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e-Jurnal Arus Elektro Indonesia
Published by Universitas Jember
ISSN : 25023508     EISSN : 24432318     DOI : -
Core Subject : Engineering,
Electrical & Electronics Engineering
JAEI (Jurnal Arus Elektro Indonesia) adalah majalah berkala ilmiah yang berisi hasil penelitian para peneliti, dosen dan praktisi mengenai ilmu-ilmu bidang keteknik elektroan khususnya di Indonesia dan tidak menutup kemungkinan hasil riset dari para penulis luar negeri. Arus yang dimaksud disini adalah asumsi dari pergerakan elektron yang mengalir melalui sebuah media tertentu. Dengan diberikannya bagian nama “arus” ini, keberlanjutannya nanti akan terus “mengalir arus” perkembangan terkini ilmu pengetahuan keteknik elektroan dengan lebih cepat di seluruh Indonesia melalui media artikel/jurnal ilmiah ini. Adapun topik-topik yang diusulkan untuk terbit pada majalah berkala ilmiah JAEI ini adalah topik mengenai elektronika, sistem tenaga, energi terbarukan, kendali, telekomunikasi dan multimedia.
Arjuna Subject : -
Articles 5 Documents
 1 
Search results for , issue "Vol 9 No 1 (2023)" : 5 Documents clear
Water Pipeline Monitoring System Using Flow Sensor Based on the Internet of Things Dedy Wahyu Herdiyanto; Triwahju Hardianto; Dimas Ardiansyah; Immawan Wicaksono; Widya Cahyadi; Catur Suko Sarwono
Jurnal Arus Elektro Indonesia Vol 9 No 1 (2023)
Publisher : Fakultas Teknik, Universitas Jember

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.19184/jaei.v9i1.39121

Abstract

Pipe leakage is one of the most common problems in agriculture. Especially if the agricultural land is quite large, it will be challenging to determine the location if a leak occurs. Active sensors are not recommended because they do not follow the green computing concept (energy-efficient computing). This study is proposed to use a passive type sensor that is more energy efficient. This study will use a water flow sensor placed at several points in the irrigation pipe network. The water flow sensor was chosen because this sensor works passively and is very accurate in detecting changes in water flow, especially in flowing water. The sensor reading results will be sent using the Internet of Things with a Wi-Fi connection. The collected data results are processed on the server and displayed in an interface that makes it easy for users to monitor water flow through smartphones. The results of the tests that have been carried out show that the designed system has worked as expected. The system can detect the location of the leaking pipe flow and indicate the leaking pipe.
Sistem Monitoring dan Logging pada Oxygen Concentrator Berbasis Node-RED dengan Protokol MQTT Keyasa Abimanyu Nugroho; Dian Figana
Jurnal Arus Elektro Indonesia Vol 9 No 1 (2023)
Publisher : Fakultas Teknik, Universitas Jember

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.19184/jaei.v9i1.33652

Abstract

Covid-19 is a spreading disease caused by SARS-CoV-2, a type of coronavirus. Covid-19 first case was reported from Wuhan, China on 31 December 2019. The virus spread rapidly to the other countries all over the world. The virus spread from an infected person’s mouth or nose in small liquid particles when they cough or sneezing. Oxygen supply in Indonesia is rare because everybody’s panick to buy their own oxygen tank and refill the supply. With PSA technology, Oxygen Concentrator that is going to be made will have an Oxygen Concentration output more than 90%. This sistem is using VPS that has its own public IP that can be accessed by internet. Monitoring and Logging system is made using flow on Node-RED that will monitor data from PLC, Oxygen Concentration and Flow. PLC Data that is read-able by Node-RED LocalHost will be published to broker using MQTT. The othe Node-RED VPS will subscribed to the broker with a specific topic and get that data. Based on the tests that is done, the monitoring and logging system is working, it shows the data on a gauge widget, chart, and level. The data that is sent through broker will be stored in a database. The data will be called by query if the user wanted to see the logger data based on the date. The maximum value of the measured Oxygen Concentration is 96.18%.
Prototype Sistem Peringatan Dini Berbasis Iot (Internet Of Things) untuk Mitigasi Bencana Tsunami di Pantai Pancer, Puger Ahmad Fauzil Akbar; Widya Cahyadi; Wahyu Muldayani
Jurnal Arus Elektro Indonesia Vol 9 No 1 (2023)
Publisher : Fakultas Teknik, Universitas Jember

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.19184/jaei.v9i1.30044

Abstract

Industri 4.0 adalah konsep revolusi industri ke 4 yang menggabungkan teknologi otomasi dengan cyber technology. IoT merupakan salah satu pilar utama dalam perkembangan revolusi industri 4.0. Fondasi IoT dapat dianggap sebagai infrastruktur jaringan global yang terdiri dari banyak perangkat terhubung yang mengandalkan teknologi sensorik, komunikasi, jaringan, dan pemrosesan informasi. Mitigasi bencana adalah serangkaian upaya untuk mengurangi risiko bencana, baik melalui pembangunan fisik maupun penyadaran dan peningkatan kemampuan menghadapi ancaman bencana. Pada penelitian ini akan dilakukan perancangan dan analisis kinerja prototype perangkat pendeteksi tsunami berbasis IoT akibat aktivitas gempa di bawah laut. Perubahan tinggi pasang surut air laut akan dimonitor secara real-time dan diolah sehingga dapat memberikan peringatan dini apabila parameter terjadinya tsunami terdeteksi. Dari analisa dan pengolahan data yang telah dilakukan dapat diambil kesimpulan prototype alat system peringatan dini tsunami yang telah dibuat bekerja dengan baik dan benar. Hal ini dibuktikan dengan sensor ultrasonic dapat membaca data, modul sim900 dapat mengirimkan data dan database dapat menyimpan data yang telah dikirimkan.
T, The Thermostat Automation for Controlled Temperature in Simulated Incubator Ekha Rifki Fauzi
Jurnal Arus Elektro Indonesia Vol 9 No 1 (2023)
Publisher : Fakultas Teknik, Universitas Jember

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.19184/jaei.v9i1.34354

Abstract

Morbiditas dan mortalitas neonatus biasanya disebabkan oleh prematuritas neonatus atau BBLR (berat badan lahir rendah). Selanjutnya, neonatus prematur akan diberi obat pada inkubator. Perangkat inkubator harus membuat lingkungan yang cocok untuk bayi seperti tingkat suhu yang stabil, konsentrasi oksigen, dan kelembaban. Tingkat suhu harus dipantau sekitar 36°-38°C pada perangkat inkubator neonatus. Termostat dapat digunakan untuk mendapatkan suhu batas atas & bawah yang telah ditentukan inkubator. Selain itu, inkubator yang disimulasikan memiliki kunci relai yang berfungsi untuk mencegah perangkat rusak karena aliran listrik yang tidak stabil dari sumber listrik. Inkubator simulasi ini secara khusus dapat digunakan dalam sistem inkubator pada perangkat inkubator.
Inovasi Desain dan Simulasi Function Generator Dengan Integrasi Microcontroller Adi Mulyadi; Muhammad Zainal Roisul Amin; Muchlis Abdi
Jurnal Arus Elektro Indonesia Vol 9 No 1 (2023)
Publisher : Fakultas Teknik, Universitas Jember

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.19184/jaei.v9i1.35067

Abstract

This paper discusses the innovation design and simulation of the function generator. The design uses the Atmega16 microcontroller and Integrated Circuit (IC) DAC0808, ATmega16, and LF351. The design and simulation were implemented at the Electrical Laboratory of the PGRI Banyuwangi University as a practical reference. The function generator test uses a frequency range of 30 Hz to 200 KHz with three waveforms of sine, pulse and ramp. The simulation results show that a sine wave is obtained at a frequency of 1 KHz and a period of 1120 us. Pulse waves are obtained at a frequency of 1 KHz and a period of 1150 us, while a ramp wave with a frequency of 1 KHz and a period of 1150 us. This proves that the function generator can generate signal waves at a frequency of 1 KHz with varying periods.

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