The utilization of solar energy in the Auditorium Indonesian Defense University (IDU) is not optimal because problem on the system off-grid The problems that occur due to technical factors (operating system is not in accordance with the concept of smart building) and non-technical (HR, Budget Maintenance, and SOP / SOM). The method used by the researchers is the optimization of observation and interviews. Optimization of solar energy utilization in Building IDU Auditorium is affected by three factors such as human resources, maintenance budgets, and standards of procedure (SOP) and the standard of maintenance (SOM). Besides the three factors were the use operational system that refers to the concept of smart building to be responsible for optimizing the utilization of solar power to support energy security

Akikur, Saidur, H.W. Ping, Ullah. (2013). Comparative study of stand – alone and hybrid solar energy systems suitable for off – gridrural electrification: Areview. Renewable and Sustainable Energy Reviews. Vol. 27. pp.738–752

Ariswan. (2007). Prospek penelitian dan aplikasi photovoltaik sebagai sumber energi alternatif. UNY Jogjakarta

Barkaszi, S.F., J.P. Dunlop. (2001). Discussion of strategies for mounting photovoltaic arrays on rooftops. Proceedings of Solar Forum Solar Energy: The Power to Choose, Washington, D.C., April 21–26, 2001.

Buckman, A.H., M. Mayfield Stephen B.M. Beck. (2014). What is a Smart Building?. Smart and Sustainable Built Environment. Vol. 3 No. 2. pp. 92 – 109

Cook, D.J. and Das, S.K. (2007). How smart are our environments? An updated look at the state of the art. Pervasive and Mobile Computing. Vol. 3 No. 2. pp. 53-73

Crawford, R.H. G.J. Treloar, R.J. Fuller, M. Bazilian. (2006). Life-cycle energy analysis of building integrated photovoltaic systems (BiPVs) with heat recovery unit. Renewable and Sustainable Energy Reviews. Vol. 10. pp: 559–575.

Dargahi, Vahid, Arash Khoshkbar Sadigh; Ganesh Kumar Venayagamoorthy; Keith Corzine. (2015). Hybrid double flying capacitor multicell converter and its application in grid-tied renewable energy resources, IET Generation, Transmission & Distribution. Vol. 9. No. 10. pp: 947-956

Devabhaktuni, Vijay, Mansoor Alam, Soma Shekara Sreenadh Reddy Depuru, Robert C. Green, Douglas Nims, Craig Near, (2013). Solar energy: Trends and enabling technologies, Renewable and Sustainable Energy Reviews. Vol. 19. pp. 555–564

Esposito, Daniel V., Vernon Alt. (2014). Estimating solar energy requirements to meet U.S. energy needs: an outreach event. NCSL International Workshop & Symposium. New York.

Gunawan, Dadang et al. (2013) Peningkatan kemampuan dan kesiapan operasional alat peralatan pertahanan dan keamanan. LPPM Unhan.

Jackson, Frank. (2008). Planning and Installing Photovoltaic Systems A guide for installers, architects and engineers second edition. UK: Earthscan

Kiliccote, S., Piette, M.A., Ghatikar, G., Hafemeister, D., Kammen, D., Levi, B.G. and Schwartz, P. (2011). Smart buildings and demand response. AIP Conference Proceedings. Vol. 1401. Berkeley. March 5-6

Kumara., Nyoman S. (2010). Pembangkit Listrik Tenaga Surya Skala Rumah Tangga Urban Dan Ketersediaannya di Indonesia. Teknologi Elektro. Vol. 9. No.1. pp. 68-75

Long Yua, Katherine Dean, Lin Li. (2006). Polymer blends and composites from renewable resources. Prog. Polym. Sci. Vol. 31. pp: 576–602

Meier, Michael A. R., Ju¨rgen O. Metzgerb and Ulrich S. Schubert. (2007). Plant oil renewable resources as green alternatives in polymer science. Chem. Soc. Rev. Vol. 36. pp: 1788–1802

Mohanty, A.K., Misra, M. & Drzal, L.T. (2002). Sustainable Bio-Composites from Renewable Resources: Opportunities and Challenges in the Green Materials World. Journal of Polymers and the Environment. Vol. 10. No. 19.

Nigam, Poonam Singh, Anoop Singh. (2011). Production of liquid biofuels from renewable resources. Progress in Energy and Combustion Science. Vol. 37. pp: 52 – 68

Penga, Changhai, Ying Huang, Zhishen Wu. (2011). Building-integrated photovoltaics (BIPV) in architectural design in China. Energy and Buildings. Vol. 43. pp. 3592–3598

Piegari, L., and R. Rizzo. (2010). Adaptive perturb and observe algorithm for photovoltaic maximum power point tracking. IET Renew Power Gener. Vol. 4. Iss. 4. pp. 317– 328

Seongwon Seo, Greg Foliente. (2012). Modelling building stock energy use and carbon emission scenarios. Smart and Sustainable Built Environment. Vol. 1 Vol. 2 pp. 118 – 138

Shaheen, Sean E., David S. Ginley, and Ghassan E. Jabbour. (2005). Organic-Based Photovoltaics: Toward Low-Cost Power Generation. Mrs Bulletin. Vol. 30

Siswoyo, Hartono. (2006). Tenaga Surya sebagai Sumber Energi.

Smith C. (1995). Revisiting solar power’s past. Technology Review. pp. 38–47

Sulaiman, Shaharin Anwar, Atul Kumar Singh, Mior Maarof Mior Mokhtar. (2014). Influence of Dirt Accumulation on Performance of PV Panels. Energy Procedia. Vol. 50. pp. 50 – 56

Supriadi, Ivan. (2014). Tentang Analisis Pemanfaatan Pembangkit Listrik Tenaga Surya ( PLTS ) pada Satuan Radar TNI AU untuk Mendukung Pertahanan Negara (Studi Kasus Satuan Radar 211 tanjung Kait ). Sentul Unhan.

Timilsinaa, Govinda R., Lado Kurdgelashvili, Patrick A. Narbel. (2012). Solar energy: Markets, economics and policies. Renewable and Sustainable Energy Reviews. Vol. 16. pp. 449– 465

Timotheus, Tigor. (2014). Pemanfaatan Photovoltaic Sebagai Pembangkit Listrik Tenaga Surya. Medan: STT Immanuel

Wang, Z., Wang, L., Dounis, A.I. and Yang, R. (2012a). Integration of plug-in hybrid electric vehicles into energy and comfort management for smart building. Energy and Buildings. Vol. 47. pp. 260-266.

Wang, Z., Wang, L., Dounis, A.I. and Yang, R. (2012b), Multi-agent control system with information fusion based comfort model for smart buildings. Applied Energy. Vol. 99. pp. 247-254.

Wills, Rosalie, James A. Milke Sara Royle, Kristin Steranka, (2015). Best Practices for Commercial Roof-Mounted Photovoltaic System Installation. New York: Springer.