top of page
Este site foi desenvolvido com o criador de sites
.com
. Crie seu site hoje.Começar

BIBLIOGRAPHY

[1] R. Billiton and W. Li. Reliability Assessment of Electric Power Systems Using Monte Carlo Methods. Plenun Press, 1994.

 

[2] M. A. Rosa. Agent-based Technology Applied to Power Systems Reliability. PhD thesis, Faculty of Engineering of University of Porto, 2009.

 

[3] D. Issicaba, J. A. P. Lopes, and M. Rosa. Adequacy and security evaluation of distribution systems with distributed generation. IEEE Transaction on Power Systems, 27(3):1681-1689, 2012.

 

[4] R. Billinton and R. N. Allan. Reliability Evaluation of Power Systems. Plenun Press, Second edition, 1996.

 

[5] R. E. Brown. Electric Power Distribution Reliability. CRC Press, 2002.

 

[6] M. McGranaghan and D. Mueller. Effects of voltage sags in process industry applications.

 

[7] R. P. Bingham. Sags and swells, February 1998.

 

[8] D. L. Brooks, R. C. Dugan, M. Waclawiak, and A. Sundaram. Indices for assessing utility distribution system rms variation performance. IEEE Transactions on Power Delivery, 13(1), 1998.

 

[9] IEEE recommended practice for monitoring electric power quality, 1995.

 

[10] D. Issicaba. Block-Oriented Agent-Based Architecture to Support the Power Distribution System Operation. PhD thesis, Faculty of Engineering of University of Porto, 2013.

 

[11] IEEE trial-use guide for electric power distribution reliability indices, 1999.

 

[12] T. Ortmeyer. A uni_ed index for power distribution reliability power quality indices. In 14th

International Conference on Harmonics and Quality of Power (ICHQP), pages 1-6. IEEE, September 2010.

 

[13] R. E. Brown, S. Gupta, R. D. Christie, S. S. Venkata, and R. Fletcher. Distribution system reliability assessment: Momentary interruptions and storms. IEEE Transactions on Power Delivery, 12(4):1569-1575, 1997.

 

 [14] J. C. Gomez, G. Campetelli, and M. Felici. Effect of the overcurrent protection settings on distribution systems on the resultant power quality. In 18th International Conference on Electricity Distribution, 2005.

 

[15] J. C. Gomez and M. M. Marcos. Voltage sag and recovery time in repetitive events. IEEE Trans. on Power Delivery, 22(7):1037-1043, 2002.

 

[16] R. S. Thallam and G. T. Heydt. Power acceptability and voltage sag indices in the three phase sense. In Power Engineering Society Summer Meeting, volume 2, pages 905{910, Seattle, July 2000. IEEE.

 

[17] Z. Klaic, S. Nikolovski, and Z. Kraus. Voltage variation performance indices in distribution network. Technical gazette, 18(4):547-551, 2011.

 

[18] J. Fernandes. Modeling adverse weather and electric vehicles integration in the distribution systems reliability assessment. Master's thesis, Faculty of Engineering of University of Porto, 2012.

 

[19] R. A. Gonz_alez-Fern_andez and A. M. Leite da Silva. Reliability assessment of time-dependent systems via sequential cross-entropy monte carlo simulation. IEEE Transactions on Power Systems, 26(4):2381-2389, 2011.

 

[20] A. M. Leite da Silva, W. F. Schmitt, A. M. Cassula, and C. E. Sacramento. Analytical and Monte Carlo approaches to evaluate probability distributions of interruption duration. IEEE Transactions on Power Systems, 20(3):1341{1348, August 2005.

 

[21] A. M. Leite da Silva, L. A. Da Fonseca Manso, J. C. De Oliveira Mello, and R. Billinton. Pseudo-chronological simulation for composite reliability analysis with time varying loads. IEEE Transactions on Power Systems, 15(1):73{80, February 2000.

 

[22] N. D. Hatziargyriou, J. Heliopoulos, and B. C Papadias. Probabilistic assessment of short-circuit currents in large power systems. In Third International Conference on Probabilistic Methods Applied to Electric Power Systems. IET, 1991.

 

[23] A. Balouktsis, D. Tsanakas, and G. Vachtsevanos. Probabilistic short-circuit analysis by Monte Carlo simulations and analytical methods. IEEE Transactions on Power Systems, 1(3):135-140, August 1986.

 

[24] F. Sato, A. V. Garcia, and A. Monticelli. Parallel implementation of probabilistic short-circuit analysis by the Monte Carlo approach. In Conference Proceedings Power Industry Computer Application Conference, pages 373{379. IEEE, 1993.

 

[25] A.Bracale, P. Caramia, A. R. Di Fazio, and D. Proto. Probabilistic short circuit analysis in electric power distribution systems including distributed generation. In 8th Mediterranean Conference on Power Generation, Transmission, Distribution and Energy Conversion (MED-POWER 2012), pages 1-6.  IET, 2012.

 

[26] M. A. El-Kady. Probabilistic short-circuit analysis by monte carlo simulations. Power Engineering Review, PER-3(5):46-47, May 1983.

 

[27] C. A. Meneses, M. G. Echeverri, and J. R. Mantovani. Probabilistic algorithms for power load fow and short-circuit analysis in distribution networks with dispersed generation. J Control Autom Electr Syst, April 2013.

 

[28] U. A. Bordalo, A. B. Rodrigues, and M. G. Da Silva. A new methodology for probabilistic short-circuit evaluation with applications in power quality analysis. IEEE Transaction on Power Systems, Vol. 21, No. 2, pages 474{479, May 2006.

 

[29] R. Y. Rubinstein and D. P. Kroese. Simulation and the Monte Carlo Method. Wiley's Series in Probability and Statistics. John Wiley & Sons, Inc, New Jersey, USA, 2nd edition, February 2008.

 

[30] Oracle. http://docs.oracle.com/javase/6/docs/api/java/util/Random.html.

 

[31] Distribution test feeders. http://www.ewh.ieee.org/soc/pes/dsacom/testfeeders/index.html, 2010.

 

[32] R. N. Allan, R. Billinton, I. Sjarief, L. Goel, and K. S. So. A reliability test system for educational purposes - basic distribution system data and results. IEEE Transactions on Power Systems, 6(2):813{820, May 1991.

 

[33] IEEE std recommended practice for calculating ac short-circuit currents in industrial and commercial power systems, 2006.

 

[34] T. A. Short. Electric Power Distribution Handbook. CRC Press, 2004.

 

[35] R. C. Dugan. Reference guide - the open distribution system simulator (opendss). Technical report, EPRI Electric Power Research Institute, June 12013.

 

[36] R. Dugan and T. McDermott. An open source platform for collaborating on smart grid research. In IEEE, editor, Proc. IEEE Power Energy Soc. Gen. Meet (San Diego, 24-29 July 2011), pages 1-7. IEEE, July 2011.

 

[37] V. Ramachandran. Modeling of utility distribution feeder in opendss and steady state impact analysis of distributed generation. Master's thesis, West Virginia University, 2011.

 

[38] Alternative to export voltages and currents?, 2012.

 

[39] D. Montenegro, M. Hernandez, and G. A. Ramos. Real time opendss framework for distribution systems simulation and analysis. In IEEE, editor, Transmission and Distribution: Latin America Conference and Exposition (Montevideo, 3-5 September 2012), pages 1-7. IEEE, September 2012.

 

[40] R. C. Dugan. Defining faults, September 2010.

 

[41] P. Deitel and H. Deitel. Java How to program. Prentice Hall, Ninth edition, 2012.

 

[42] H. B. Funmilayo, J. A. Silva, and K. L. Butler-Purry. Overcurrent protection for the IEEE 34-node radial test feeder. IEEE Transactions on Power Delivery, 27(2):459-468, April 2012.

 

[43] W. H. Kersting. Radial distribution test feeders. In Power Engineering Society Winter Meeting, volume 2, pages 908{912, Columbus, January 2001. IEEE.

 

[44] M. Chow and L. S. Taylor. Analysis and prevention of animal-caused faults in power distribution sytems. IEEE Transactions on Power Delivery,  10(2):995-1001, April 1995.

bottom of page