Real-Time Telemetry Data Monitoring System on Soil Movement of Railway Tracks

  • Railway Electrical Engineering Indonesian Railway Polytechnic
  • Electrical Engineering, Sultan Agung Islamic University
  • Railway Electrical Engineering Indonesian Railway Polytechnic
https://doi.org/10.25139/inform.v6i1.3339
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Keywords: Monitoring, Telemetry, Real-Time, Land Shift

Abstract

A telemetry data monitoring system is needed to monitor land shifting. This system consists of an ATMega328 microcontroller, a Linear Variable Differential Transformer (LVDT) and a rheostat, an accelerometer sensor, a rain gauge tipping bucket, and the HC-12 radio telemetry module. Normally, the LVDT reads the land shift in the 0-20 mm range, the Rheostat is capable of shifting up to 66 mm, the accelerometer sensor reads less than 20 deg of data, and the rain gauge tipping bucket sensor creates the amount of rainfall below 50 mm/hour which is then sending real-time data regularly for 24 hours. The buzzer installed in the field will sound if the LVDT reads land shift more than 30 mm, Rheostat more than 51 mm, and the accelerometer sensor reads data more than 45 deg; also, the rain gauge tipping bucket sensor reads more than 70 mm/hour. This test creates parameter data. So that shift data can be monitored.

References

[1] T. S. Doni Monardo, “Laporan Kinerja BNPB,” Badan Nasional Penanggulangan Bencana, Jakarta, 2019.
[2] Paimin, Sukresno and I. B. Pramono, Teknik Mitigasi Banjir dan Tanah Longsor, Bogor: Tropenbos International Indonesia Programme (2009), 2009.
[3] H. A. Nugroho, R. H. P., Suharni, A. T. Sutanto and Hariyanto, “Rancang Bangun Real Time Monitoring dan Peringatan Dini Tanah Longsor Berbasis Risiko,” Prosiding Seminar Nasional Fisika (SINAFI) 2018, pp. 302-306, 2018.
[4] D. F. Supriyadi, “Sistem Monitoring Pergeseran Tanah Terhadap Potensi Longsor Secara Wireless Berbasis Mikrokontroler,” ADLN-Perpustakaan Universitas Airlangga, Surabaya, 2016.
[5] H. Ardia, “Kecelakaan Kereta Malabar,” Bisnis.com, 6 April 2014. [Online]. Available: https://ekonomi.bisnis.com/read/20140406/98/217336/kecaccident-kereta-malabar-penyebab-masih-diinvestigation-knkt . [Accessed 2020 May 13].
[6] K. J. A. M. A. J. S. T. M. B. M. Crissa D. Fernandez, "Development of Microcontroller-based Landslide Early Warning System," IEEE Region 10 Conference (TENCON)-Proceeding of the International Conference, pp. 3000-3005, 2016.
[7] D. Bailey, Practical Radio Engineering and Telemetry for Industry, Australia: Newnes, an imprint of Elsevier, 2003.
[8] K. Baidwan and C. Kumar, "Design of Linear Variable Differential Transformer (LVDT) Based Displacement Sensor with Wider Linear Range Characteristics," The International Journal of Science & Technoledge, vol. 3, no. 4, pp. 74-79, 2015.
[9] A. N. H and George, "Design and Development of a Planar Linear Variable Differential Transformer for Displacement Sensing," IEEE Sensors Journal, Vols. 5298-5305, p. 17 (16), 2017.
[10] W. Jefriyanto, E. Satria and M. Djamal, “Pengembangan Sensor LVDT (Linear Variable Differential Transformer dengan berbagai Konfigurasi,” Prosiding SKF 2017, pp. 66-73, 2017.
[11] W. Jefriyanto, B. G. M. Saka and M. Djamal, “Desain Prototype Sensor Pergerakan Tanah Dengan Menggunakan Sensor LVDT (Linear Variable Differential Transformer),” Neutrino-Jurnal Pendidikan Fisika, vol. 2, no. 1, pp. 25-29, 2019.
[12] Y. P, Y. PN, L. K, R. L, W. Sp and R. O, “Sistem Telemetri Simulasi Mitigasi Bencana Kegempaan dan Deteksi Peningkatan Kadar Konduktivitas Belerang pada Gunung Berapi Berbasis Wireless 802.15.4,” Jurnal Pendidikan Fisika dan Aplikasinya (JPFA), vol. 4, no. 2, pp. 15-21, 2014.
[13] Z. Hendri and Wildian, “Pembuatan dan Karakterisasi LVDT sebagai Sensor Jarak,” Jurnal Fisika Unand, vol. 2, no. 3, pp. 170-179, 2013.
[14] Y. M. P. D. Prof. Drs. Sukestiyarno, Olah Data Penelitian Berbantuan SPSS, Semarang: Universitas Negeri Semarang, 2016.