Pemantauan Kualitas Udara Berbasis Internet Of Things
DOI:
https://doi.org/10.30865/klik.v3i2.566Keywords:
Air Quality Monitoring System; WeMos; MQ-7; GP2Y1010AU0F; DHT11Abstract
Air quality control is very important to do to avoid several diseases and minimize the effects of lung damage for Covid-19 survivors due to the increasing number of air pollution. This makes it quite difficult for people to know the air quality. The method used is a research and development method that includes system design, tool making, web-based application design, tool integration, and system testing. The sensors used are the MQ-7 sensor for CO gas, the Sharp GP2Y1010AU0F sensor for dust, and the DHT11 sensor for temperature and humidity. Each sensor is assembled into one with the WeMos D1 R2 microcontroller. The results of the system test for three days showed that the average temperature was 29.18°C, humidity was 80.01%, CO was 3983 g/m3 , and dust was 83.90 g/m3 . air quality monitoring systems for CO gas and dust pollutants can provide early warnings of poor air quality, so that people around the location of equipment placement can be more alert and reduce activities in the environment. Air quality data obtained from sensors can be displayed in real-time through the Blynk application and also stored on the ThingSpeak server which can be displayed on the ThingView application and web-based applications.
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References
H. Setya et al., “Balancing Robot Roda Dua dengan Metode Rule base Berbasis Mikrokontroller Arduino,” Balanc. Robot Roda Dua dengan Metod. Rule base Berbas. Mikrokontroller Arduino, vol. 11, no. 1, pp. 7–11, 2018.
T. V. Damayanti and R. E. Handriyono, “Monitoring Kualitas Udara Ambien Melalui Stasiun Pemantau Kualitas Udara Wonorejo, Kebonsari Dan Tandes Kota Surabaya,” Environ. Eng. J. ITATS, vol. 2, no. 1, pp. 11–18, 2022.
Y. Aprianto, N. Nurhasanah, and I. Sanubary, “Prediksi Kadar Particulate Matter (PM10) untuk Pemantauan Kualitas Udara Menggunakan Jaringan Syaraf Tiruan Studi Kasus Kota Pontianak,” Positron, vol. 8, no. 1, p. 15, 2018.
Ansori, “PERATURAN MENTERI KESEHATAN REPUBLIK INDONESIA NOMOR 1077/MENKES/PER/V/2011 Title No Title,” Pap. Knowl. . Towar. a Media Hist. Doc., vol. 3, no. April, pp. 49–58, 2015.
R. D. Ratnani, “Teknik Pengendalian Pencemaran Udara Yang Diakibatkan oleh Partikel,” Momentum, vol. 4, no. 2, pp. 27–32, 2008.
A. Sabiq, N. Nurmaya, T. Alfarisi, and Y. A. Pratama, “Purwarupa Sistem Pemantauan Kualitas Udara dan Cuaca Melalui Web Berbasis Wireless Sensor Network,” JST (Jurnal Sains dan Teknol., vol. 6, no. 2, pp. 248–257, 2017.
G. C. Rumampuk, V. C. Poekoel, and A. M. Rumagit, “Perancangan Sistem Monitoring Kualitas Udara Dalam Ruangan Berbasis Internet of Things,” J. Tek. Inform., vol. 17, no. 1, pp. 11–18, 2021.
J. M. S. Waworundeng and O. Lengkong, “Sistem Monitoring dan Notifikasi Kualitas Udara dalam Ruangan dengan Platform IoT,” CogITo Smart J., vol. 4, no. 1, p. 94, 2018.
H. Subagiyo, R. Tri Wahyuni, M. Akbar, and F. Ulfa, “Rancang Bangun Sensor Node untuk Pemantauan Kualitas Udara,” J. Sains, Teknol. dan Ind., vol. 18, no. 1, p. 72, 2021.
A. Oktaviani and Hustinawati, “Prediksi Rata-Rata Zat Berbahaya Di Dki Jakarta Berdasarkan Indeks Standar Pencemar Udara Menggunakan Metode Long Short-Term Memory,” J. Ilm. Inform. Komput., vol. 26, no. 1, pp. 41–55, 2021.
M. A. A. Razali, M. Kassim, N. A. Sulaiman, and S. Saaidin, “A ThingSpeak IoT on Real Time Room Condition Monitoring System,” 2020 IEEE Int. Conf. Autom. Control Intell. Syst. I2CACIS 2020 - Proc., no. June, pp. 206–211, 2020.
D. Lederman and W. F. Maloney, “R & D and Development,” Sci. Technol., no. September, p. 38, 2004.
Y. Setiawan, H. Tanudjaja, and S. Octaviani, “Penggunaan Internet of Things (IoT) untuk Pemantauan dan Pengendalian Sistem Hidroponik,” TESLA J. Tek. Elektro, vol. 20, no. 2, p. 175, 2019.
Y. Pranatha, “Sistem Monitoring Kualitas Udara Berbasis Internet of Things,” reserchGate, no. 1, pp. 26–27, 2020.
G. Kalaivani and P. Mayilvahanan, “Air Quality Prediction and Monitoring using Machine Learning Algorithm based IoT sensor- A researcher’s perspective,” Proc. 6th Int. Conf. Commun. Electron. Syst. ICCES 2021, 2021.
D. Parida, A. Behera, J. K. Naik, S. Pattanaik, and R. S. Nanda, “Real-time environment monitoring system using ESP8266 and thingspeak on internet of things platform,” 2019 Int. Conf. Intell. Comput. Control Syst. ICCS 2019, no. Iciccs, pp. 225–229, 2019.
M. Sadali, Y. K. Putra, L. Kertawijaya, and I. Gunawan, “Sistem Monitoring dan Notifikasi Kualitas Udara Dijalan Raya Dengan Platform IOT,” Infotek J. Inform. dan Teknol., vol. 5, no. 1, pp. 11–21, 2022.
M. S. Meraz, M. G. J. Gutierrez, and I. M. Juarez, “Air Quality Monitoring in a Smart Campus,” 2020 IEEE Int. Smart Cities Conf. ISC2 2020, 2020.
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