GreenHouse DESIGN OF FERTIGATION SYSTEM CONTROL IN GREEN HOUSE BASED ON INTERNET OF THING (IoT)

Muhammad Hasan Basri

doi:10.36456/best.vol5.no1.6171

Authors

Muhammad Hasan Basri Universitas Nurul Jadid

DOI:

https://doi.org/10.36456/best.vol5.no1.6171

Keywords:

Green house, Control System Fertigasi, Sensor DHT22, Mikrokontroler NodeMCU ESP8266, Blynk

Abstract

Abstract - Green house must be able to control the environment with temperature and humidity parameters that are suitable for plant growth. However, manual watering must always be done at any time, which is time-consuming for farmers. Greenhouses with modern technology create automatic controls such as plant sprinklers. Thus, the time spent on watering plants is less than the manual system. In addition, farmers can save water which has been wasted all this time because they do not know the condition of water requirements for plants. An automatic plant watering system with a DHT 22 sensor is used to control the greenhouse environment. With the development of the internet almost all over the world, giving changes to daily human activities. Internet of Things (IoT) technology allows objects to connect and communicate with each other. In this fertigation control device, IOT connects sensor devices and solenoid valves to be monitored via the internet network. IoT is built with the ESP8266 module which allows access via the internet. The hardware design uses a microcontroller as a control method. The data is then sent online to an open-source site that acts as a web server. The web server is used for controlling and monitoring data accessed via the internet. The conclusion of this tool is that the system can do watering automatically. The system can do watering automatically, greater than the humidity temperature of 30 and humidity of less than 90%. So that the condition of the plants can be maintained properly. The system can be controlled with a WIFI network through the Blynk application. Can display the status of humidity, temperature and humidity conditions on the LCD and the Blynk application. Can be controlled from anywhere and anytime.

References

L. A. Lomo, “Smart Greenhouse Berbasis Mikrokontroler Arduino Mega 2650 Rev 3,” Jur. Tek. Elektro Fak. Sains dan Teknol. Univ. Sanata Dharma, pp. 1–65, 2016, [Online]. Available: https://repository.usd.ac.id/6331/2/125114042_full.pdf

R. Oktaviani and E. T. Pawenang, “Risiko Gejala Keracunan Pestisida pada Petani Greenhouse,” Higeia J. Public Heal. Res. Dev., vol. 4, no. 2, pp. 178–188, 2020, [Online]. Available: http://journal.unnes.ac.id/sju/index.php/higeiahttps://doi.org/10.15294/higeia/v4i2/33544

A. Minariyanto, M. Mardiono, and S. W. Lestari, “Perancangan Prototype Sistem Pengendali Otomatis Pada Greenhouse Untuk Tanaman Cabai Berbasis Arduino Dan Internet Of Things (IoT),” J. Teknol., vol. 7, no. 2, pp. 121–135, 2020, doi: 10.31479/jtek.v7i2.50.

O. P. Y. Meishanti, D. Cahyanto, A. S. Arifin, and ..., “Pemberdayaan Green House Enviromental Literacy Desa Kayen,” Jumat Pertan. …, vol. 2, no. 1, 2021, [Online]. Available: http://ejournal.unwaha.ac.id/index.php/abdimasper/article/view/1152

Arisnandar et al., “Pemanfaatan Greenhouse sebagai Media Pembelajaran Kontekstual ABSTRAK,” J. lepa-lepa open, vol. 1, no. 2, pp. 298–306, 2021, [Online]. Available: https://ojs.unm.ac.id/JLLO/article/view/16918/pdf

T. Liu, “Digital-output relative humidity & temperature sensor/module DHT22,” New York Aosong Electron., vol. 22, pp. 1–10, 2015.

D. Alexander and O. Turang, “PENGEMBANGAN SISTEM RELAY PENGENDALIAN DAN PENGHEMATAN PEMAKAIAN LAMPU BERBASIS MOBILE,” vol. 2015, no. November, pp. 75–85, 2015.

F. Marinus, B. Yulianti, and M. Haryanti, “Rancang Bangun Sistem Penyiraman Tanaman Berdasarkan Waktu Menggunakan Rtc Berbasis Arduino Uno Pada Tanaman Tomat,” J. Univ. Suryadarma, pp. 78–89, 2020.

M. Y. Efendi and J. E. Chandra, “Implementasi Internet of Things Pada Sistem Kendali Lampu Rumah Menggunakan Telegram Messenger Bot Dan Nodemcu Esp 8266,” Glob. J. Comput. Sci. Technol. A Hardw. Comput., vol. 19, no. 1, p. 16, 2019.

I. Efimov and G. Salama, “The future of optical mapping is bright: RE: Review on: ‘optical imaging of voltage and calcium in cardiac cells and tissues’ by Herron, Lee, and Jalife,” Circ. Res., vol. 110, no. 10, pp. 292–297, 2012, doi: 10.1161/CIRCRESAHA.112.270033.

Winarno, Adi, and Awang Joko Mastera. "DESAIN SISTEM PENDETEKSI KEBAKARAN HUTAN DENGAN GPS DAN TELEGRAM." TESLA: Jurnal Teknik Elektro 25.1 (2023): 1-12.

Winarno, Adi, and Nur Faizim. "Design & Build a Slurry Transfer Control & Monitoring System on the ATM 140 Spray Dryer using Microcontroller with Ultrasonic Sensors." BEST: Journal of Applied Electrical, Science, & Technology 4.2 (2022): 57-62.

Bastari, Winarno Fadjar, Akbar Sujiwa, and Rizky Setyobudi. "Penerapan Internet Of Things Pada Aplikasi Alat Deteksi Dan Monitoring Tekanan Darah." SNHRP 5 (2023): 609-621.

Solikin, Akhmad, and Endang Setyati. "DROWSY DETECTION FROM VIDEO DRIVER FACE BASED ON EYE AND MOUTH FEATURES EXTRACTION USING THE CONVOLUTION NEURAL NETWORK METHOD." BEST: Journal of Applied Electrical, Science, & Technology 2.1 (2020): 30-33.

Solikin, Akhmad, Yulfi Ainun Al Farizi, and Yanantra Budi Pramana. "Wireless Android-Based Control of Plastic Crane Roll Control Prototype." BEST: Journal of Applied Electrical, Science, & Technology 4.1 (2022): 37-40.

Fauszan, Muchammad Lukman, Mochamad Choirul Fu’ad, and Akhmad Solikin. "Sistem Rancang Bangun Alat Pemberi Pakan Otomatis Pada Ayam Petelur Berbasis IoT Menggunakan Node MCU." SinarFe7 5.1 (2022): 85-89.

Rochman, Sagita, and Roib Mukodah. "AUTOMATIC FISH GRILLER BASED ON TEMPERATURE CONTROLLER." BEST: Journal of Applied Electrical, Science, & Technology 2.2 (2020): 33-36.

Suryawati, Indri, and Sagita Rochman. "GENERATOR FUEL COST OPTIMIZATION USING ANT COLONY ALGORITHM." BEST: Journal of Applied Electrical, Science, & Technology 1.1 (2019): 1-4.