. (2019). Comprehensive review of artificial neural network applications to pattern recognition. IEEE access, 7;158820-158846.

Sakshi, T. M., Tyagi, P., & Jain, V. (2024). Emerging trends in hybrid information systems modeling in artificial intelligence. Hybrid Information Systems: Non-Linear Optimization Strategies with Artificial Intelligence, 115. https://doi.org/10.1515/9783111331133-007

Dimitropoulos, X., & Riley, G. (2006, May). Modeling autonomous-system relationships. In 20th Workshop on Principles of Advanced and Distributed Simulation (PADS'06) (pp. 143-149). IEEE.

Saleem, M., Khadim, A., Fatima, M., Khan, M. A., Nair, H. K., & Asif, M. (2022, October). ASSMA-SLM: Autonomous System for Smart Motor-Vehicles integrating Artificial and Soft Learning Mechanisms. In 2022 International Conference on Cyber Resilience (ICCR) (pp. 1-6). IEEE.

Conway, L., Volz, R., & Walker, M. (1987, March). Tele-autonomous systems: Methods and architectures for intermingling autonomous and telerobotic technology. In Proceedings. 1987 IEEE International Conference on Robotics and Automation 4;1121-1130.

Jo, K., Kim, J., Kim, D., Jang, C., & Sunwoo, M. (2014). Development of autonomous car—Part I: Distributed system architecture and development process. IEEE Transactions on Industrial Electronics, 61(12), 7131-7140. doi: 10.1109/TIE.2014.2321342.

Bakambu, J. N., & Polotski, V. (2007). Autonomous system for navigation and surveying in underground mines. Journal of Field Robotics, 24(10), 829-847. https://doi.org/10.1002/rob.20213

Jo, K., Kim, J., Kim, D., Jang, C., & Sunwoo, M. (2015). Development of autonomous car—Part II: A case study on the implementation of an autonomous driving system based on distributed architecture. IEEE Transactions on Industrial Electronics, 62(8), 5119-5132. doi: 10.1109/TIE.2015.2410258

Hadi, G. S., Varianto, R., Trilaksono, B. R., & Budiyono, A. (2014). Autonomous UAV system development for payload dropping mission. Journal of Instrumentation, Automation and Systems, 1(2), 72-77.

Dimitropoulos, X., Krioukov, D., & Riley, G. (2006). Revealing the autonomous system taxonomy: The machine learning approach. arXiv preprint cs/0604015.

Chedid, R., & Saliba, Y. (1996). Optimization and control of autonomous renewable energy systems. International journal of energy research, 20(7), 609-624.

Zhu, X., Chikangaise, P., Shi, W., Chen, W. H., & Yuan, S. (2018). Review of intelligent sprinkler irrigation technologies for remote autonomous system. International Journal of Agricultural & Biological Engineering, 11(1)23-30. DOI:10.25165/IJABE.V11I1.3557

Maheshwari, R. U., Jayasutha, D., Senthilraja, R., & Thanappan, S. (2024). Development of Digital Twin Technology in Hydraulics Based on Simulating and Enhancing System Performance. Journal of Cybersecurity & Information Management, 13(2);50-65. DOI:10.54216/JCIM.130204

Paulchamy, B., Uma Maheshwari, R., Sudarvizhi AP, D., Anandkumar AP, R., & Ravi, G. (2023). Optimized Feature Selection Techniques for Classifying Electrocorticography Signals. Brain‐Computer Interface: Using Deep Learning Applications, 255-278. https://doi.org/10.1002/9781119857655.ch11

Paulchamy, B., Chidambaram, S., Jaya, J., & Maheshwari, R. U. (2021). Diagnosis of Retinal Disease Using Retinal Blood Vessel Extraction. In International Conference on Mobile Computing and Sustainable Informatics: ICMCSI 2020 (pp. 343-359). Springer International Publishing.

Maheshwari, U. Silingam, K. (2020). Multimodal Image Fusion in Biometric Authentication. Fusion: Practice and Applications, 79-91. DOI: https://doi.org/10.54216/FPA.010203

R.Uma Maheshwari (2021). ENCRYPTION AND DECRYPTION USING IMAGE PROCESSING TECHNIQUES. International Journal of Engineering Applied Sciences and Technology, 5(12);219-222 DOI:10.33564/IJEAST.2021.v05i12.037

N.V., R.K., M., A., E., B., J., S.J.P., A., K. and S., P. (2022), "Detection and monitoring of the asymptotic COVID-19 patients using IoT devices and sensors", International Journal of Pervasive Computing and Communications, 18(4);407-418. https://doi.org/10.1108/IJPCC-08-2020-0107

Subramani, P., K, S., B, K.R. et al. (2023). Prediction of muscular paralysis disease based on hybrid feature extraction with machine learning technique for COVID-19 and post-COVID-19 patients. Pers Ubiquit Comput 27;831–844. https://doi.org/10.1007/s00779-021-01531-6

Subramani, P.; Rajendran, G.B.; Sengupta, J.; Pérez de Prado, R.; Divakarachari, P.B. (2020). A Block Bi-Diagonalization-Based Pre-Coding for Indoor Multiple-Input-Multiple-Output-Visible Light Communication System. Energies 13; 3466. https://doi.org/10.3390/en13133466

Shivappriya, S.N.; Karthikeyan, S.; Prabu, S.; Pérez de Prado, R.; Parameshachari, B.D. (2020). A Modified ABC-SQP-Based Combined Approach for the Optimization of a Parallel Hybrid Electric Vehicle. Energies 13; 4529. https://doi.org/10.3390/en13174529

Maheshwari, R. U., & Paulchamy, B. (2024). Securing online integrity: a hybrid approach to deepfake detection and removal using Explainable AI and Adversarial Robustness Training. Automatika, 65(4); 1517–1532. https://doi.org/10.1080/00051144.2024.2400640

Maheshwari, R.U., Kumarganesh, S., K V M, S. et al.(2024) Advanced Plasmonic Resonance-enhanced Biosensor for Comprehensive Real-time Detection and Analysis of Deepfake Content. Plasmonics. https://doi.org/10.1007/s11468-024-02407-0

Brunton, S. L., & Kutz, J. N. (2024). Promising directions of machine learning for partial differential equations. Nature Computational Science, 4(7), 483-494. https://doi.org/10.1038/s43588-024-00643-2

Kaveh, A. (2024). Applications of Artificial neural networks and machine learning in Civil Engineering. Studies in computational intelligence, 1168, 472.

Priti Parag Gaikwad, & Mithra Venkatesan. (2024). KWHO-CNN: A Hybrid Metaheuristic Algorithm Based Optimzed Attention-Driven CNN for Automatic Clinical Depression Recognition . International Journal of Computational and Experimental Science and Engineering, 10(3)491-506. https://doi.org/10.22399/ijcesen.359

Radhi, M., & Tahseen, I. (2024). An Enhancement for Wireless Body Area Network Using Adaptive Algorithms. International Journal of Computational and Experimental Science and Engineering, 10(3)388-396. https://doi.org/10.22399/ijcesen.409

Agnihotri, A., & Kohli, N. (2024). A novel lightweight deep learning model based on SqueezeNet architecture for viral lung disease classification in X-ray and CT images. International Journal of Computational and Experimental Science and Engineering, 10(4)592-613. https://doi.org/10.22399/ijcesen.425

PATHAPATI, S., N. J. NALINI, & Mahesh GADIRAJU. (2024). Comparative Evaluation of EEG signals for Mild Cognitive Impairment using Scalograms and Spectrograms with Deep Learning Models. International Journal of Computational and Experimental Science and Engineering, 10(4)859-866. https://doi.org/10.22399/ijcesen.534

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Published

2024-11-17

How to Cite

J Jeysudha, K. Deiwakumari, C.A. Arun, R. Pushpavalli, Ponmurugan Panneer Selvam, & S.D. Govardhan. (2024). Hybrid Computational Intelligence Models for Robust Pattern Recognition and Data Analysis . International Journal of Computational and Experimental Science and Engineering, 10(4). https://doi.org/10.22399/ijcesen.624

Issue

Vol. 10 No. 4 (2024): IJCESEN

Section

Research Article

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