Analisis Karakteristik Disturbansi Frekuensi 9 – 150 Khz Pada Sistem Photovoltaic Terhadap Tipe Beban Induktif

  • Nagib Muhammad Jurusan Teknik Elektro, Politeknik Negeri Jakarta
  • Budi Utami Jurusan Teknik Elektro, Politeknik Negeri Jakarta
  • Hatib Setiana Jurusan Teknik Elektro, Politeknik Negeri Jakarta


The Solar Power Plant converts light into electricity using photovoltaic. It uses an inverter to convert DC to AC electricity to be connected to an AC load. Along with the increasing use of solar panel, inverter use has also increased. In fact, the inverter can produce disturbances at frequency between 9-150kHz. Based on this matter, this study is focused on observing the disturbance characteristics of photovoltaic system due to variations in irradiation and inductive load in the frequency range from 9 - 150 kHz. It is expected that the output of this observations can be a reference for research in analyzing, predicting and knowing the effects on the electric power system. First, this observation provide inductive type of load then observe it in at least two different solar irradiation conditions. Based on observations obtained, in general there are three frequencies of dominant disturbances, namely the range 19-29kHz, 69-79Khz, and 140-149kHz.


Download data is not yet available.


Agudelo-Martinez, D., Garzon, C. & Pavas, A., 2018. Interaction of power quality disturbances within 2–150 kHz (supraharmonics): Analytical framework. Ljubljana, IEEE.

David, P., Jose, A. S., Costa, S. & Joao, M. S., 2017. Investigating the impact of solar cells partial shading on photovoltaic modules by thermography. Washington DC, IEEE, pp. 1979-1983.

Dubey, R. et al., 2015. Measurement of temperature coefficient of photovoltaic modules in field and comparison with laboratory measurements. New Orleans, IEEE.

Grevener, A., Meyer, J. & Rönnberg, S., 2020. Comparison of Measurement Methods for the Frequency Range 2–150 kHz (Supraharmonics) Based on the Present Standards Framework. IEEE Access, Volume 8, pp. 77618 - 77630.

Hiren, P. & Vivek, A., 2008. MATLAB-Based Modeling to Study the Effects of Partial Shading on PV Array Characteristics. IEEE Transactions on Energy Conversion, 23(1), pp. 302-310.

Rajput, S. K., 2017. SOLAR ENERGY Fundamentals, Economic and Energy Analysis. In: Ghaziabad: NITRA, pp. 1-7.

Malek, H. & Chen, Y., 2014. BICO MPPT: A Faster Maximum Power Point Tracker and Its Application for Photovoltaic Panels. International Journal of Photoenergy, Volume 2014.

Priyadarshi, S., Bhaduri, S. & Shiradkar, N., 2018. IoT Based, Inexpensive System for Large Scale, Wireless, Remote Temperature Monitoring of Photovoltaic Modules. Waikoloa, IEEE.

Quasching, V., 2005. Understanding Renewable Energy Systems. London: Earthscan.

Ritzman, D. et al., 2020. Comparison of Measurement Methods for 2–150-kHz Conducted Emissions in Power Networks. IEEE Transactions on Instrumentation and Measurement, Volume 70.

Samah, L., Mouna, B. & Lassaad, S., 2017. Analysis of shading effects on a photovoltaic array. Hammamet, IEEE, pp. 1-5.

Sandrolini, L., Thomas, D. W. P., Sumner, M. & Rose, C., 2018. Measurement and Evaluation of the Conducted Emissions of a DC/DC Power Converter in the Frequency Range 2–150 kHz. Long Beach, IEEE.

Schuepbach, E. et al., 2015. Swiss Energy Strategy 2050: Research on Photovoltaic Electricity Production. Monte Carlo, IEEE.

Sudiarto, B., 2017. The Properties and Behavior of Disturbances in the Frequency Range 9 kHz to 150 kHz Produced by Household Appliances in a Residential Network Environment, Duisburg: ETS University Duisburg Essen.

Sudiarto, B., Widyanto, A. N. & Hirsch, H., 2016. Effect of Standby Mode Operation of Some Household Appliances on Disturbance Voltage and Current in Frequency Range of 9-150 kHz Produced by Other Equipment in Low Voltage Network. Wroclaw, IEEE, pp. 722-725.

Syed, D., Gitanjali, M. & Vinod, K. Y., 2017. Assessing the performance of partially shaded photovoltaic array under different radiations. Delhi, IEEE, pp. 1-3.

Tiandho, Y. et al., 2018. Accurate Model for Temperature Dependence of Solar Cell Performance According to Phonon Energy Correction. Latvian Journal of Physics and Technical Sciences, 55(5), pp. 15-25.

Wu, W., Zhang, C., Su, J. & Wang, H., 2015. The Design of New High Efficiency Photovoltaic Grid and Independent Power Supply Inverter. Jabalpur, IEEE.

Yaghoobi, J., Zare, F., Rehman, T. & Rathnayake, H., 2019. Analysis of High Frequency Harmonics in Distribution Networks : 9 - 150 kHz. Melbourne, IEEE.

Zhuang, S., Zhao, W., Wang, Q. & Huang, S., 2018. A New Measurement Method for Supraharmonics in 2–150 kHz. Paris, IEEE.

How to Cite
Muhammad, N., Utami, B., & Setiana, H. (2024). Analisis Karakteristik Disturbansi Frekuensi 9 – 150 Khz Pada Sistem Photovoltaic Terhadap Tipe Beban Induktif. Jurnal Teknologi Dan Sistem Informasi Bisnis, 6(2), 297-303.