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International Journal of Next-Generation Engineering and Technology

Open Access Peer Review International
Open Access

Adaptive Latency-Aware Microservice Orchestration and Anomaly-Resilient Edge–Cloud Architectures for Mixed Reality and Time-Critical Applications

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Dr. Elena Markovic 1 ,
4 Department of Computer Science, University of Amsterdam, Netherlands

Abstract

The rapid proliferation of mixed and augmented reality applications, latency-sensitive IoT systems, and time-critical cloud-native services has intensified the need for adaptive, resilient, and latency-aware microservice orchestration across heterogeneous cloud–edge environments. Emerging immersive applications such as augmented reality commerce and mixed reality surgical systems demand ultra-low latency, high availability, and robust fault tolerance, while simultaneously confronting network instability and resource heterogeneity.

This study proposes a comprehensive architectural and methodological framework for adaptive microservice orchestration and anomaly-resilient deployment across distributed cloud–edge infrastructures. Drawing exclusively upon established literature in microservices scheduling, edge deployment robustness, anomaly detection, Bayesian optimization, and mixed reality systems, the study synthesizes a unified theoretical model addressing latency-awareness, robustness, monitoring scalability, and intelligent anomaly detection.

A multi-layer adaptive orchestration framework is designed, integrating optimal cloudlet placement, robustness-oriented edge deployment, QoS-aware multi-resource management, latency-aware accelerator utilization, decentralized adaptive cloud–edge–dew models, hierarchical monitoring architectures, and machine learning-based anomaly detection. The methodology incorporates Bayesian optimization for orchestration parameter tuning, synthetic minority oversampling for imbalance mitigation, and hybrid anomaly detection pipelines using Random Forest, Support Vector Machines, and log-based failure prediction.

The proposed framework demonstrates improved theoretical latency resilience, enhanced deployment robustness, reduced service failure propagation, and improved anomaly detection reliability in heterogeneous environments. Conceptual evaluation based on industrial surveys, scheduling models, and architectural comparisons indicates improved system adaptability and fault containment compared to centralized orchestration approaches.

Conclusion: The integration of latency-aware orchestration, robustness-oriented deployment, and adaptive anomaly detection forms a foundational architecture for next-generation immersive and time-critical systems. The study contributes a theoretically grounded and practically aligned blueprint for scalable, resilient microservice ecosystems supporting mixed reality and distributed intelligent applications.

Keywords

Microservices orchestration, Edge computing, Latency-aware systems

References

📄 Agrawal, S.; Agrawal, J. Survey on anomaly detection using data mining techniques. Procedia Computer Science, 2015, 60, 708–713.
📄 Brochu, E.; Cora, V. M.; De Freitas, N. A tutorial on Bayesian optimization of expensive cost functions, with application to active user modeling and hierarchical reinforcement learning. arXiv, 2010, arXiv:1012.2599.
📄 Chen, Q.; Wang, Z.; Leng, J.; Li, C.; Zheng, W.; Guo, M. Avalon: Towards QoS awareness and improved utilization through multi-resource management in datacenters. Proceedings of the ACM International Conference on Supercomputing, 2019, 272–283.
📄 Eltanbouly, S.; Bashendy, M.; AlNaimi, N.; Chkirbene, Z.; Erbad, A. Machine learning techniques for network anomaly detection: A survey. Proceedings of the 2020 IEEE International Conference on Informatics, IoT, and Enabling Technologies, 2020, 156–162.
📄 Filip, I.-D.; Pop, F.; Serbanescu, C.; Choi, C. Microservices scheduling model over heterogeneous cloud-edge environments as support for IoT applications. IEEE Internet of Things Journal, 2018, 5(4), 2672–2681.
📄 Fronza, I.; Sillitti, A.; Succi, G.; Terho, M.; Vlasenko, J. Failure prediction based on log files using random indexing and support vector machines. Journal of Systems and Software, 2013, 86, 2–11.
📄 Gonzalez-Cuautle, D.; Hernandez-Suarez, A.; Sanchez-Perez, G.; Toscano-Medina, L. K.; Portillo-Portillo, J.; Olivares-Mercado, J.; Perez-Meana, H. M.; Sandoval-Orozco, A. L. Synthetic minority oversampling technique for optimizing classification tasks in botnet and intrusion-detection-system datasets. Applied Sciences, 2020, 10, 794.
📄 K. S. Hebbar, “MACHINE LEARNING-ASSISTED SERVICE BOUNDARY DETECTION FOR MODULARIZING LEGACY SYSTEMS,” International Journal of Applied Engineering & Technology, vol. 04,no.02, pp. 401-414, Sep. 2022, https://romanpub.com/resources/ijaet-v4-2-2022-48.pdf
📄 Jia, M.; Cao, J.; Liang, W. Optimal cloudlet placement and user to cloudlet allocation in wireless metropolitan area networks. IEEE Transactions on Cloud Computing, 2015, 5(4), 725–737.
📄 Li, B.; He, Q.; Cui, G.; Xia, X.; Chen, F.; Jin, H.; Yang, Y. READ: Robustness-oriented edge application deployment in edge computing environment. IEEE Transactions on Services Computing, 2020, 15(3), 1746–1759.
📄 Lu, L.; Wang, H.; Liu, P.; Liu, R.; Zhang, J.; Xie, Y.; Liu, S.; Huo, T.; Xie, M.; Wu, X. Applications of mixed reality technology in orthopedics surgery: A pilot study. Frontiers in Bioengineering and Biotechnology, 2022, 10.
📄 Primartha, R.; Tama, B. A. Anomaly detection using random forest: A performance revisited. Proceedings of the 2017 International Conference on Data and Software Engineering, 2017, 1–6.
📄 Rauschnabel, P. A. Augmented reality is eating the real-world! The substitution of physical products by holograms. International Journal of Information Management, 2021, 57, 102279.
📄 Stefanič, P.; Cigale, M.; Jones, A. C.; Knight, L.; Taylor, I.; Istrate, C.; Suciu, G.; Ulisses, A.; Stankovski, V.; Taherizadeh, S.; Salado, G. F.; Koulouzis, S.; Martin, P.; Zhao, Z. SWITCH workbench: A novel approach for the development and deployment of time-critical microservice-based cloud-native applications. Future Generation Computer Systems, 2019, 99, 197–212.
📄 Tefera, G.; She, K.; Deeba, F. Decentralized adaptive latency-aware cloud-edge-dew architecture for unreliable network. Proceedings of the 2019 11th International Conference on Machine Learning and Computing, 2019, 142–146.
📄 Wang, R.; Ying, S.; Li, M.; Jia, S. HSACMA: A hierarchical scalable adaptive cloud monitoring architecture. Software Quality Journal, 2020, 28(3), 1379–1410.
📄 Zhang, W.; Cui, W.; Fu, K.; Chen, Q.; Mawhirter, D. E.; Wu, B.; Li, C.; Guo, M. Laius: Towards latency awareness and improved utilization of spatial multitasking accelerators in datacenters. Proceedings of the ACM International Conference on Supercomputing, 2019, 58–68.
📄 Zhou, X.; Peng, X.; Xie, T.; Sun, J.; Ji, C.; Li, W.; Ding, D. Fault analysis and debugging of microservice systems: Industrial survey, benchmark system, and empirical study. IEEE Transactions on Software Engineering, 2018, 47(2), 243–260.

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