Abstract
Advancements in compact integrated circuit fabrication have significantly progressed, allowing for the integration of wireless transceivers, signal processing units, and sensors into a unified and compact unit. This technological breakthrough has paved the way for seamless interactions with the physical world, finding applications across various domains, including security, production management, and environmental monitoring. In this study, we delve into the intricate design aspects of a distributed sensor network, where each node operates within defined energy and communication constraints. The integration of prevailing wireless technologies, computational capabilities, and organic polymers into an innovative generation of intelligent devices represents a critical dimension of our exploration. This article meticulously examines the implementation of a wireless sensor network employing the Bluetooth Low Energy (BLE) protocol. The incorporation of organic polymers as a sensing layer amplifies energy efficiency and enables selective sensitivity in diverse monitoring applications. A notable advantage is the rapid and cost-effective production of electronics using organic polymers, underlining their substantial potential. Furthermore, we emphasize flexible organic electronics, underpinned by the semiconducting and flexible properties inherent in organic materials, constituting a fundamental element of our technological paradigm. Key prerequisites for achieving optimal operational device performance are thoroughly discussed, encompassing achievements and technical challenges in the design and fabrication of next-generation devices, with a keen focus on product optimization.
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