DC boost converter is an essensial equipment in the system of DC microgrid  which has a function as step up voltage. In making a boost converter equipment of power generation, it often encounters a problem within especially in designing of switching transformer, so that it is need  a long development  time and   high  development cost. In order to solve this problem, in this research it has been made a inverter  development  as boost converter which has been done by simulation and experiment. The simulation results show that for an input voltage 10-14 Vdc yields voltage 254 Vdc, while by testing for an input voltage 10-14 Vdc yields voltage 253 Vdc. Either simulation or test result  show that voltage can be applied in the system of dc micro grid for the need of load based switch mode power supply /SMPS. 

Lasseter, Robert H, Paigi, Paolo. Microgrid: A Conceptual Solution. Power Electronics Specialists Conference (PESC 04) IEEE 35th Annual. German. 2004; 6: 4285-4290.

Mohammad E. Khodayar, Masoud Barati, Mohammad Shahidehpour. Integration of High Reliability Distribution System in Microgrid Operation. IEEE Transaction on Smart Grid. 2012; 3(4): 1997-2006.

Manual book SI 5048 U-11, SMA Technologie AG Germany. AC Power Supply Produc for Rural Electrification. 2007: 16-17.

Sun Xiao, Yim-Shu Lee, De-hong Xu. Modeling, Analysis, and Implementation of Parallel Multi-Inverter Systems With Instantaneous Average – Current – Sharing Scheme. IEEE Transaction on Power Electronics. 2003; 18(3): 844-856.

Juan C Vasquez, Josep M Guerrero, Alvaro Luna, Pedro Rodríguez, Remus Teodorescu. Adaptive Droop Control Applied to Voltage-Source Inverters Operating in Grid-Connected and Islanded Modes. IEEE Transactions on Industrial Electronic. 2009; 56(10): 4088-4096.

Nilsson Daniel, Ambra Sannino. Efficiency analysis of low and medium voltage dc distribution system. IEEE Power Engineering Society General Meeting. Denver. 2004; 2: 2315-1321.

Youichi Ito, Yang Zhongqing, Hirofumi Akagi. DC Micro-grid Based Distribution Power Generation System. Power Electronics and Motion Control Conference (IPEMC) The 4th International IEEEl. 2004; 3: 1740 – 1745.

Dylan Dah-Chun Lu, Vassilios G. Agelidis. Photovoltaic -Battery-Powered DC Bus System for Common Portable Electronic Device. IEEE Transaction On Power Electronic. 2009; 24(3): 849-855.

Piotr Biczel, Lukas Michalski. Simuling Model of Power Electronic Converters for DC Microgrid Simulation. Power Quality Alternative Energy and Distributed System, in Compatible and Power Electronic (CPE2009) International Conference – Workshop IEEE. 2009; 6: 161-165.

Fang Lin Luo, Hong Ye. Advanced DC/DC converters. CRC Press. ISBN 0-8493-1956-0. 2004: 20-22.

Piotr Biczel. Power Electronic Converters in DC Microgrid. International Conference – Workshop (CPE) IEEE. 2007: 1-6.

Hanh-Phuc Le, Seth R Sanders, Elad Alon. Design Techniques for Fully Integrated Switched-Capacitor DC-DC Converters. IEEE Journal Of Solid-State Circuit. 2011; 46(9): 2120-2131.

Yi-Ping Hsieh, Jiann-Fuh Chen, Tsorng-Juu Liang, Lung-Sheng Yang. A Novel High Step-Up DC-DC Converter for Microgrid. IEEE Transaction on Power Electronic. 2011; 26(4): 1127-1136.

Felinto SF Silva, Antônio AA Freitas, Sérgio Daher, Saulo C. Ximenes, Sarah K. A. Sousa. High Gain DC-DC Boost Convertr With A Coupling Inductor. Power Electronics Conference (COBEP '09). 2009: 486-492.

Hongfei Wu, Kai Sun, Runruo Chen, Haibing Hu, Yan Xing. Full-Bridge Three-Port Converters With Wide Input Voltage Range for Renewable Power Systems. IEEE Transactions on Power Electronics. 2012; 27(9): 3965 – 3974

Ned Mohan, Tore M Undelan, William P Robbins. Power Electronics, Converter, Application and Design. Third Edition. West Susse: John Willey & Sons. 2003: 172-174.

Budiyanto, Rudy Setiabudy, Eko Adhi Setiawan, Uno Bintang Sudibyo. Development Of Direct Current Microgrid Control For Ensuring Power Supply From Renewable Energy Sources. International Journal of Technology (IJTech). 2011; 2(3): 199-206.