PROTOTIPE ATAP STADION OTOMATIS BERBASIS IoT (INTERNET OF THING) DENGAN APLIKASI BLYNK
##plugins.themes.bootstrap3.article.sidebar##
##plugins.themes.bootstrap3.article.main##
Abstract
Stadium is the venue for sport activities like football, athletics, and and also be used for opening and ceremonial venue, and music concerts. The application of stadium roof is needed to anticipate unpredictable weather conditions that can hinder the running event. The stadium prototipe are made by using an electrical actuator in the form of a servo motor. The prototype have 3 input sensors in the form of LDR sensor, water level sensor, and DHT11 sensor, which function for read a weather condition around the stadium and for output using mini roof programmed using NodeMCU. Analysis of roof stadium performance testing is carried out with variables and parameters, and the test include the water level sensor test in reading weather conditions, servo motion test, DHT 11 sensor test to read temperature and humidity, and LDR sensor test to read conditions in the stadium. In the water level sensor test and the LDR sensor test there is no error. In the DHT11 sensor test error was found 0,6% for temperature reading and 1,9% error for humidity reading. In the servo motion test average success is 98,1% for first servo and 96,8% for second servo.
##plugins.themes.bootstrap3.article.details##
Faruq, M. M. (2008). Meningkatkan Kebugaran Tubuh Melalui Permainan dan Olahraga Bulu Tangkis. Jakarta.
Prasetyo, Y. W. (2018). Konsep Perencanaan dan Perancangan Stadion Olahraga Di Depok Dengan Pendekatan Arsitektur High-Tech. Universitas Sebelas Maret. Surakarta
Sulastri, R. (2016). Prototype Kendali Buka/Tutup Atap Dan Penyiraman Tanaman Cabai Berbasis Mikrokontroler dan SMS Gateway. Politeknik Negeri Sriwijaya. Palembang.
Mustar, M. Y., & Wiyagi, R. O. (2017). Implementasi Sistem Monitoring Deteksi Hujan dan Suhu Berbasis Sensor Secara Real Time (Implementation of Rain Detection and Temperature Monitoring System Based on Real Time Sensor). Jurnal Semesta Teknika. Vol. 20, No. 1: 20–28.
Feriska, A., & Triyanto, D. (2017) Rancang Bangun Penjemur dan Pengering Pakaian Otomatis Berbasis Mikrokontroler. Universitas Tanjungpura. Pontianak
Maulana, I., & Nur, K. H. (2014) Motor Servo DC Politeknik Negeri Bandung. Bandung.
Aprilia, A. R., Hidayat, R., & Wibisono, A. (2016) “Prototipe Mesin Bank Botol Plastik Menggunakan RFID (Radio Frequency Identification),” Jurnal Autocracy, vol. 3, no. 2. 83-94.
Ardian, H., Triyanto, D., & Rismawan, T. (2017) Sistem Kendali Lampu dan Steker Terintegrasi Menggunakan Mikrokontroler berbasis Web Service. Universitas Tanjungpura. Pontianak.
Syam, R. (2015). Seri buku ajar : Robotika Kinematika dan Dinamika Robot Lengan. Universitas Hasanuddin. Makassar.
Rizqulloh, S. R., Hadikusuma, R. S., Aulia, N., & Hidayat, R. (2022). Automatic Sluice Monitoring Based On The Water Ph In a Brackish Water Pool Using a Web Server. Jurnal Elektro Teknik, 1(1), 22-29.
Saragih, Y., Silaban, J. H. P., Roostiani, H. A., & Elisabet, S. A. (2020, June). Design of automatic water flood control and monitoring systems in reservoirs based on internet of things (IoT). In 2020 3rd International Conference on Mechanical, Electronics, Computer, and Industrial Technology (MECnIT) (pp. 30-35). IEEE.
Arafat. (2016) Sistem Pengamanan Pintu Rumah Berbasis Internet Of Things (IoT) Dengan ESP8266. Universitas Islam Kalimantan. Banjarmasin
Handi, Fitriyah, H., & Setyawan, G., E. (2019) Sistem Pemantauan Menggunakan Blynk dan Pengendalian Penyiraman Tanaman Jamur Dengan Metode Logika Fuzzy. Universitas Brawijaya. Malang