IoT Implementation in Water Level Monitoring System Using ESP32 and Antares Platform
DOI:
https://doi.org/10.30871/ji.v18i1.12814Keywords:
Internet of Things (IoT), ESP32, Antares, Ultrasonic Sensor, MQTT, Water Level Monitoring, Real-time MonitoringAbstract
This research develops an Internet of Things (IoT)-based water level monitoring system that can work in real-time both locally and online. The system is designed using an ultrasonic sensor integrated with an ESP32 microcontroller to process and send data to the Antares platform via the MQTT protocol. The obtained data can be displayed via the Antares dashboard and an I2C LCD as a local display, equipped with LED indicators and a buzzer as a warning when the water level is below the 65 cm threshold. To maintain communication stability, a static IP configuration is used. Test results show that the system has high accuracy with an average error of 0.2 cm, a delay of 129.15 ms, and no packet loss, thus being able to provide reliable performance. Thus, this system is considered effective, efficient, and suitable for application in monitoring water levels for various industrial needs.
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References
[1] Y. Ratmini, V. Atina, and E. Purwanto, “Sistem Monitoring dan Peringatan Dini Banjir Berbasis Internet of Things (IoT),” Jurnal Ilmiah Teknologi Informasi Asia, vol. 19, no. 1, pp. 1–7, Feb. 2025, doi: 10.32815/jitika.v19i1.1103.
[2] K. Fajri, I. Santoso, and T. Prakoso, “ANALISIS KINERJA TRANSMISI DATA ANTAR NODE DAN NODE KE SERVER DENGAN PARAMETER QOS PADA JARINGAN SENSOR NIRKABEL.”
[3] N. Syamsi, M. Ulfah, and D. Lesmideyarti, “Water Level Monitoring for Flood Early Mitigation Based on Internet of Things (IoT),” TEPIAN, vol. 5, no. 2, pp. 58–64, Jun. 2024, doi: 10.51967/tepian.v5i2.2504.
[4] I. Bagus, M. Lingga Pradirta, I. Nyoman Piarsa, I. Putu, A. Dharmaadi, and P. Korespondensi, “SISTEM PENDETEKSI BANJIR DAN BADAI ANGIN SERTA MONITORING CUACA BERBASIS INTERNET OF THINGS”, doi: 10.25126/jtiik.202295983.
[5] Noptin Harpawi and Yogi Syaputra, “Monitoring Kualitas Udara dan Kontrol Air PurifierT,” vol. 8, May 2022.
[6] I. Noval, A. Prahara, and I. R. Widiasari, “Implementasi Metode Received Signal Strength Indication dan Quality of Service Terhadap Analisis Kualitas Jaringan Wireless di CV Java Media Perdana Pati,” Jurnal Teknologi Informasi dan Komunikasi), vol. 7, no. 4, p. 2023, 2023, doi: 10.35870/jti.
[7] I. Sari Kusuma Wardhana, B. Agus Wardjiono, S. Jakarta STI, and S. Komputer, “Analisis Pengiriman Data Sensor dengan Jaringan Wireless Meggunakan Metode Quality of Service (QoS),” vol. 5, no. 2, pp. 371–383, 2022, doi: 10.31764/justek.vXiY.ZZZ.
[8] A. Fatakhunnaim1, A. E. Jayati2, and P. Muliandhi3, “Analisis Kualitas Jaringan Wi-Fi di Lantai 7 Gedung Menara USM Menggunakan Ekahau Site Survey.”
[9] M. K. Rihmi, G. Bintoro, M. A. Rahman, G. Puspito, and A. Muntaha, “ACCURACY ANALYSIS OF DISTANCE MEASUREMENT USING SONAR ULTRASONIC SENSOR HC-SR04 ON SEVERAL TYPES OF MATERIALS,” Journal of Environmental Engineering & Sustainable Technology JEEST, vol. 11, no. 01, pp. 10–13, 2024, [Online]. Available: http://jeest.ub.ac.id
