Renewable energy implementation could become the alternative for electrical energy supply in a remote area with no network for electricity and also could be implemented in an urban area to reduce electricity consumption in daily usage. One of the problems to implement renewable energy is how to measure solar power potential and wind power potential to decide the qualification to apply the system in a particular area. This research used Arduino Uno as the main Controller that connected to a Voltage sensor, Current Sensor ACS712 30A dan light intensity sensor BH1750 to measure solar power potential and also anemometer to measure wind power potential. Software design was done using Arduino IDE program that successfully produced stable Low-Cost system that can operate well with all kind of solar panel with maximum Voltage of 34.7 V and current ± 30 A. The results from system testing shows that the system has accuracy for voltage sensor with value of 99.2%, current sensor with value of 95.3% and light intensity sensor with value of 99.8% and also has excellent precision with SDR value  for every sensor are 0.034%, 4.58% and 0.026%.

monitoring system; data logger; wind power; solar power

Winasis, W. Azis, R. Imron, and S. Fajar, “Desain Sistem Monitoring Sistem Photovoltaic Berbasis Internet Of Things (IoT),” Jurnal Nasional Teknik Elektro Teknik Informatika (JNTETI) Vol. 5, No. 4, p.328-333 November 2016

T. Hamdani, (View Sept. 2018). “Arcandra Paparkan 3 Kunci Kembangkan Energi Terbarukan di RI [Online],” Availabe: https://finance.detik.com/energi/d-3987615/arcandra-paparkan-3-kunci-kembangkan-energi-terbarukan-di-ri

M. Pamungkas., H. Hafiddudin, and Y. S. Rohmah, “Perancangan dan Realisasi Alat Pengukur Intensitas Cahaya,” ELKOMIKA: Jurnal Teknik Energi Elektrik, Teknik Telekomunikasi, & Teknik Elektronika, Vol. 3, No. 2, p.120-132, 2015.

M. Fuentes, M. Vivar, J. M. Burgos, J. Aguilera, and J. A. Vacas, “Design of an accurate, low-cost autonomous data logger for PV system monitoring using Arduino™ that complies with IEC standards,” Solar Energi Materials and Solar Cells, Vol.130, p.529-543, November 2014.

A.F. Farizy, D.A. Asfani. “Desain Sistem Monitoring State Of Charge Baterai Pada Charging Station Mobil Listrik Berbasis Fuzzy Logic Dengan Mempertimbangkan Temperature”. Jurnal Teknik ITS, Vol.5, No.2, p.278-282, Oktober 2016.

E. Machmud, “Rancang Bangun Maximum Power Point Tracking (MPPT) Solar Sel Untuk Aplikasi Pada Sistem Grid Pembangkit Listrik Tenaga Angin (PLTAg),” Jurnal Gamma Universitas Muhammadiyah Malang Vol.9, No.1, p.170-178 September 2013.

Z. Arifin, and H. Rahadian, “Rancang Bangun Stand-Alone Automatic Rain Gauge (ARG) Berbasis Panel Surya,” Jurnal Nasional Teknik Elektro Vol.6, No.3, p. 178-184, 2017.

The National Optical Astronomy Observatory NOAO, (View Jun. 2018). “Recommended Light Levels (Illuminance) for Outdoor and Indoor Venues” Available: https://www.noao.edu/education/QLTkit/

ACTIVITY_Documents/Safety/LightLevels_outdoor+indoor.pdf.

O. Dwiyanto, “Kwh Meter Digital Dengan Sensor Arus Acs712 Berbasis Mikrokontroler Atmega 32,” Doctoral dissertation, Universitas Muhammadiyah Surakarta, 2010.

M. Ikhsan, and Y. Away, “Teknik Reduksi Energi pada Perancangan Data Logger Parameter Matahari,” Jurnal Rekayasa Elektrika, Vol.11, No.1, p.30-35, 2014.

M. R. Fachri, I. D. Sara, and Y. Away, “Pemantauan Parameter Panel Surya Berbasis Arduino secara Real Time,” Jurnal Rekayasa Elektrika, Vol.11, No.4, p.123-128, 2015.