DC Power Bibliography

Hopey D.  2015.  {FirstEnergy to pay for solar installations at CCAC}. Pittsburgh Post-Gazette.

Hopey D.  2015.  {FirstEnergy to pay for solar installations at CCAC}. Pittsburgh Post-Gazette.

Freeman D.  2013.  {A follow-up on the DC-powered home}. EDN Network.

SHWEHDI MH, Aqil MAAl.  2014.  Forthcoming smart DC nano-grid for green buildings—A reflective vision. International Journal of Smart Grid and Clean Energy. :52–58.

SHWEHDI MH, Aqil MAAl.  2014.  {Forthcoming smart DC nano-grid for green buildings—A reflective vision}. International Journal of Smart Grid and Clean Energy. :52–58.

Crebier JC, Barbosa PG, Canales F, Lee FC, Ferrieux JP.  2000.  Frequency domain analysis and evaluation of differential mode input current for three-phase DCM boost rectifiers with different control strategies. Power Electronics Specialists Conference, 2000. PESC 00. 2000 IEEE 31st Annual. 1:482–487vol.1.

Crebier JC, Barbosa PG, Canales F, Lee FC, Ferrieux JP.  2000.  {Frequency domain analysis and evaluation of differential mode input current for three-phase DCM boost rectifiers with different control strategies}. Power Electronics Specialists Conference, 2000. PESC 00. 2000 IEEE 31st Annual. 1:482–487vol.1.

Moore D.  2016.  {From Pittsburgh to India, racing to reinvent the electric grid Pt 1/2}. Pittsburgh Post-Gazette2.

Wang Y, Choi S, Lee E.  2009.  Fuel cell power conditioning system design for residential application. International Journal of Hydrogen Energy. 34:2340–2349.

Wang Y, Choi S, Lee E.  2009.  {Fuel cell power conditioning system design for residential application}. International Journal of Hydrogen Energy. 34:2340–2349.

Xu H, Kong L, Wen X.  2004.  Fuel cell power system and high power DC-DC converter. Power Electronics, IEEE Transactions on. 19:1250–1255.

Xu H, Kong L, Wen X.  2004.  {Fuel cell power system and high power DC-DC converter}. Power Electronics, IEEE Transactions on. 19:1250–1255.

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, 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.

Blaabjerg F, Consoli A, Ferreira JA, Van Wyk JD.  2005.  The future of electronic power processing and conversion. Industry Applications, IEEE Transactions on. 41:3–8.

Blaabjerg F, Consoli A, Ferreira JA, Van Wyk JD.  2005.  {The future of electronic power processing and conversion}. Industry Applications, IEEE Transactions on. 41:3–8.