Sistem Monitoring Tanda Belok, Pengereman, dan Kecepatan pada Sepeda Motor Menggunakan MIT APP Inventor
Keywords:
IoT, Google Firebase, Google Spreadsheet, Sepeda Motor, MIT APP Inventor
Abstract
Traffic accidents are a serious issue, causing an average of three fatalities every hour. Based on available data, approximately 61% of traffic accidents are caused by human factors, 9% by vehicle roadworthiness, and 30% by infrastructure-related factors such as road conditions, traffic signs, weather, and the surrounding environment. In the process of accident investigation, law enforcement officers often face difficulties in obtaining accurate data related to vehicle speed, braking activity, and the use of turn signals by the rider. As a result, the information gathered is often subjective and varies among different witnesses. This study aims to design and implement a motorcycle monitoring system capable of recording vehicle speed, braking actions, and turn signal activation in real-time to support objective traffic accident analysis. The method used in this research involves the development of a microcontroller-based hardware system equipped with a speed sensor, brake sensor, and turn signal sensor. All data is automatically transmitted using Internet of Things (IoT) connectivity to the Google Firebase platform. An Android application developed using MIT App Inventor displays the data in real-time, while storage is handled through integration with Google Spreadsheet. The results of this system are expected to provide accurate and reliable reference data for law enforcement and relevant institutions in analyzing traffic accidents, as well as to serve as a preventive tool for future incidents by enabling digital monitoring of driving behavior. Keywords: IoT, Google Firebase, Google Sheets, Motorcycle Vehicles, MIT APP InventorDownloads
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[4] F. Ratnawati and M. A. Subandri, “Implementasi Sistem Monitoring Kecepatan Sepeda Motor Siswa SLTA Sederajat,” TANJAK J. Pengabdi. Kpd. Masy., vol. 5, no. 2, pp. 181–188, 2024, doi: 10.35314/27t5ff63.
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[6] I. Oktavianto, D. Wirasamita, and A. Salim, “PERANCANGAN SISTEM KENDALI STARTER SEPEDA MOTOR BERBASIS ANDROID MENGGUNAKAN APP INVENTOR,” 2021.
[7] N. Shittain Mitu, V. T. Vassilev, and M. Tabany, “Low Cost, Easy-to-Use, IoT and Cloud-Based Real-Time Environment Monitoring System Using ESP8266 Microcontroller,” vol. 6, no. February, pp. 30–44, 2021, [Online]. Available: http://www.iaras.org/iaras/journals/ijitws.
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[9] Wikipedia, “NodeMCU.” .
[10] H. Muchtar and B. Firdaus, “Kendaraan Sepeda Motor Berbasis Aplikasi Android,” no. November, pp. 1–2, 2017.
[11] R. Nurul Hidayatullah, N. Ariesanto Ramdhan, and A. Khamid, “Pengembangan Kendali Lampu Menggunakan Mikrokontroler Nodemcu Esp32 Dan Arduino Ide Berbasis Internet of Things (Iot),” JATI (Jurnal Mhs. Tek. Inform., vol. 8, no. 4, pp. 7762–7767, 2024, doi: 10.36040/jati.v8i4.10461.
[12] L. A. Yuliani, L. Nurpulaela, and U. Latifa, “Implementasi Node MCU Sebagai Serial Komunikasi dengan Arduino Uno pada Smart Shopping Trolley,” J. ELTIKOM, vol. 5, no. 1, pp. 48–55, 2021, doi: 10.31961/eltikom.v5i1.282.
[13] Y. I. A. Yanti, “Rancang Bangun Buck-Bosost Converter Pada Sistem Pembangkit Listrik Tenaga Mikro Hidro,” Instutut Teknologi Sepuluh November, 2017.
[14] A. G. Giyantara, D. Christover, and Y. T. K. Priyanto, “Design and Implementation Buck-boost Converter using Arduino Mega 2560,” no. Iconit 2019, pp. 169–176, 2020, doi: 10.5220/0009443301690176.
[15] Y. T. Lin, C. Y. Tseng, J. H. Kuang, and Y. M. Hwang, “A design method for a variable combined brake system for motorcycles applying the adaptive control method,” Machines, vol. 9, no. 2, pp. 1–18, 2021, doi: 10.3390/machines9020031.
[16] V. agus Arintika, “ANALISA SISTEM PENGEREMAN COMBI BRAKE SYSTEM(CBS) PADA HONDA VARIO TECHNO 125 IDLING STOP SYSTEM(ISS) PGM-FI DENGAN PENGARUH PENAMBAHAN VARIASI MAS,” Institut Teknologi Sepuluh November, 2015.
Published
2025-07-21
How to Cite
Herizon, H., Artika, B., Yuliza, M., & Rahmat, R. (2025, July 21). Sistem Monitoring Tanda Belok, Pengereman, dan Kecepatan pada Sepeda Motor Menggunakan MIT APP Inventor. Elektron : Jurnal Ilmiah, 17(1), 27-32. https://doi.org/https://doi.org/10.30630/eji.17.1.588
Section
Articles

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