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Wireless Residential Electric Controller Using Arduino Uno and Bluetooth Module HC-05 Nelwan, Allan; Manembu, Pinrolinvic; Wauran, Alfrets; Manoppo, Franky; Mamahit, Calvin
JURNAL EDUNITRO Jurnal Pendidikan Teknik Elektro Vol. 3 No. 1 (2023): April Issue
Publisher : Department of Electrical Engineering Education, Faculty of Engineering, State University of Manado

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.53682/edunitro.v3i1.5408

Abstract

This research aims to design electrical installations in residential homes that apply Internet of Things (IoT) technology. An Arduino Uno mini system is the controller whose interface uses the HC-05 Bluetooth module. At the same time, the control uses a cellphone with the Android operating system. The design is based on a research development model, but it is not fully standardized by development research because there are some limitations to the problem. The focus is only on tool design, namely planning, manufacturing, and testing the resulting tool or device. The design results obtained an electrical installation control device with an Android phone. The device is capable of connecting and disconnecting load points remotely and automatically. The control distance is approximately 20 meters according to the Bluetooth specifications used.
Smart Home with Voice Control Lights Using Arduino Uno R3 Mamahit, Calvin; Wauran, Alfrets; Manoppo, Franky; Seke, Fransiskus; Ticoh, Janne
JURNAL EDUNITRO Jurnal Pendidikan Teknik Elektro Vol. 3 No. 2 (2023): October Issue
Publisher : Department of Electrical Engineering Education, Faculty of Engineering, State University of Manado

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.53682/edunitro.v3i2.6792

Abstract

The development of science and technology has positively impacted human life, which has now reached the age of electric voice commands. An intelligent home management system allows humans to operate their house's electrical gadgets, such as lighting, using simple voice commands, eliminating the need to move around to switch on or off equipment. When users of indoor lighting use sound waves to operate the system or turn on the lights, the sound sensor sends an input signal to the microcontroller, which is then processed with the microcontroller's output in the form of a voltage to turn on the load. The system will function when the FC-04 sound sensor receives sound input (sound code). The FC-04 sound sensor can only provide a digital output signal with a value of 1 and 0 in the form of a clap, which is then accumulated on Arduino with a value above 400 million by the program uploaded to be used as a 5-volt output to turn on/off the lights. This is because when turning on the lights from a certain distance, several factors can affect it, including setting the sound sensor's sensitivity and noise levels in the surrounding area.
Wireless Residential Electric Controller Using Arduino Uno and Bluetooth Module HC 05 Nelwan, Allan; Manembu, Pinrolinvic; Wauran, Alfrets; Manoppo, Franky; Mamahit, Calvin
JURNAL EDUNITRO Jurnal Pendidikan Teknik Elektro Vol. 3 No. 1 (2023): April Issue
Publisher : Department of Electrical Engineering Education, Faculty of Engineering, State University of Manado

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.53682/edunitro.v3i1.5408

Abstract

This research aims to design electrical installations in residential homes that apply Internet of Things IoT technology An Arduino Uno mini system is the controller whose interface uses the HC 05 Bluetooth module At the same time the control uses a cellphone with the Android operating system The design is based on a research development model but it is not fully standardized by development research because there are some limitations to the problem The focus is only on tool design namely planning manufacturing and testing the resulting tool or device The design results obtained an electrical installation control device with an Android phone The device is capable of connecting and disconnecting load points remotely and automatically The control distance is approximately 20 meters according to the Bluetooth specifications used < p>
Smart Home with Voice Control Lights Using Arduino Uno R3 Mamahit, Calvin; Wauran, Alfrets; Manoppo, Franky; Seke, Fransiskus; Ticoh, Janne
JURNAL EDUNITRO Jurnal Pendidikan Teknik Elektro Vol. 3 No. 2 (2023): October Issue
Publisher : Department of Electrical Engineering Education, Faculty of Engineering, State University of Manado

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.53682/edunitro.v3i2.6792

Abstract

The development of science and technology has positively impacted human life which has now reached the age of electric voice commands An intelligent home management system allows humans to operate their house s electrical gadgets such as lighting using simple voice commands eliminating the need to move around to switch on or off equipment When users of indoor lighting use sound waves to operate the system or turn on the lights the sound sensor sends an input signal to the microcontroller which is then processed with the microcontroller s output in the form of a voltage to turn on the load The system will function when the FC 04 sound sensor receives sound input sound code The FC 04 sound sensor can only provide a digital output signal with a value of 1 and 0 in the form of a clap which is then accumulated on Arduino with a value above 400 million by the program uploaded to be used as a 5 volt output to turn on off the lights This is because when turning on the lights from a certain distance several factors can affect it including setting the sound sensor s sensitivity and noise levels in the surrounding area < p>
Implementation of Data Logging and Fault History in the Automatic Transfer Switch System at the Automation Laboratory, Electrical Engineering Department, Politeknik Negeri Manado Ilshi Tesalonika Lapian; Jesika Diana Tabar; Renaldy Rondonuwu; Fitria Claudya Lahinta; Alfrets Septy Wauran
Journal of Social Research Vol. 5 No. 7 (2026): Journal of Social Research
Publisher : International Journal Labs

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.55324/josr.v5i7.3296

Abstract

Automatic Transfer Switch (ATS) systems are essential for maintaining power continuity in automation laboratories, where equipment such as PLCs, HMIs, and servo drives requires an uninterrupted power supply. Despite widespread ATS deployment, most laboratory-scale implementations operate without a structured mechanism for recording fault events, leaving operators without historical data for reliability evaluation, root-cause analysis, or maintenance planning.This paper presents the design and implementation of an integrated data logging and fault history system for an ATS at the Automation Laboratory, Electrical Engineering Department, Politeknik Negeri Manado, using a PLC–SCADA architecture over Modbus TCP/IP. Two complementary logging mechanisms were implemented: periodic time-series recording of electrical parameters (voltage, current, and frequency) at one-second intervals, and event-driven fault logging that captured timestamped records upon detection of undervoltage, blackout, and trip conditions. The SCADA platform provided real-time visualization, alarm management, historical trend display, and CSV data export. Fifty simulated fault cycles across three fault categories were conducted to evaluate system performance. All fault events were correctly detected and logged, achieving a 100% detection rate, zero false positives, and timestamp accuracy of ±12 ms. Reliability metrics—Mean Time To Repair (MTTR = 2.31 s), Mean Time Between Failures (MTBF = 6.72 h), and system availability (99.990%)—were computed automatically from the historian database.The system transformed a conventional ATS installation into a data-rich monitoring platform capable of supporting quantitative reliability analysis and evidence-based maintenance decision-making.