Single Ended Primary Inductace Converter (SEPIC) merupakan converter turunan buck-boost converter di mana converter tersebut dapat menaikkan maupun menurunkan tegangan input namun polaritas tegangan output SEPIC tidak berubah. Di mana polaritas tegangan output buck-boost converter terbalik. Hasil simulasi gelombang pada software PSIM sendiri masih terdapat rise time yang lumayan tinggi sehingga dibutuhkan kontrol untuk menghilangkan rise time dan membuat settling time menjadi lebih singkat. Kontrol yang digunakan merupakan kontrol proporsional dan kontrol integratif. Di mana kontrol proporsional memiliki fungsi untuk memperbaiki transient dan settling time dan kontrol integratif memiliki fungsi untuk membuat error steady state-nya berkurang menjadi 0. Metode yang digunakan adalah metode Ziegler Nichols. Hasil yang didapatkan adalah penggunaan kontrol Proporsional Integratif dapat menghilangkan overshoot pada sistem close-loop, namun settling time yang dibutuhkan cenderung lebih lama yaitu: 0,152 detik jika dibandingkan dengan sistem open-loop yaitu: 0,0754 detik dan lebih banyak ripple yang dihasilkan sehingga perlu dikaji ulang untuk mendapatkan respon yang lebih baik lagi.

SEPIC; konverter; kontrol proporsional; kontrol integratif

Daniel W. Hart, “Power Electronicsâ€, 2015

Aisuwarya, R. and Hidayati, Y. "Implementation of Ziegler-Nichols PID Tuning Method on Stabilizing Temperature of Hot-water Dispenser," 2019 16th International Conference on Quality in Research (QIR): International Symposium on Electrical and Computer Engineering, Padang, Indonesia, 2019, pp. 1-5.

Azrita, B.A., Maaspaliza, B.A., Auzani, B.J., and Wahidah, B.A.H. "A modified PID controller of SEPIC converter for excellent dynamic performance," 2016 IEEE International Conference on Power and Energy (PECon), Melaka, Malaysia, 2016, pp. 423-427.

Baliwant, B.B., Gothane, A.R., and Waghmare, V.B. "PWM Based Charge Controller For Renewable Energy Applications Using SEPIC Converter," 2019 3rd International Conference on Computing Methodologies and Communication (ICCMC), Erode, India, 2019, pp. 1051-1054.

Rose, J.L., and Sankaragomathi, B. Design, Modeling, Analysis and Simulation of a SEPIC Converter. Middle-East Journal of Scientific Research, 24(7), 2016, pp. 2302-2308.

Gangadharan, K. A Closed Loop Converter of Modified Sepic Converter for Renewable Application. IJREE, 3(2), 2016, pp. 7-12.

Sakthivel, C., Selvakumar, K.and Venkatesan, T. Modified SEPIC Converter with High Static Gain for Renewable Energy Applications. IJCTA, 9(37), 2016, pp. 865-873.

Ilayaraja, S. and Narmadha, T.V. "Modeling of an E-Vehicle Charging Station using DC-DC Self-lift SEPIC Converter," 2016 Second International Conference on Science Technology Engineering and Management (ICONSTEM), Chennai, India, 2016, pp. 526-531.

Poluthai, S. and Jirasuwankul, N. "Simulation of a Miniature SEPIC Converter with PI Controller for Thermoelectric Generator Module," 2018 International Electrical Engineering Congress (iEECON), Krabi, Thailand, 2018, pp. 1-4.

Durgadevi, S. and Umamaheswari, M.G. Analysis and Design of Single Phase Power Factor Correction with DC–DC SEPIC Converter for Fast Dynamic Response using Genetic Algorithm Optimised PI Controller. IET Circuits, Devices & Systems, 12(2), 2018, pp. 164-174.