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Electrician : Jurnal Rekayasa dan Teknologi Elektro
Published by Universitas Lampung
ISSN : -     EISSN : 25493442     DOI : https://doi.org/10.23960/elc
Core Subject : Engineering,
Control & Systems Engineering Electrical & Electronics Engineering Engineering
Focus and Scope Publication of scientific research results in the field of electrical engineering which covers: ~ Power system analysis ~ Electrical energy conversion ~ High voltage technology ~ Electronics ~ Control system ~ Telecommunication system ~ Computer and interfacing ~ Information engineering.
Arjuna Subject : Teknik (semua kategori) - Teknik Listrik dan Elektro
Articles 265 Documents
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Penerapan Logika Fuzzy untuk Kendali Suhu Ruangan dengan Air Conditioner pada Rumah dan Kantor Adrianus Raffel; Yoga Alif Kurnia Utama
Electrician : Jurnal Rekayasa dan Teknologi Elektro Vol. 17 No. 3 (2023)
Publisher : Department of Electrical Engineering, Faculty of Engineering, Universitas Lampung

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.23960/elc.v17n3.2536

Abstract

The purpose of this research is to build a fuzzy logic system using the mamdani method which can control room temperature with Air Conditioner (AC) in homes and offices so that every room in the house and office that uses Air Conditioner (AC) as air conditioner gets optimal temperature so it doesn't affect the health of people in the room, saves electricity usage, and can extend the life of the Air Conditioner (AC) itself. In this study several parameters will be used such as room size, number of Air Conditioners (AC) in one room, Air Conditioner (AC) specifications, and the number of people in one room where these parameters will be taken from daily life in Indonesia. Then from these parameters will be processed with fuzzy logic using the mamdani method so that it will produce an output in the form of what is the optimal temperature that will be issued by the Air Conditioner (AC) in the room.
Simulasi Analisis Kualitas Daya Menggunakan Logika Fuzzy Untuk Meningkatkan Efisiensi Sistem Tenaga Listrik Fernando Wibisono; Tamaji
Electrician : Jurnal Rekayasa dan Teknologi Elektro Vol. 17 No. 3 (2023)
Publisher : Department of Electrical Engineering, Faculty of Engineering, Universitas Lampung

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.23960/elc.v17n3.2539

Abstract

This study aims to simulate power quality analysis using fuzzy logic to increase the efficiency of the power system. Poor power quality can cause disturbances in the electric power system and reduce the efficiency of the energy used. Therefore, improving power quality is one of the main focuses in the electric power industry.The fuzzy logic method is used in this study to evaluate power quality based on relevant parameters, such as voltage, current, frequency and harmonics. Fuzzy logic is able to overcome the uncertainty and complexity of data related to electric power systems, and provide more adaptive and intelligent solutions. In this study, simulations were carried out using special software that implements fuzzy logic to analyze power quality. The input data obtained from the electric power system is used to build a fuzzy logic model. Then, the simulation results are used to identify existing power quality problems and propose appropriate improvement strategies.The simulation results show that the use of fuzzy logic can significantly increase the efficiency of the power system by minimizing disturbances and optimizing power quality. In addition, fuzzy logic also provides the ability to predict the future conditions of the electric power system and take the necessary precautions. This research has important practical implications in the field of power systems. By using fuzzy logic in power quality analysis, power companies and grid operators can optimize power system operations, reduce power losses, improve energy efficiency, and ensure reliable electricity supply to consumers.
Rancang Bangun Prototipe Rumah Kaca untuk Tanaman Stroberi Berbasis Internet of Things Muhammad Dimas Syaputra
Electrician : Jurnal Rekayasa dan Teknologi Elektro Vol. 17 No. 3 (2023)
Publisher : Department of Electrical Engineering, Faculty of Engineering, Universitas Lampung

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.23960/elc.v17n3.2543

Abstract

Stroberi merupakan suatu jenis buah-buahan dimana bernilai ekonomis yang tinggi dan di dalamnya terkandung segudang manfaat. Pembudidayaan tanaman stroberi di Indonesia telah mulai dilakukan. Penanaman stroberi dinilai memiliki nilai ekonomis yang cukup menghasilkan di sisi petani. Dalam melakukan pembudidayaan stroberi, suhu dan kelembaban tanaman stroberi merupakan hal sangat penting dalam pertumbuhan stroberi. Jika suhu terlalu tunggi maka tanaman bisa kehilangan kemampuan fisiologisnya seperti seperti fotosintesis,nutrisi dan jika suhu terlalu rendah pertumbuhan tanaman menjadi lambat bahkan berhenti. Dari permasalahan tersebut , peneliti bertujuan membuat prototipe rumah kaca yang memiliki beberapa komponen seperti tempetur suhu agar kondisi rumah kaca tetap terjaga pada suhu 28°C dengan menggunakan sensor DHT11, Sensor Kelembaban Tanah YL 69 digunakan untuk mengetahui kelembaban tanah media tanam, pompa 12 V digunakan untuk melakukan penyiram dan pempukan otomastis, mist maker sebagai pendingin ruang yang dibantu oleh kipas dan ESP8266 sebagai mikrokontroler. Hasil dari alat prototipe rumah kaca ini dapat membantu petani stroberi dalam melakukan perawatan tanaman stroberi dan dapat menghasilkan buah stroberi yang berkualitas sehingga memiliki nilai jual yang cukup mahal
Rancang Bangun Box Pengering Sepatu Berbasis Mikrokontroler Muhammad Reski Ramadhan
Electrician : Jurnal Rekayasa dan Teknologi Elektro Vol. 17 No. 3 (2023)
Publisher : Department of Electrical Engineering, Faculty of Engineering, Universitas Lampung

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.23960/elc.v17n3.2544

Abstract

Intisari -- Sepatu adalah jenis alas kaki (Fotwear) yang biasanya terdiri dari sol, telapak sepatu, penutup sepatu, dan tali sepatu. Kendala yang dialami pada sepatu adalah proses pengeringan menggunakan Cahaya matahari langsung akan merusak kondisi sepatu. Namun bukan hanya factor musim yang mempengaruhi masalah pengeringan sepatu yang basah bisa jadi karena situasi dan kondisi seperti malam hari. Pada Box pengering sepatu ini komponen yang digunakan yaitu elemen pemanas kipas dc peltier, sensor DHT22, Sensor Soil Moisture (Kelembapan Tanah), Lampu UV-C, dan komponen pendukung lainnya. Untuk proses pengeringan sepatu menggunakan kipas dc peltier sebagai penghasil suhu panas dan dingin, sensor DHT22 dan Sensor Soil Moisture berfungsi sebagai sensor suhu dan kelembapan pada box pengeringan sepatu, dan lampu UV-C berfungsi sebagai sterilisasi pada sepatu saat proses pengeringan.
Front Matter Volume 17 No 3 September 2023 Yudi Eka Putra
Electrician : Jurnal Rekayasa dan Teknologi Elektro Vol. 17 No. 3 (2023)
Publisher : Department of Electrical Engineering, Faculty of Engineering, Universitas Lampung

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.23960/elc.v17n3.2548

Abstract

Page 27 of 27 | Total Record : 265

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