The focus of this research is to utilize wind energy for power generation as an electric power service for shrimp farming in the Kulon Progo district of Yogyakarta. This is done in order to minimize the use of diesel fuel in daily operations to drive the aerator pump that produces air bubbles and needs lighting. The method used is to calculate the need for electrical power in 24 hours, plan the windmill according to the local average wind speed. Parameters for measuring the final result are net present cost (NPC), cost of energy (CoE), and payback period. The scenario is used by installing a wind power generator compared to a generator from a diesel engine. The results of the study with a wind power generation system capable of producing 41755,07kW/year of power with the NPC value having a more efficient economic value of Rp. 158,254,000.00, a more efficient CoE value of Rp. 477.41, and for a diesel power plant of Rp. 1,569,015,240.00 and CoE worth Rp5,867,45. The payback period for the scenario with wind power is 3 years and 9 months and and 15 years 7 months for the scenario with diesel power plants.

Ahshan, R., Al-Badi, A., Hosseinzadeh, N., & Shafiq, M. (2018). Small wind turbine systems for application in Oman. 2018 5th International Conference on Electric Power and Energy Conversion Systems (EPECS), 1–6.

Badaruddin, B., & Hardiansyah, F. (2015). Perhitungan Optimasi Bahan Bakar Solar pada Pemakaian Generator Set Di BTS. Jurnal Teknologi Elektro, 6(2), 142512.

Burton, T., Jenkins, N., Sharpe, D., & Bossanyi, E. (2011). Wind energy handbook. John Wiley & Sons.

Fara, L. (2012). Advanced solar cell materials, technology, modeling, and simulation. IGI Global.

Hasibuan, A., Dani, F., Nrartha, I. M. A., & others. (2022). Simulation and Analysis of Distributed Generation Installation on a 20 kV Distribution System Using ETAP 19.0. Bulletin of Computer Science and Electrical Engineering, 3(1), 18–29.

Juwito, A. F., Pramonohadi, S., & Haryono, T. (2012). Optimalisasi energi terbarukan pada pembangkit tenaga listrik dalam menghadapi desa mandiri energi di Margajaya. Semesta Teknika, 15(1).

Katadata KKP. (2016). Indonesia raja udang ASEAN. Your Own Wind Turbine. Centre for Alternative Technology. http://www.m.katadata.co.id/infografik/2016/03/30/indonesiaraja

Nehrir, M. H., Wang, C., Strunz, K., Aki, H., Ramakumar, R., Bing, J., Miao, Z., & Salameh, Z. (2011). A review of hybrid renewable/alternative energy systems for electric power generation: Configurations, control, and applications. IEEE Transactions on Sustainable Energy, 2(4), 392–403.

Piggot, H. (1997). Windpower workshop building your own wind turbine. Centre of Alternative Technologi Publication.

Putri, R., Hasibuan, A., Ezwarsyah, E., Jannah, M., Kurniawan, R., Siregar, W. V., & Sayuti, M. S. (2022). Pembangkit Listrik Tenaga Bayu sebagai Sumber Alternatif pada Mesjid Tengku Bullah Universitas Malikussaleh. RELE (Rekayasa Elektrikal Dan Energi): Jurnal Teknik Elektro, 5(1), 39–44.

Susanti, I. (2019). Analisa Penentuan Kapasitas Baterai dan Pengisiannya Pada Mobil Listrik. Jurnal Elektra, 4(2), 29–37.

Yasuha, J. X. L., Saifi, M., & others. (2017). Analisis Kelayakan Investasi Atas Rencana Penambahan Aktiva Tetap (Studi Kasus pada PT. Pelabuhan Indonesia III (Persero) Cabang Tanjung Perak Terminal Nilam). Jurnal Administrasi Bisnis (JAB), 46(1).