Based on Deep Learning Intelligent Information Systems: Architecture, Knowledge Integration & Decision Optimization

Authors

  • Lanyi Wang Durham University, Durham, UK Author

Keywords:

deep learning, intelligent information system, knowledge integration, decision optimization, interpretability

Abstract

The exponential growth of multi-source digital data in domains such as healthcare and manufacturing has intensified the need for intelligent information systems (IIS) capable of accurate, interpretable, and resource-efficient decision-making. However, existing deep learning-based IIS often suffer from fragmented knowledge integration, limited decision optimization, and inadequate explainability, restricting their generalization and compliance in real-world environments. This study proposes a deep learning-based IIS that unifies three core components: a Knowledge Integration Module (KIM) for semantic alignment of structured and unstructured data through graph-based fusion; a Hybrid Decision-Optimization Engine (HDOE) combining reinforcement learning and constrained optimization for adaptive decision control; and an Explainable Representation Layer (ERL) providing feature-level attribution to enhance transparency and auditability. Empirical evaluations on two public datasets, industrial and medical, demonstrate significant performance gains over four baselines: accuracy = 92.1±0.4 %, F1 = 91.7±0.5 %, and latency reduction = 18.7 %. Interpretability scores improved by 0.9 points, while cross-domain accuracy degradation remained under 5 % with noise-induced accuracy loss below 2.5 %. These results confirm that the proposed IIS achieves statistically verified improvements in efficiency, interpretability, and robustness. The framework provides a reproducible and explainable foundation for deep learning-based decision systems applicable to data-intensive, compliance-sensitive domains such as healthcare, finance, and industrial optimization.

References

1. B. Al Kurdi, I. Akour, and M. ALSHURIDEH, "Leveraging Intelligent Information Systems for Enhanced Smart Project Implementation: A Strategic Framework," International Journal of Theory of Organization and Practice (IJTOP), vol. 4, no. 2, pp. 135-146, 2024.

2. J. Serey, M. Alfaro, G. Fuertes, M. Vargas, C. Duran, R. Ternero, and J. Sabattin, "Pattern recognition and deep learning technologies, enablers of industry 4," 0, and their role in engineering research. Symmetry, vol. 15, no. 2, p. 535, 2023.

3. I. D. Mienye, and T. G. Swart, "A comprehensive review of deep learning: Architectures, recent advances, and applications," Information, vol. 15, no. 12, p. 755, 2024. doi: 10.3390/info15120755

4. X. Pan, X. Li, Q. Li, Z. Hu, and J. Bao, "Evolving to multi-modal knowledge graphs for engineering design: state-of-the-art and future challenges," Journal of Engineering Design, vol. 36, no. 7-9, pp. 1156-1195, 2025. doi: 10.1080/09544828.2023.2301230

5. S. Feng, and R. Zhong, "Optimization and analysis of intelligent accounting information system based on deep learning model," Computational Intelligence and Neuroscience, vol. 2022, no. 1, p. 1284289, 2022.

6. M. E. Cruz, and D. Miguel, "Cross-Domain Transfer Learning: Enhancing Deep Neural Networks for Low-Resource Environments," ITEJ (Information Technology Engineering Journals), vol. 9, no. 2, pp. 72-79, 2024. doi: 10.24235/itej.v9i2.136

7. M. Mohamed, "Empowering deep learning based organizational decision making: A Survey," Sustain. Mach. Intell. J, vol. 3, no. 2, p. 13, 2023. doi: 10.61185/smij.2023.33105

8. D. Coscia, L. Meneghetti, N. Demo, G. Stabile, and G. Rozza, "A continuous convolutional trainable filter for modelling unstructured data," Computational Mechanics, vol. 72, no. 2, pp. 253-265, 2023. doi: 10.1007/s00466-023-02291-1

9. R. Murugadoss, P. Venkadesh, S. V. Divya, K. Sowmithra, K. Abinaya, and C. Sathya, "AI-Driven Emotion-Aware Learning with Cross-Modal Fusion," In 2025 8th International Conference on Circuit, Power & Computing Technologies (ICCPCT), August, 2025, pp. 1969-1974.

10. J. Wu, H. Wang, K. Qian, and E. Feng, "Optimizing latency-sensitive AI applications through edge-cloud collaboration," Journal of Advanced Computing Systems, vol. 3, no. 3, pp. 19-33, 2023. doi: 10.69987/jacs.2023.30303

11. R. Sun, and Y. Ren, "A multi-source heterogeneous data fusion method for intelligent systems in the Internet of Things," Intelligent Systems with Applications, vol. 23, p. 200424, 2024. doi: 10.1016/j.iswa.2024.200424

12. S. Rahmani, H. Aghalar, S. Jebreili, and A. Goli, "Optimization and computing using intelligent data-driven approaches for decision-making," In Optimization and computing using intelligent data-driven approaches for decision-making, 2024, pp. 90-176. doi: 10.1201/9781003536796-6

13. V. Hassija, V. Chamola, A. Mahapatra, A. Singal, D. Goel, K. Huang, and A. Hussain, "Interpreting black-box models: a review on explainable artificial intelligence," Cognitive Computation, vol. 16, no. 1, pp. 45-74, 2024. doi: 10.1007/s12559-023-10179-8

14. M. Nandan, S. Mitra, and D. De, "GraphXAI: a survey of graph neural networks (GNNs) for explainable AI (XAI)," Neural Computing and Applications, pp. 1-52, 2025.

15. M. Esna-Ashari, "Beyond the Black Box: A Review of Quantitative Metrics for Neural Network Interpretability and Their Practical Implications," International journal of sustainable applied science and engineering, vol. 2, no. 1, pp. 1-24, 2025.

Downloads

Published

2026-02-17

Issue

Vol. 3 (2026): 2nd International Conference on Electronics, Engineering, Computer Science and Applied Development (EESD 2025)

Section

Articles

How to Cite

Wang, L. (2026). Based on Deep Learning Intelligent Information Systems: Architecture, Knowledge Integration & Decision Optimization. Simen Owen Academic Proceedings Series, 3, 134-146. https://simonowenpub.com/index.php/SOAPS/article/view/68