Architectural Paradigms, Protocol Dynamics, And Security Implications In Wireless Sensor Networks: An Integrative And Critical Research Synthesis

Dr. Alejandro Moreno

doi:10.55640/

Open Access

Architectural Paradigms, Protocol Dynamics, And Security Implications In Wireless Sensor Networks: An Integrative And Critical Research Synthesis

https://doi.org/10.55640/

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Dr. Alejandro Moreno ¹ ,

⁴ Department of Computer Engineering, Universidad Nacional de La Plata, Argentina

Abstract

Wireless Sensor Networks (WSNs) have emerged as a foundational technology enabling pervasive sensing, monitoring, and intelligent decision-making across a wide range of application domains, including environmental monitoring, industrial automation, smart cities, healthcare, and the Internet of Things (IoT). Over more than two decades of research, WSNs have evolved from simple, homogeneous collections of sensor nodes into complex, multi-tiered, heterogeneous, and service-oriented systems. This evolution has been driven by growing application demands, advances in hardware miniaturization, and the need for scalability, reliability, energy efficiency, and security. Despite extensive literature, the field remains fragmented across architectural models, protocol stacks, synchronization mechanisms, clustering strategies, and security frameworks, often examined in isolation rather than as interdependent design dimensions. This research article presents an integrative and critical synthesis of architectural paradigms, protocol behaviors, and security challenges in WSNs, grounded strictly in established scholarly references. The study adopts a qualitative analytical methodology, systematically examining canonical surveys, architectural studies, protocol analyses, clustering frameworks, synchronization techniques, and security reviews. The results reveal that architectural choices fundamentally shape protocol performance, energy consumption, data aggregation efficiency, and security exposure. Furthermore, emerging multi-tier and clustered architectures offer scalability and energy benefits but introduce new coordination and trust challenges. The discussion highlights unresolved tensions between centralization and distribution, efficiency and robustness, and openness and security. By deeply elaborating theoretical implications, trade-offs, and limitations, this article contributes a cohesive conceptual framework that unifies architectural, protocol, and security perspectives in WSN research. The findings aim to support researchers and system designers in developing more resilient, scalable, and secure WSNs for future intelligent environments.

Keywords

Wireless Sensor Networks, Network Architecture, Clustering Protocols

References

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