Self-Organized Wireless Sensor Network (SOWSN) for dense jungle applications
To facilitate wireless sensor networks deployment in dense jungle environments, the challenges of unreliable wireless communication links used for routing data between nodes and the gateway, and the limited battery energy available from the nodes must be overcome. In this paper, we introduce the S...
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| Main Authors: | , , , , , |
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| Format: | Article |
| Language: | English English |
| Published: |
IEEE
2023
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| Subjects: | |
| Online Access: | http://irep.iium.edu.my/107468/8/107468_Self-Organized%20Wireless%20Sensor%20Network%20%28SOWSN%29%20for%20Dense%20Jungle%20Applications%20_%20SCOPUS.pdf http://irep.iium.edu.my/107468/9/107468_Self-Organized_Wireless_Sensor_Network_SOWSN_for_Dense_Jungle_Applications.pdf http://irep.iium.edu.my/107468/ https://ieeexplore.ieee.org/document/10281366 |
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| Summary: | To facilitate wireless sensor networks deployment in dense jungle environments, the challenges
of unreliable wireless communication links used for routing data between nodes and the gateway, and the
limited battery energy available from the nodes must be overcome. In this paper, we introduce the SelfOrganized Wireless Sensor Network (SOWSN) to overcome these challenges. To develop the traits needed
for such SOWSN nodes, three types of computational intelligence mechanisms have been featured in the
design. The first feature is the introduction of Multi Criteria Decision Making (MCDM) algorithm with
simple Additive Weight (SAW) function for clustering the SOWSN nodes. The second feature is the
introduction of the fuzzy logic ANFIS-optimized Near Ground Propagation Model to predict the wireless
transmission link quality and power transfer between transmitters. The third feature is the introduction of the
(Levenberg Marquardt artificial neural network (LM-ANN) for Adaptive Dynamic Power Control to further
optimize the transmitter power levels, radio modulation, Spreading Factor configurations, and settings of the
employed SOWSN LoRaWAN nodes based on predicted wireless transmission link quality parameters. The
introduced features were extensively evaluated and analyzed using simulation and empirical measurements.
Using clustering, near-ground propagation, and adaptive transmission power control features, a robust
wireless data transmission system was built while simultaneously providing power conservation in SOWSN
operation. The payload loss can be improved using SAW clustering from 1275 bytes to 5100 bytes. The result
of power conservation can be seen from the reduction of transmission power in SOWSN nodes with the
increase of transmission time (TOA) as its side effect. With the original power transmission at 20 dBm,
original TOA time at 96.832 milliseconds for all nodes, and SNR 3 as input, transmission power was reduced
to 12.76 dBm and the TOA increased to 346.78 milliseconds for all nodes. |
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