DC Power Bibliography

Starke MR, Tolbert LM, Ozpineci B.  2008.  AC vs. DC distribution: A loss comparison. Transmission and Distribution Conference and Exposition, 2008. T&D. IEEE/PES. :1–7.

Starke MR, Tolbert LM, Ozpineci B.  2008.  {AC vs. DC distribution: A loss comparison}. Transmission and Distribution Conference and Exposition, 2008. T{&}D. IEEE/PES. :1–7.

Starke MR, Li F, Tolbert LM, Ozpineci B.  2008.  AC vs. DC distribution: Maximum transfer capability. Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century, 2008 IEEE. :1–6.

Starke MR, Li F, Tolbert LM, Ozpineci B.  2008.  {AC vs. DC distribution: Maximum transfer capability}. Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century, 2008 IEEE. :1–6.

Kakigano H, Miura Y, Ise T.  2009.  {Configuration and control of a DC microgrid for residential houses}. Transmission and Distribution Conference and Exhibition: Asia and Pacific, IEEE/PES. :1–4.

Kakigano H, Miura Y, Ise T.  2009.  Configuration and control of a DC microgrid for residential houses. Transmission and Distribution Conference and Exposition: Asia and Pacific, T and D Asia 2009.

Kurohane K, Uehara A, Senjyu T, Yona A, Urasaki N, Funabashi T, Kim CH.  2011.  {Control strategy for a distributed DC power system with renewable energy}. Renewable Energy. 36:42–49.

Kurohane K, Uehara A, Senjyu T, Yona A, Urasaki N, Funabashi T, Kim CH.  2011.  Control strategy for a distributed DC power system with renewable energy. Renewable Energy. 36:42–49.

Baran ME, Mahajan NR.  2003.  DC distribution for industrial systems: opportunities and challenges. Industry Applications, IEEE Transactions on. 39:1596–1601.

Baran ME, Mahajan NR.  2003.  {DC distribution for industrial systems: opportunities and challenges}. Industry Applications, IEEE Transactions on. 39:1596–1601.

Hesla E, Brusso B, Downey L, Giese B, Parise G, Valdes M, Clemente K, Cook C, Dionise T, Garland P et al..  2013.  {DC task team report}. Industrial {&} Commercial Power Systems Technical Conf (I{&}CPS), 2013 IEEE/IAS 49th. :1–9.

Hesla E, Brusso B, Downey L, Giese B, Parise G, Valdes M, Clemente K, Cook C, Dionise T, Garland P et al..  2013.  DC task team report. Industrial & Commercial Power Systems Technical Conf (I&CPS), 2013 IEEE/IAS 49th. :1–9.

Techakittiroj K.  2008.  Electrical plug and outlet for the DC distribution system in buildings. Control, Automation and Systems, 2008. ICCAS 2008. International Conference on. :2667–2670.

Techakittiroj K.  2008.  {Electrical plug and outlet for the DC distribution system in buildings}. Control, Automation and Systems, 2008. ICCAS 2008. International Conference on. :2667–2670.

Kakigano H, Miura Y, Ise T, Momose T, Hayakawa H.  2008.  {Fundamental characteristics of DC microgrid for residential houses with cogeneration system in each house}. IEEE Power and Energy Society 2008 General Meeting: Conversion and Delivery of Electrical Energy in the 21st Century, PES. :1–8.

Kakigano H, Miura Y, Ise T, Momose T, Hayakawa H.  2008.  Fundamental characteristics of DC microgrid for residential houses with cogeneration system in each house. IEEE Power and Energy Society 2008 General Meeting: Conversion and Delivery of Electrical Energy in the 21st Century, PES.

Kakigano H, Miura Y, Ise T, Momose T, Hayakawa H.  2008.  Fundamental characteristics of DC microgrid for residential houses with cogeneration system in each house. IEEE Power and Energy Society 2008 General Meeting: Conversion and Delivery of Electrical Energy in the 21st Century, PES. :1–8.

Kakigano H, Hashimoto T, Matsumura Y, Kurotani T, Iwamoto W, Miura Y, Ise T, Momose T, Hayakawa H.  2010.  {Fundamental characteristics of laboratory scale model DC microgrid to exchange electric power from distributed generators installed in residential houses}. Electrical Engineering in Japan (English translation of Denki Gakkai Ronbunshi). 172:28–41.

Kakigano H, Hashimoto T, Matsumura Y, Kurotani T, Iwamoto W, Miura Y, Ise T, Momose T, Hayakawa H.  2010.  Fundamental characteristics of laboratory scale model DC microgrid to exchange electric power from distributed generators installed in residential houses. Electrical Engineering in Japan (English translation of Denki Gakkai Ronbunshi). 172:28–41.

, Cvetkovic I, Boroyevich D, Zhang W, Wang R, Mattavelli P.  2013.  Grid-interface bidirectional converter for residential DC distribution systems - Part one: High-density two-stage topology. IEEE Transactions on Power Electronics. 28

, Cvetkovic I, Boroyevich D, Zhang W, Wang R, Mattavelli P.  2013.  {Grid-interface bidirectional converter for residential DC distribution systems - Part one: High-density two-stage topology}. IEEE Transactions on Power Electronics. 28

Kurohane K, Senjyu T, Uehara A, Yona A, Funabashi T, Kim C-H.  2010.  {A hybrid smart AC/DC power system}. Industrial Electronics and Applications (ICIEA), 2010 the 5th IEEE Conference on. :764–769.

Kurohane K, Senjyu T, Uehara A, Yona A, Funabashi T, Kim C-H.  2010.  A hybrid smart AC/DC power system. Industrial Electronics and Applications (ICIEA), 2010 the 5th IEEE Conference on. :764–769.

Kakigano H, Nomura M, Ise T.  2010.  Loss evaluation of dc distribution for residential houses compared with ac system. 2010 International Power Electronics Conference - ECCE Asia -, IPEC 2010. :480–486.

Kakigano H, Nomura M, Ise T.  2010.  {Loss evaluation of dc distribution for residential houses compared with ac system}. 2010 International Power Electronics Conference - ECCE Asia -, IPEC 2010. :480–486.