FAILURE-AWARE ARTIFICIAL INTELLIGENCE: DESIGNING SYSTEMS THAT DETECT, CATEGORIZE, AND RECOVER FROM OPERATIONAL FAILURES

Ashis Ghosh

doi:10.55640/ijaair-v03i01-02

Open Access

FAILURE-AWARE ARTIFICIAL INTELLIGENCE: DESIGNING SYSTEMS THAT DETECT, CATEGORIZE, AND RECOVER FROM OPERATIONAL FAILURES

https://doi.org/10.55640/ijaair-v03i01-02

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Ashis Ghosh ¹

,

⁴ Independent Researcher San Francisco, CA, USA

Abstract

As artificial intelligence systems increasingly transition from controlled laboratory environments to real-world deployment, their ability to handle unexpected failures becomes a critical determinant of practical utility and safety. This paper introduces a comprehensive framework for failure-aware artificial intelligence, encompassing systematic mechanisms for detecting, categorizing, and responding to failures in deployed AI systems. We propose a three-tier failure taxonomy that distinguishes between input-level anomalies, processing-level errors, and output-level inconsistencies, each requiring distinct detection and recovery strategies. The proposed architecture integrates continuous self-monitoring components, confidence estimation modules, and adaptive recovery mechanisms that enable graceful degradation rather than catastrophic failure. Building upon prior work in modular robotic system architectures and patented approaches to dexterous task execution, we present design principles for building failure-resilient AI systems, including redundancy patterns, fallback hierarchies, and human-in-the-loop escalation protocols. Evaluation through simulated failure injection across multiple AI task domains demonstrates that failure-aware systems maintain operational continuity in 87% of induced failure scenarios, compared to 23% for conventional architectures. The framework provides practitioners with actionable guidelines for enhancing the robustness and reliability of deployed artificial intelligence systems across diverse application contexts.

Keywords

failure detection, fault tolerance, artificial intelligence systems, system reliability, graceful degradation, self-monitoring AI

References

📄 Amodei, D., Olah, C., Steinhardt, J., Christiano, P., Schulman, J., & Mané, D. (2016). Concrete problems in AI safety. arXiv. https://arxiv.org/abs/1606.06565

📄 Augenbraun, J. E., Ghosh, A., Hansen, S. J., Verheye, A., & MacPhee, D. (2022). Robot for performing dextrous tasks and related methods and systems (U.S. Patent No. 11,407,118 B1). U.S. Patent and Trademark Office.

📄 Croce, F., Andriushchenko, M., Sehwag, V., Debenedetti, E., Flammarion, N., Chiang, M., Mittal, P., & Hein, M. (2021). RobustBench: A standardized adversarial robustness benchmark. In J. Vanschoren & S. Yeung (Eds.), Proceedings of the Neural Information Processing Systems Track on Datasets and Benchmarks (Vol. 1). Curran Associates, Inc. https://datasets-benchmarks-proceedings.neurips.cc/paper/2021/hash/3e60e09c222f206c725385f53d7e567c-Abstract-round2.html

📄 Fort, S., Ren, J., & Lakshminarayanan, B. (2021). Exploring the limits of out-of-distribution detection. Advances in Neural Information Processing Systems, 34, 7068–7081. https://proceedings.neurips.cc/paper/2021/hash/3941c4358616274ac2436eacf67fae05-Abstract.html

📄 Gal, Y., & Ghahramani, Z. (2016). Dropout as a Bayesian approximation: Representing model uncertainty in deep learning. In M. F. Balcan & K. Q. Weinberger (Eds.), Proceedings of the 33rd International Conference on Machine Learning (Vol. 48, pp. 1050–1059). PMLR.

📄 Gartner. (2024). Predicts 2024: AI foundation models are redefining enterprise AI (Report ID: G00798893). Gartner, Inc.

📄 Ghosh, A. (in press). A modular software architecture for safe and scalable mobile manipulation systems. International Journal of Engineering Technology and Computer Science IT Innovations.

📄 Goodfellow, I. J., Shlens, J., & Szegedy, C. (2015). Explaining and harnessing adversarial examples. In Y. Bengio & Y. LeCun (Eds.), Proceedings of the 3rd International Conference on Learning Representations (ICLR 2015). https://arxiv.org/abs/1412.6572

📄 Hendrycks, D., & Gimpel, K. (2017). A baseline for detecting misclassified and out-of-distribution examples in neural networks. In Proceedings of the 5th International Conference on Learning Representations (ICLR 2017). https://arxiv.org/abs/1610.02136

📄 Lamport, L., Shostak, R., & Pease, M. (1982). The Byzantine generals problem. ACM Transactions on Programming Languages and Systems, 4(3), 382–401. https://doi.org/10.1145/357172.357176

📄 Qin, Y., Zhang, J., & Chen, X. (2021). Graceful degradation and related fields. arXiv. https://arxiv.org/abs/2106.11119

📄 RAND Corporation. (2024). The root causes of failure for artificial intelligence projects and how they can succeed: Avoiding the anti-patterns of AI (Research Report RRA2680-1). https://www.rand.org/pubs/research_reports/RRA2680-1.html

📄 Sculley, D., Holt, G., Golovin, D., Davydov, E., Phillips, T., Ebner, D., Chaudhary, V., Young, M., Crespo, J.-F., & Dennison, D. (2015). Hidden technical debt in machine learning systems. In C. Cortes, N. D. Lawrence, D. D. Lee, M. Sugiyama, & R. Garnett (Eds.), Advances in Neural Information Processing Systems (Vol. 28, pp. 2503–2511). Curran Associates, Inc.

📄 Trivedi, K. S., Dong, S., Ma, X., & Cui, J. (2024). Development of intelligent fault-tolerant control systems with machine learning, deep learning, and transfer learning algorithms: A review. Expert Systems with Applications, 237, Article 121582. https://doi.org/10.1016/j.eswa.2023.121582

📄 Yang, J., Zhou, K., Li, Y., & Liu, Z. (2024). Generalized out-of-distribution detection: A survey. International Journal of Computer Vision, 132, 4132–4178. https://doi.org/10.1007/s11263-024-02222-4

📄 Zhang, J., Fu, Q., Chen, X., Du, L., Li, Z., Wang, G., Cha, S., Liu, S., Han, J., & Liu, Y. (2023). OpenOOD v1.5: Enhanced benchmark for out-of-distribution detection. In A. Oh, T. Naumann, A. Globerson, K. Saenko, M. Hardt, & S. Levine (Eds.), Advances in Neural Information Processing Systems (Vol. 36, pp. 63202–63215). Curran Associates, Inc.

📄 Zhao, Y., Chen, W., Tan, T., Du, K., Liu, Y., & Zhou, J. (2024). OODRobustBench: A benchmark and large-scale analysis of adversarial robustness under distribution shift. In R. Salakhutdinov, Z. Kolter, K. Heller, A. Weller, N. Oliver, J. Scarlett, & F. Berkenkamp (Eds.), Proceedings of the 41st International Conference on Machine Learning (Vol. 235, pp. 61905–61931). PMLR.

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International Journal of Advanced Artificial Intelligence Research

FAILURE-AWARE ARTIFICIAL INTELLIGENCE: DESIGNING SYSTEMS THAT DETECT, CATEGORIZE, AND RECOVER FROM OPERATIONAL FAILURES

Abstract

Keywords

References

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