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http://dx.doi.org/10.3745/JIPS.03.0169

Wireless Mobile Sensor Networks with Cognitive Radio Based FPGA for Disaster Management  

Ananthachari, G.A. Preethi (Technology Studies, Endicott College of International Studies, Woosong University)
Publication Information
Journal of Information Processing Systems / v.17, no.6, 2021 , pp. 1097-1114 More about this Journal
Abstract
The primary objective of this work was to discover a solution for the survival of people in an emergency flood. The geographical information was obtained from remote sensing techniques. Through helpline numbers, people who are in need request support. Although, it cannot be ensured that all the people will acquire the facility. A proper link is required to communicate with people who are at risk in affected areas. Mobile sensor networks with field-programmable gate array (FPGA) self-configurable radios were deployed in damaged areas for communication. Ad-hoc networks do not have a centralized structure. All the mobile nodes deploy a temporary structure and they act as a base station. The mobile nodes are involved in searching the spectrum for channel utilization for better communication. FPGA-based techniques ensure seamless communication for the survivors. Timely help will increase the survival rate. The received signal strength is a vital factor for communication. Cognitive radio ensures channel utilization in an effective manner which results in better signal strength reception. Frequency band selection was carried out with the help of the GRA-MADM method. In this study, an analysis of signal strength for different mobile sensor nodes was performed. FPGA-based implementation showed enhanced outcomes compared to software-based algorithms.
Keywords
Cognitive Radio; Disaster Management; FPGA; GRA; Sensors; Signal Strength;
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