基于无线传感器网络和FRBR的nrf24l1太阳能振动传播分析系统

Q3 Decision Sciences

JOIV International Journal on Informatics Visualization Pub Date : 2023-03-03 DOI:10.30630/joiv.7.1.1592

W. Wedashwara, M. Yadnya, I Wayan Sudiarta, I Wayan Agus Arimbawa, T. Mulyana

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引用次数: 1

摘要

预防地震和滑坡等自然灾害造成的影响需要对振动传播进行分析。在户外应用中，WIFI等互联网资源并不总是可用，因此需要nrf24101等替代数据通信。该系统还需要一个便携式电源，如太阳能。本研究旨在通过实现基于模糊规则的回归(FRBR)算法，开发基于nrf24l1无线传感器网络和太阳能的振动传播分析系统。该系统由两个压电和nrf24l1振动传感器组成。该系统还使用了第三个节点，该节点配备了温度和土壤湿度传感器、空气温度和湿度以及光强度作为环境变量。评估结果显示，服务质量(QoS)结果吞吐量为99.564%，PDR为99.675%，延迟为0.0073s。模糊关联规则(FAR)提取结果为9条规则，平均支持度为0.319，振动传播置信度为1。以平均电流值为0.250A，电压为3.266V来评估太阳能的可用性。FRBR的结果基于振动的传播，其传播产生的均方误差(MSE)为0.141，平均绝对误差(MAE)为0.165。相关矩阵和FAR结果表明，只有土壤湿度对繁殖幅度和持续时间有主要影响。而其他变量可以回归土壤水分，MSE为0.232,MAE为0.287。

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Solar Powered Vibration Propagation Analysis System using nRF24l01 based WSN and FRBR

Prevention of the effects caused by natural disasters such as earthquakes and landslides requires analysis of vibration propagation. In outdoor applications, internet sources such as WIFI are not always available, so it requires alternative data communications such as nRF24l01. The system also requires a portable power source such as solar power. This research aims to develop a vibration propagation analysis system based on the nRF24l01 wireless sensor network and solar power by implementing the fuzzy rule-based regression (FRBR) algorithm. The system consists of two piezoelectric and nrf24l01 vibration sensors. The system also uses a third node equipped with temperature and soil moisture sensors, air temperature and humidity, and light intensity as environmental variables. The evaluation results show the Quality of Services (QoS) results with a throughput of 99.564%, PDR 99.675%, and a delay of 0.0073s. The Fuzzy Association Rule (FAR) extraction results yield nine rules with average support of 0.319 and confidence of 1 for vibration propagation. The availability of solar power was evaluated with an average current value of 0.250A and a voltage of 3.266V. The results of FRBR are based on the propagation of the vibration that propagated and produced a mean square error (MSE) of 0.141 and a mean absolute error (MAE) of 0.165. The correlation matrix and FAR results show that only soil moisture has a major effect on the magnitude and duration of propagation. However, other variables can regress soil moisture with MSE 0.232 and MAE 0.287.

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