Cross-Cloud Continuity : A Scalable Framework for Resilient and Regulated Digital Infrastructure
DOI:
https://doi.org/10.32628/IJSRSET2358717Keywords:
Cloud Resiliency, Fault Tolerance, Cost Optimization, Cloud Design, Edge Computing IntegrationAbstract
As digital infrastructure becomes increasingly reliant on multi-cloud architectures, ensuring consistent availability, fault tolerance, and disaster recovery across distributed systems is a critical challenge. This extended study advances the discourse on cloud resiliency engineering by addressing underexplored areas such as the quantification of resilience metrics, economic modeling of redundancy strategies, and the integration of AI-driven automation for predictive fault detection. It also evaluates the operational and regulatory complexities introduced by multi-jurisdictional deployments, legacy system modernization, and emerging threats like quantum computing. Unlike traditional approaches focused solely on infrastructure-level solutions, this research presents a multi-dimensional framework that encompasses human factors, policy-aware architecture, and vendor interoperability. By synthesizing insights from real-world implementations, performance benchmarks, and evolving technologies such as edge computing and post-quantum cryptography, the study provides a comprehensive roadmap for building resilient, secure, and scalable cloud systems. The proposed framework equips cloud architects, developers, and enterprise leaders with actionable strategies to design and manage cloud environments that are both technically robust and contextually adaptable.
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