Xbee Pro S1 Based Wireless Data Acquisition System for Landslide Monitoring

Authors

Rika Ratnasari , Rahadi Wirawan , Laili Mardiana , Jakrapong Kaewkhao

DOI:

10.29303/jossed.v2i2.918

Published:

2021-10-31

Issue:

Vol. 2 No. 2 (2021): October

Keywords:

landslide, wireless data acquisition system, Xbee module

Articles

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How to Cite

Ratnasari, R., Wirawan, R. ., Mardiana, L. ., & Kaewkhao, J. . (2021). Xbee Pro S1 Based Wireless Data Acquisition System for Landslide Monitoring. Journal of Science and Science Education, 2(2), 91–96. https://doi.org/10.29303/jossed.v2i2.918

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Abstract

Landslides are disasters that occur due to the shifting of land. To detect it, we need a system that can monitor it in real-time. Therefore, in this study, a wireless data acquisition system based on the Xbee Pro S1 module was built for monitoring landslides so that the community quickly responded in the event of a disaster. Testing the range of the module is very important to ensure that data communication between the transmitter and receiver can take place. The test carried out in this study was to take the plate distance data on the extensometer by adding a load and then detected using an ultrasonic sensor. The Xbee transmitter sends data to the Xbee receiver in real-time. From the test results, the maximum range of the Xbee Pro S1 module is 150m outdoors with an average delivery time of 15s from the transmitter to the receiver

References

Artanto, D. (2012). Interaction of Arduino and LabVIEW. Jakarta: PT Elex Media Komputindo.

Hanto, D., Budiono, B., Setiono, A., & Nugraha, Y.P. (2012). Design and Build an Extensometer with Wireless Communication Using Xbee Pro S1. South Tangerang: Indonesian Institute of Sciences (LIPI).

Hussein. (2010). Weather Monitoring Telemetry System Prototype Based On Xbee Pro Iee.804.15.4. Journal of Physics Applications 6(2).

Irpan. (2011). Making a Microcontroller Based Infusion Fluid Flow System Monitored Wirelessly. Depok: University of Indonesia.

Kurniawati, R.D. (2011). Introduction of RES2DINV (Geophysical Report) Software. University of Jember.

Mizrah, E. A., Balakirev, R. V, & Shtabel, N. V. (2015). Automated control and data acquisition system for lithium-ion accumulators test bench. IOP Conference Series: Materials Science and Engineering, 94, 12005. https://doi.org/10.1088/1757-899x/94/1/012005

onchi, G., Severo, J., de Sá, W., & Galvao, R. (2015). Data Acquisition and Automation for Plasma Rotation Diagnostic in the TCABR Tokamak. Journal of Physics: Conference Series, 591, 12007. https://doi.org/10.1088/1742-6596/591/1/012007.

Shafique, M. I. Bin, Halim, M. A., Rabbi, F., & Rhaman, M. (2016). Exploring the Opportunities of a Balloon-Satellite in Bangladesh for Weather Data Collection and Vegetative Analysis. IOP Conference Series: Earth and Environmental Science, 38, 12009. https://doi.org/10.1088/1755-1315/38/1/012009

Somantri, L. (2008). Study of landslide disaster mitigation using remote sensing technology. UPI Bandung.

Sumarudin, A., Ghozali, A., Hasyim, A., & Efendi, A. (2016). Implementation monitoring temperature, humidity and mositure soil based on wireless sensor network for e-agriculture technology. IOP Conference Series: Materials Science and Engineering, 128, 12044. https://doi.org/10.1088/1757-899X/128/1/012044.

Wibawa, T.A.S., Arifin, A., & Saleh, A. (2011). Microcontroller-Based Wireless Soccer Robot Design. Surabaya: Surabaya State Electronics Polytechnic.

Wirawan R., Sudiarta, I.W., & Dian, W.K. (2016). Ultrasonic Sensor-Based Soil Displacement Detection System for Landslide Mitigation, Competitive Grant Research, Number: 134/SP2H/LT/DRPM/III/2016.

Yuliza, E., Habil, H., Munir, M. M., Irsyam, M., Abdullah, M., & Khairurrijal. (2016). Study of soil moisture sensor for landslide early warning system: Experiment in laboratory scale. Journal of Physics: Conference Series, 739, 12034. https://doi.org/10.1088/1742-6596/739/1/012034.

Author Biographies

Rika Ratnasari, Magister Pendidikan IPA Universitas Mataram Lombok Indonesia

Rahadi Wirawan, University of Mataram

Laili Mardiana, Mustansiriyah University, Baghdad

Jakrapong Kaewkhao, Nakhon Pathom Rajabhat University, Thailand

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Copyright (c) 2021 Rika Ratnasari

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