Учебники / 0841558_16EA1_federico_milano_power_system_modelling_and_scripting

For the sake of completeness, the web pages of the software packages discussed above are:

Unfortunately, since most of these packages are free and open source, their web pages can move or, worse, disappear. The maintenance of some packages could be also discontinued in the future. However, one of the advantages of free and open source projects is that even if the original maintainer drops his project, the latest stable version will be always available and, in most cases, other developers will take care of that project. Thus, using Python and other open source projects ensures long-lasting software applications.

E.2 Links related to Power System Analysis

Other useful links related to power system analysis are:

•IEEE Task Force on Open Source Software for Power Systems, available at:

ewh.ieee.org/cmte/psace/CAMS taskforce/index.htm

•IEEE PES PEEC Digital Educational Resources, available at: www.ece.mtu.edu/faculty/ljbohman/peec/Dig Rsor.htm

•IEEE Power Systems Test Case Archive, available at:

www.ee.washington.edu/research/pstca/

• Power Systems Dynamic Test Cases Archive, available at:

psdyn.ece.wisc.edu/IEEE benchmarks/index.htm

References

[1]Acevedo, S., Linares, L.R., Mart´ı, J.R., Fujimoto, Y.: E cient HVDC Converter Model for Real Time Transient Simulation. IEEE Transactions on Power Systems 14(1), 166–171 (1999)

[2]Acha, E., Fuerte-Esquivel, C.R., Ambriz-P´erez, H., Angeles-Camacho, C.: FACTS - Modelling and Simulation in Power Networks. John Wiley & Sons, New York (2004)

[3]Achilles, S., P¨oller, M.: Direct Drive Synchronous Machine Models for Stability Assessment of Wind Farms. In: Proceedings of the 4th International

Workshop on Large-Scale Integration of Wind Power and Transmission Networks for O shore Wind Farms (October 2003)

[4]Ackermann, T.: Wind Power in Power Systems. John Wiley & Sons, Chichester (2005)

[5]Ajjarapu, V., Christy, C.: The Continuation Power Flow: a Tool for Steady State Voltage Stability Analysis. IEEE Transactions on Power Systems 7(1), 416–423 (1992)

[6]Ajjarapu, V., Lee, B.: Bifurcation Theory and its Application to Nonlinear Dynamical Phenomena in an Electrical Power System. IEEE Transactions on Power Systems 7(1), 424–431 (1992)

[7]Akhmatov, V., Knudsen, H., Nielsen, A.H.: Advanced Simulation of Windmills in the Electric Power Supply. International Journal of Electrical Power and Energy Systems 22(6), 421–434 (2000)

[8]Alsac, O., Bright, J., Prais, M., Stott, B.: Further Developments in LP-based Optimal Power Flow. IEEE Transactions on Power Systems 5(3), 697–711 (1990)

[9]Anderson, P.M., Bose, A.: Stability Simulation of Wind Turbine Systems. IEEE Transactions on Power Apparatus and Systems 102(12), 3791–3795 (1983)

[10]Anderson, P.M., Fouad, A.A.: Power System Control and Stability. WileyIEEE Press, New York (2002)

[11]Arabi, S., Kundur, P.: Stability Modelling of Storage Devices in FACTS Applications. In: Proceedings of the IEEE PES Summer Meeting, Edmonton, Alberta (July 2001)

[12]Arabi, S., Kundur, P., Sawada, J.H.: Appropriate HVDC Transmission Simulation Models for Various Power System Stability Studies. IEEE Transactions on Power Systems 13(4), 1292–1297 (1998)

[13]Arabi, S., Rogers, G.J., Wong, D.Y., Kundur, P., Lauby, M.G.: Small Signal stability Program Analysis of SVC and HVDC in AC Power Systems. IEEE Transactions on Power Systems 6(3), 1147–1153 (1991)

[14]Arrillaga, J., Arnold, C.P.: Computer Analysis Power Systems. John Wiley & Sons, New York (1990)

[15]Arrillaga, J., Arnold, C.P., Camacho, J.R., Sankar, S.: AC-DC Load Flow with Unit-Connected Generator-Converter Infeeds. IEEE Transactions on Power Systems 8(2), 701–706 (1993)

[16]Arrillaga, J., Smith, B.: AC-DC Power System Analysis. power and Energy Series. The Institution of Electrical Engineers, London (1998)

[17]Arrillaga, J., Watson, N.R.: Computer Modelling of Electrical Power Systems, 2nd edn. John Wiley & Sons, York (2001)

[18]Ascher, D., Martelli, A., Ravenscroft, A.: Python Cookbook, 2nd edn. O’Reilly, Sebastopol (2006)

[19]Astic, J.Y., Binhain, A., Jerosolimski, M.: The Mixed Adams-BDF Variable Step Size Algorithm to Simulate Transient and Long Term Phenomena in Power Systems. IEEE Transactions on Power Systems 9(2), 929–935 (1994)

[20]Athay, T., Podmore, R., Virmani, S.: A Practical Method for the Direct Analysis of Transient Stability. IEEE Transactions on Power Apparatus and

Systems 98(2), 573–584 (1979)

´

[21] Avalos, R.J., Ca˜nizares, C.A., Milano, F., Conejo, A.J.: Equivalency of Continuation and Optimization Methods to Determine Saddle-node and Limitinduced Bifurcations in Power Systems. IEEE Transactions on Circuits and Systems - I: Fundamental Theory and Applications 56(1), 210–223 (2009)

[22] Ayasun, S., Nwankpa, C.O., Kwatny, H.G.: Computation of Singular and Singularity Induced Bifurcation Points of Di erential-Algebraic Power System Model. IEEE Transactions on Circuits and Systems - I: Fundamental Theory and Applications 51(8), 1525–1538 (2004)

[23] Barcelo, W.R., Lemmon, W.W.: Standardized Sensitivity Coe cients for Power System Networks. IEEE Transactions on Power Systems 3(4), 1591– 1599 (1988)

[24] Bazaraa, M.S., Sherali, H.O., Shetty, C.M.: Nonlinear Programming: Theory and Algorithms, 2nd edn. John Wiley & Sons, New York (1993)

[25] Berg, G.L.: Power System Load Representation. Proceedings of the IEEE 120(3), 344–348 (1973)

[26] Bhattacharya, S., Dommel, H.W.: A New Commutation Margin Control Representation for Digital Simulation of HVDC System Transient. IEEE Transactions on Power Systems 3(3), 1127–1132 (1988)

[27] Bijwe, P.R., Kelapure, S.M.: Nondivergent Fast Power Flow Methods. IEEE Transactions on Power Systems 18(2), 633–638 (2003)

[28] Billington, R., Aborehaid, S., Fotuhi-Firuzabad, M.: Well-Being Analysis for HVDC Transmission Systems. IEEE Transactions on Power Systems 12(2), 913–918 (1997)

[29] Braz, L.M.C., Castro, C.A., Murari, C.A.F.: A Critical Evaluation of Step Size Optimization Based Load Flow Methods. IEEE Transactions on Power Systems 15(1), 202–207 (2000)

[30]Brenan, K.E., Campbell, S.L., Petzold, L.: Numerical Solution of Initial-Value Problems in Di erential-Algebraic Equations. SIAM, Philadelphia (1995)

[31]Brooke, A., Kendrick, D., Meeraus, A., Raman, R., Rosenthal, R.E.: GAMS, a User’s Guide, GAMS Development Corporation, 1217 Potomac Street, NW, Washington, DC 20007, USA (December 1998), http://www.gams.com

[32]Brueck, D., Tanner, S.: Python 2.1 Bible. Hungry Minds, Inc., New York (2006)

[33]Buresh, M.: Photovoltaic Energy Systems, Design and Installation. McGrawHill, New York (1983)

[34]Butcher, J.C.: Numerical Methods for Ordinary Di erential Equations. John Wiley & Sons, New York (2003)

[35]Ca˜nizares, C.A.: On Bifurcation Voltage Collapse and Load Modeling. IEEE Transactions on Power Systems 10(1), 512–522 (1995)

[36]Ca˜nizares, C.A.: Applications of Optimization to Voltage Collapse Analysis. In: Proceedings of the IEEE PES Summer Meeting, San Diego, USA (July 1998)

[37]Ca˜nizares, C.A.: Calculating Optimal System Parameters to Maximize the Distance to Saddle-Node Bifurcations. IEEE Transactions on Circuits and Systems - I: Fundamental Theory and Applications 45(3), 225–237 (1998)

[38]Ca˜nizares, C.A.: Modeling of TCR and VSI Based FACTS Controllers. ENEC, Milan, Italy, Tech. Rep. (December 1999)

[39]Ca˜nizares, C.A.: Voltage Stability Assessment: Concepts, Practices and Tools. IEEE/PES Power System Stability Subcommittee, Final Document, Tech. Rep. (August 2002), http://www.power.uwaterloo.ca

[40]Ca˜nizares, C.A., Alvarado, F.L.: Point of Collapse Methods and Continuation Methods for Large AC/DC Systems. IEEE Transactions on Power Systems 8(1), 1–8 (1993)

[41]Ca˜nizares, C.A., Alvarado, F.L., DeMarco, C.L., Dobson, I., Long, W.F.: Point of Collapse Methods applied to AC/DC Power Systems. IEEE Transactions on Power Systems 7(2), 673–683 (1992)

[42]Ca˜nizares, C.A., Alvarado, F.L., Zhang, S.: UWPFLOW Program, university of Waterloo (2006), http://www.power.uwaterloo.ca

[43]Ca˜nizares, C.A., Chen, H., Rosehart, W.: Pricing System Security in Electricity Markets. In: Proceedings of the Bulk Power systems Dynamics and Control V, Onomichi, Japan (September 2001)

[44]Ca˜nizares, C.A., Hranilovic, S.: Transcritical and Hopf Bifurcation in AC/DC Systems. In: Proceedings of the Bulk Power System Voltage Phenomena III - Seminar, Davos, Switzerland (August 1994)

[45]Ca˜nizares, C.A., Mithulananthan, N., Milano, F., Reeve, J.: Linear Performance Indices to Predict Oscillatory Stability Problems in Power Systems. IEEE Transactions on Power Systems 19(2), 1104–1114 (2004)

[46]Ca˜nizares, C.A., Rosehart, W., Berizzi, A., Bovo, C.: Comparison of Voltage Security Constrained Optimal Power flow Techniques. In: Proceedings of the IEEE PES Summer Meeting, Vancouver, BC, Canada (July 2001)

[47]Ca˜nizares, C.A., Rosehart, W., Quintana, V.: Costs of Voltage Security in Electricity Markets. In: Proceedings of the IEEE PES Summer Meeting, Seat-

tle, WA, USA (July 2000)

´ ´

[48] Carpentier, J.: Contribution ´a l’Etude du Dispatching Economique. Bulletin de la Soci´et´ Fran¸caise des Electriciens 3(6), 431–447 (1962)

[49]Carpentier, J.: Di erential Injection Method, a General Method for Secure and Optimal Load Flows. In: Proceedings of the Power Industry Computer Application (PICA), 255–262 (1973)

[50]Carpentier, J.: Optimal Power Flows. International Journal of Electrical Power and Energy Systems 1(1), 3–15 (1979)

[51]Castillo, E., Conejo, A.J., Pedregal, P., Garc´ıa, R., Alguacil, N.: Building and Solving Mathematical Programming Models in Engineering and Science. John Wiley & Sons, New York (2001)

[52]Chapman, S.J.: Electric Machinery and Power System Fundamentals. McGraw Hill, New York (2002)

[53]Chen, A.H.L., Nwankpa, C.O., Kawatny, H.G., Ming Yu, X.: Voltage Stability Toolbox: An Introduction and Implementation. In: Proceedings of the North American Power Symposium (NAPS), MIT, Cambridge (November 1996)

[54]Chen, Y., Shen, C.: A Jacobian-Free Newton-GMRES(m) Method with Adaptive Preconditioner and its Application for Power Flow Calculations. IEEE Transactions on Power Systems 21(3), 1096–1103 (2006)

[55]Chiang, H.D., Dobson, I., Thomas, R.J.: On Voltage Collapse in Electric Power Systems. IEEE Transactions on Power Systems 5(2), 601–611 (1990)

[56]Chiang, H.D., Flueck, A.J., Shah, K.S., Balu, N.: CPFLOW: A Practical Tool for Tracing Power System Steady-State Stationary Behavior due to Load and Generation Variations. IEEE Transactions on Power Systems 10(2), 623–634 (1995)

[57]Chiang, H.D., Wu, F.F., Varaiya, P.P.: Foundations of the Direct Methods for Power System Transient Stability Analysis. IEEE Transactions on Circuits and Systems - I: Fundamental Theory and Applications 34(1), 160–173 (1987)

[58]Chopra, S., Dexter, S.D.: Decoding Liberation: The Promise of Free and Open Source Software. Routledge Taylor & Francis Group, New York (2008)

[59]Chow, J.: Power System Toolbox (2002), http://www.eagle.ca/~cherry

[60]Chow, J.H., Cheung, K.W.: A Toolbox for Power System Dynamics and Control Engineering Education and Research. IEEE Transactions on Power Systems 7(4), 1559–1564 (1992)

[61]Chun, L., Qirong, J., Xiaorong, X., Zhonghong, W.: Rule-based Control for STATCOM to Increase Power System Stability. In: Proceedings of the PowerCon, (August 1998)

[62]Chun, W.J.: Core Python Programming, 1st edn. Prentice Hall, Inc., Upper Saddle River (2000)

[63]Coar, K.: Open Source Definition (2007), http://www.opensource.org/docs/osd

[64]Cole, S.: MatDyn. Katholieke Universiteit Leuven, Belgium, http://www.esat.kuleuven.be/electa/teaching/matdyn

[65]Conejo, A.J., Arroyo, J.M.: Optimal Response of a Thermal Unit to an Electricity Spot Market. IEEE Transactions on Power Systems 15, 1098–1104 (2000)

[66]Conejo, A.J., Arroyo, J.M.: Multiperiod Auction for a Pool-based electricity market. IEEE Transactions on Power Systems 17(4), 1225–1231 (2002)

[67]Cormen, T.H., Leiserson, C.E., Rivest, R.L., Stein, C.: Introduction to Algorithms. MIT Press and McGraw-Hill (2001)

[68]CYME International Inc., CYMSTAB - User’s Guide and Reference Manual, Burlington, MA (July 1994)

[69]Dahlquist, G.G.: A Special Stability Problem for Linear Multistep Methods. BIT Numerical Mathematics 3(1), 27–43 (1963)

[70]D’Albertanson, B., Hawkins, D.: An Integrated MV Distributed Generation Connection Planning Tool. In: Proceedings of the IET-CIRED SmartGrids for Distribution (June 2008)

[71]Das, D., Kothari, D.P., Kalam, A.: Simple and E cient Method for Load Flow Solution of Radial Distribution Networks. International Journal of Electrical Power and Energy Systems 17(5), 335–346 (1995)

[72]Davidenko, D.F.: On a New Method of Numerical Solution of Systems of Nonlinear Equations. Mathematical Reviews 14, 906 (1953)

[73]de Berg, M., van Kreveld, M., Overmars, M., Schwarzkopf, O.: Computational Geometry, Algorithms and Applications. Springer, Heidelberg (2000)

[74]Demmel, J.W.: Applied Numerical Linear Algebra. SIAM, Philadelphia (1997)

[75]Power System Engineering and Software, DigSilent, http://www.digsilent.de

[76]Dobson, I.: Observations on the Geometry of Saddle Node Bifurcation and Voltage Collapse in Electrical Power Systems. IEEE Transactions on Circuits and Systems - I: Fundamental Theory and Applications 39(3), 240–243 (1992)

[77]Dobson, I., Alvarado, F., DeMarco, C.L.: Sensitivity of Hopf Bifurcation to Power System Parameters. IEEE Decision and Control 3, 2928–2933 (1992)

[78]Dommel, H.W.: Digital Computer Solution of Electromagnetic Transients in Single and Multiphase Networks. IEEE Transactions on Power Apparatus and Systems 88(4), 388–398 (1969)

[79]Dommel, H.W.: Nonlinear and Time-Varying Elements in Digital Simulation of Electromagnetic Transients. IEEE Transactions on Power Apparatus and Systems 90(6), 2561–2567 (1971)

[80]Dommel, H.W., Tinney, W.F.: Optimal Power Flow Solutions. IEEE Transactions on Power Apparatus and Systems 87(10), 1866–1876 (1968)

[81]Drud, A.S.: GAMS/CONOPT, ARKI Consulting and Development, Bagsvaerdvej 246A, DK-2880 Bagsvaerd, Denmark (1996), http://www.gams.com/

[82]Dular, P., Kuo-Peng, P.: Three-Dimensional Modeling of Both Inductive and Capacitive E ects in Massive Inductors. IEEE Transactions on Magnetics 42(4), 743–746 (2006)

[83]FlowDemo.net, EEH - Power Systems Laboratory, Z¨urich, http://flowdemo.net

[84]El-Hawary, M.E.: Electrical Energy Systems. CRC Press, Boca Raton (2000)

[85]El-Samahy, I., Bhattacharya, K., Ca˜nizares, C., Anjos, M.F., Pan, J.: A Procurement Market Model for Reactive Power Services Considering System Security. IEEE Transactions on Power Systems 23(1), 137–149 (2008)

[86]OpenDSS, Electric Power Research Institute, http://sourceforge.net/projects/electricdss

[87]ENEL, http://www.enel.com

[88]Energy, G.: GE-PSLF Load Flow Data Export/Import File for PSLF Version 15.1, General Electric International, Inc., 1 River Road, Schenectady, NY 12345, USA (June 2005)

[89]Energy Development and Power Generating Committee of the Power Engineering Society, “IEEE Recommended Practice for Excitation System Models for Power System Stability Studies,” IEEE Std 421.5-1992, New York, Tech. Rep. (March 1992)

[90]Extended Transient-Midterm Stability Package: User’s Manual for the Power Flow Program, EPRI, ePRI computer code manual EL-2002-CCM (January 1987)

[91]European Wind Energy Association, Wind Force 12-A Blueprint to Archive 12% of the World’s Electricity from Wind Power by 2020, EWEA, Tech. Rep., 56 pages (2001)

[92]Eurostag, http://www.eurostag.be

[93]Evrenoso˜glu, C.Y., Abur, A., Akleman, E.: Three Dimensional Visualization and Animation of Traveling Waves in Power Systems. Electric Power Systems Research 77(7), 876–883 (2007)

[94]Feng, Z., Xu, W.: Fast Computation of Post-contingency System Margins for Voltage Stability Assessments of Large-scale Power Systems. IEE Proceedings on Generation, Transmission and Distribution 147(2), 76–80 (1990)

[95]Fiacco, A.V., McCormick, G.P.: Nonlinear Programming: Sequential Unconstrained Minimization. John Wiley & Sons, New York (1968)

[96]Fletcher, R.: Practical Methods of Optimization. John Wiley & Sons, New York (1987)

[97]Flueck, A.J., Chiang, H.D.: Solving the Nonlinear Power Flow Equations with an Inexact Newton Method Using GMRES. IEEE Transactions on Power Systems 13(2), 267–273 (1998)

[98]Fouad, A.A., Vittal, V.: Power System Transient Stability Analysis Using the Transient Energy Function Method. Prentice Hall, Upper Saddle River (1992)

[99]Fourer, R., Gay, D.M., Kernighan, B.W.: AMPL: A Modeling Language for Mathematical Programming, 2nd edn. Duxbury Press/Brooks/Cole Publishing Company, Boston (2002)

[100]Free Software Foundation (FSF), http://www.fsf.org/

[101]FreeGIS, http://www.freegis.org

[102]Friedl, J.E.F.: Mastering Regular Expressions, 2nd edn. O’Reilly, Sebastopol (2002)

[103]FSF Free Software Licensing and Compliance Lab, http://www.fsf.org/licensing/

[104]Gao, B., Morison, G.K., Kundur, P.: Voltage Stability Evaluation using Modal Analysis. IEEE Transactions on Power Systems 7(4), 1529–1542 (1992)

[105]Geography Markup Language, http://www.opengeospatial.org/standards/gml

[106]Gill, P.E., Murray, W., Wright, M.H.: Practical Optimization. Academic Press, London (1981)

[107]Gisin, B.S., Obessis, M.V., Mitsche, J.V.: Practical Methods for Transfer Limit Analysis in the Power Industry Deregulated Environment. In: Proceedings of the Power Industry Computer Application (PICA), pp. 261–266 (1999)

[108]Goderya, F., Metwally, A.A., Mansour, O.: Fast Detection and Identification of Islands in Power Systems. IEEE Transactions on Power Apparatus and Systems 99(1), 217–221 (1980)

[109]Gole, A.M., Sood, V.K.: A Static Compensator Model for use with Electromagnetic Transients Simulation Programs. IEEE Transactions on Power Systems 5(3), 1389–1407 (1990)

[110]G´omez-Exp´osito, A., Conejo, A.J., Ca˜nizares, C.: Electric Energy Systems - Analysis and Operation. CRC Press, Boca Raton (2008)

[111]Granville, S.: Optimal Reactive Dispatch through Interior Point Methods. IEEE Transactions on Power Systems 9(1), 136–146 (1994)

[112]Granville, S., Mello, J.C.O., Melo, A.C.G.: Application of Interior Point Methods to Power Flow Unsolvability. IEEE Transactions on Power Systems 11(4), 1096–1103 (1996)

[113]Grijalva, S., Sauer, P.W.: A Necessary Condition for Power Flow Power Jacobian Singularity Based on Branch Complex Flows. IEEE Transactions on Circuits and Systems - I: Fundamental Theory and Applications 52(7), 1406– 1413 (2005)

[114]Gross, C.A.: Power System Analysis, 2nd edn. John Wiley & Sons, Chichester (1986)

[115]Gu, W., Milano, F., Jang, P., Tang, G.: Hopf Bifurcations Induced by SVC Controllers: A Didactic Example. Electric Power Systems Research 77(3-4), 234–240 (2007)

[116]Guoyu, X., Galiana, F.D., Low, S.: Decoupled Economic Dispatch using the Participation Factors Load Flow. IEEE Transactions on Power Apparatus and Systems 104(6), 1377–1384 (1985)

[117]Hairer, E., Nørsett, S.: Solving Ordinary Di erential Equations I: Nonsti Problems, 2nd edn., Berlin, Germany. Springer Series in Computational Mathematics, vol. 8 (2000)

[118]Haley, P.H., Ayres, M.: Super Decoupled Loadflow with Distributed Slack Bus. IEEE Transactions on Power Apparatus and Systems 104(1), 104–113 (1985)

[119]Hansen, A.D., Michalke, G.: Modelling and Control of Variable speed Multipole Permanent Magnet Synchronous Generator Wind Turbine. Wind Energy 11(5), 537–554 (2008)

[120]Happ, H.H.: Optimal Power Dispatch: A Comprehensive Survey. IEEE Transactions on Power Apparatus and Systems PAS-96(3), 841–854 (1977)

[121]Haque, M.H.: A General Load Flow Method for Distribution Systems. Electric Power Systems Research 54(1), 47–54 (2000)

[122]Haque, M.H.: Improvement of First Swing Stability Limit by Utilizing Full Benefit of Shunt FACTS Devices. IEEE Transactions on Power Systems 19(4), 1894–1902 (2004)

[123]Hassan, I.D., Bucci, R.M., Swe, K.T.: 400 MW SMES Power Conditioning System Development and Simulation. IEEE Transactions on Power Electronics 8(3), 237–249 (1993)

[124]Hatziadoniu, C.J., Lobo, A.A., Pourboghrat, F., Daneshdoost, M.: A Simplified Dynamic Model of Grid-Connected Fuel-Cell Generators. IEEE Transactions on Power Systems 17(2), 467–473 (2002)

[125]Haug, E.J., Arora, J.S.: Applied Optimal Design. John Wiley & Sons, New York (1979)

[126]Heier, S.: Grid Integration of Wind Energy Conversion Systems. John Wiley & Sons, England (1998)

[127]Hetzler, S.M.: A Continuous Version of Newton’s Method. The College Mathematical Journal 28(5), 348–351 (1997)

[128]Hill, D.J.: Nonlinear Dynamic Load Models with Recovery for Voltage Stability Studies. IEEE Transactions on Power Systems 8(1), 166–176 (1993)

[129]Hingorani, G., Gyugyi, L.: Understanding FACTS: Concepts and Technology of Flexible AC Transmission Systems. IEEE Press, Los Alamitos (1999)

[130]Hirsch, P.: Extended Transient-Midterm Stability Program (ETMSP) Ver. 3.1: User’s Manual, EPRI, TR-102004-V2R1 (May 1994)

[131]Hiskens, I.A.: Power System Modeling for Inverse Problems. IEEE Transactions on Circuits and Systems - I: Regular Papers 51(3), 539–551 (2004)

[132]Ho man, K., Kunze, R.: Linear Algebra, 2nd edn. Prentice-Hall, Englewood Cli s (1971)

[133]Holdsworth, L., Wu, X.G., Ekanayake, J.B., Jenkins, N.: Direct Solution Method for Initialising Doubly-fed Induction Wind Turbines in Power System Dynamic Models. IEE Proceedings on Generation, Transmission and Distribution 150(3), 334–342 (2003)

[134]Huneault, M., Galiana, F.D.: A Survey of the Optimal Power Flow Literature. IEEE Transactions on Power Systems 6(2), 762–770 (1991)

[135]Iba, K., Suzuki, H., Egawa, M., Watanabe, T.: A Method for Finding a Pair of Multiple Load Flow Solutions in Bulk Power Systems. IEEE Transactions on Power Systems 5(2), 582–591 (1990)

[136]Iba, K., Suzuki, H., Egawa, M., Watanabe, T.: Calculation of Critical Loading Condition with Nose Curve using Homotopy Continuation Method. IEEE Transactions on Power Systems 6(2), 584–593 (1991)

[137]IEC, IEC 61968 Application Integration at Electric Utilities - System Interfaces for Distribution Management - Part 11: Common Information Model (CIM), draft

[138]IEC, IEC 61970 Energy Management System Application Program Interface (EMS-API) - Part 301: Common Information Model (CIM) Base, edition 1.0 (November 2003)

[139]IEC 61400-1, Wind Turbines - Part 1: Design Requirements, International Electrotechnical Commission, Geneva, Switzerland, Tech. Rep. (August 2005)

[140]IEEE Commettee Report, Reader’s Guide to SSR. IEEE Transactions on Power Apparatus and Systems 7(2), 150–157 (1992)

[141]IEEE Power System Engineering Committee Report, Terms, Definitions & Symbols for Subsynchronous Oscillations. IEEE Transactions on Power Apparatus and Systems 104(6), 1326–1334 (1985)

[142]IEEE Subsynchronous Resonance Task Force, First Benchmark Model for Computer Simulation of Subsynchronous Resonance. IEEE Transactions on Power Apparatus and Systems 96(5), 1565–1572 (1977)

[143]IEEE Task Force on Excitation Limiters, Recommended Models for Overexcitation Limiting Devices. IEEE Transactions on Energy Conversion 10(4), 706–713 (1995)

[144]IEEE Task Force on Excitation Limiters, Underexcitation Limiter Models for Power System Stability Studies. IEEE Transactions on Energy Conversion 10(3), 524–531 (1995)

[145]IEEE Working Group on Computer Modelling of Excitation Systems, Excitation System Models for Power System Stability Studies. IEEE Transactions on Power Apparatus and Systems 100(2), 494–509 (1981)