Lina Alhmoud


  1. [1] L.A.A. Elhmoud, Reliability improvement of DFIG-based wind energy conversion systems by real-time control (East Lansing-MI: Michigan State University. Electrical Engineering, 2015).
  2. [2] G.J.W. Van Bussel and M.B. Zaaijer, Reliability, availability and maintenance aspects of large-scale offshore wind farms, a concepts study, Proceedings of MAREC 2001, 113(1), 2001, 119–126.
  3. [3] M. Shafiee and F. Dinmohammadi, An FMEA-based risk assessment approach for wind turbine systems: a comparative study of onshore and offshore, Energies, 7(2), 2014, 619–642.
  4. [4] F. Blaabjerg, K. Ma, and D. Zhou, Power electronics and reliability in renewable energy systems, IEEE International Symposium on Industrial Electronics (ISIE), IEEE, 2012.
  5. [5] S. Yang, D. Xiang, A. Bryant, P. Mawby, L. Ran, and P. Tavner, Condition monitoring for device reliability in power electronic converters: A review, IEEE Transactions on Power Electronics, 25(11), 2010, 2734–2752.
  6. [6] M. Weckert and J. Roth-Stielow, Lifetime as a control variable in power electronic systems, Emobility-Electrical Power Train, 2010. IEEE, 2010.
  7. [7] M.A. Eleffendi and C.M. Johnson, Application of Kalman filter to estimate junction temperature in IGBT power modules, IEEE Transactions on Power Electronics, 31(2), 2016, 1576–1587.
  8. [8] A. Bryant, S. Yang, P. Mawby, D. Xiang, L. Ran, P. Tavner, and P.R. Palmer, Investigation into IGBT dV/dt during turn-off and its temperature dependence, IEEE Transactions on Power Electronics, 26(10), 2011, 3019–3031.
  9. [9] E.R. Motto and J.F. Donlon, IGBT module with user accessible on-chip current and temperature sensors, in Twenty-Seventh Annual IEEE Applied Power Electronics Conference and Exposition (APEC), 2012, 176–181.
  10. [10] L. Alhmoud, Reliability improvement for a high-power IGBT in wind energy applications, IEEE Transactions on Industrial Electronics, 65(9), 2018, 7129–7137.
  11. [11] A. Wintrich, U. Nicolai, W. Tursky, and T. Reimann, Application manual power semiconductors (Germany: Semikron International GmbH, 2011).
  12. [12] C. Busca, R. Teodorescu, F. Blaabjerg, S. Munk-Nielsen, L. Helle, T. Abeyasekera, and P. Rodrıguez, An overview of the reliability prediction related aspects of high power IGBTs in wind power applications, Microelectronics Reliability, 51(9–11), 2011, 1903–1907.
  13. [13] R. Bayerer, T. Herrmann, T. Licht, J. Lutz, and M. Feller, Model for power cycling lifetime of IGBT Modules – various factors influencing lifetime, 5th International Conf. on Integrated Power Electronics Systems, Nuremberg, Germany, 2008, 1–6.
  14. [14] R.E. Kalman, A new approach to linear filtering and prediction problems, Journal of Basic Engineering, 82(1), 1960, 35–45.
  15. [15] A.K. Gautam and S. Majumdar, Parameter estimation of RC circuits using extended Kalman filter, International Journal of Advanced in Management, Technology and Engineering Sciences, 8(1), 2018, 83–91.
  16. [16] R. Bansal and S. Majumdar, Implementation of extended Kalman filter on a stochastic model of LPF, International Journal of Advanced in Management, Technology and Engineering Sciences, 7(12), 2017, 120–130.
  17. [17] M.J. Zadeh and S.H. Fathi, A new approach for photovoltaic arrays modeling and maximum power point estimation in real operating conditions, IEEE Transactions on Industrial Electronics, 64(12), 2017, 9334–9343.
  18. [18] L.W. Xu and K.Y. Qian, A fast method for lifetime estimation of blue light-emitting diode chips based on nonradiative recombination defects, IEEE Photonics Journal, 9(4), 2017, 1–9.
  19. [19] A. Gautam, S. Majumdar, Parameter estimation of diode circuit using extended Kalman filter, International Journal of Electronics and Communication Engineering, 12(9), 2018, 605–610.
  20. [20] L. Reggiani, L. Dossi, L. Barletta, and A. Spalvieri, Extended Kalman filter for MIMO phase noise channels with independent oscillators, IEEE Communications Letters, 22(6), 2018, 1200–1203.

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