Prof. Jin's Research Group

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Courses

ECE 520

Fundamentals of electromagnetic principles and theorems, including, Maxwell's Equations and boundary conditions; Energy conservation and Poynting's theorem; Uniquess theorem, Reciprocity theorem, Duality principles and Equivalence principles; etc.. Applications of electromagnetic theory and theorems to the analysis of waveguide, cavity, antenna and scattering problems. Solution of boundary-value problems in Cartesian, cylindrical and spherical coordinates.

Course Webpage

ECE 540

Basic computational techniques for numerical analysis of electromagnetics problems, including the finite difference, finite element, and moment methods. Emphasis on the formulation of physical problems into mathematical boundary-value problems, numerical discretization of continuous problems into discrete problems, and development of rudimentary computer codes for simulation of electromagnetic fields in engineering problems using each of these techniques.

Course Webpage

Theses Advised

  1. S. S. Ni, “Hybridization of the Finite-Element Method and the Shooting-and-Bouncing-Ray Method for Scattering and Radiation from Large and Complex Targets,” Ph.D. Thesis, 1995 (presently at Northrop-Grumman).
  2. J. Chen, “Simulations of Electromagnetic Effect in Magnetic Resonance Imaging,” Ph.D. Thesis, 1998 (formerly at Motorola, presently at University of Houston).
  3. A. D. Greenwood, “Finite Element Method for Electromagnetic Scattering and Radiation from Complex Axisymmetric Structures,” Ph.D. Thesis, 1998 (presently at Air Force Research Laboratory).
  4. F. Ling, “Fast Electromagnetic Modeling of Multilayer Microstrip Antennas and Circuits,” Ph.D. Thesis, 2000 (formerly at Motorola and Neolinear, presently at Cadence).
  5. E. D. Branch, “A Higher-Order Finite Element Method for Computing the Radar Cross Section of Bodies of Revolution,” Ph.D. Thesis, 2000 (presently at Air Force Research Laboratory).
  6. D. Jiao, “Advanced Time-Domain Finite Element Method for Electromagnetic Analysis,” Ph.D. Thesis, 2001 (formerly at Intel, presently at Purdue University).
  7. J. Liu, “Higher-Order Finite Element–Boundary Integral Methods for Electromagnetic Scattering and Radiation Analysis,” Ph.D. Thesis, 2002 (formerly at Ansoft, presently at Sigrity).
  8. M. E. Kowalski, “Analysis and Optimization of Electromagnetic Phased-Arrays for Hyperthermia,” Ph.D. Thesis, 2002 (presently at SLAC, Stanford University).
  9. K. Donepudi, “Fast Higher-Order Solutions for Electromagnetic Scattering from Three-Dimensional Bodies,” Ph.D. Thesis, 2002 (presently at Intel Corporation).
  10. Ali E. Yilmaz, “Parallel FFT-Accelerated Time-Domain Integral Equation Solvers for Electromagnetic Analysis,” Ph.D. Thesis, 2005 (presently at UT-Austin).
  11. E. A. Dunn, “A Higher-Order Finite Element—Boundary Integral Method for Electromagnetic Scattering and Radiation from Bodies of Revolution,” Ph.D. Thesis, 2005 (presently at SAIC).
  12. Z. Lou, “Time-Domain Finite-Element Simulation of Large Antennas and Antenna Arrays,” Ph.D. Thesis, 2006.
  13. D. Correia, “A Higher-Order Perfectly Matched Layer for Open-Region, Waveguide, and Periodic Electromagnetic Problems,” Ph.D. Thesis, 2006.
  14. K. Mao, “Finite Element Analysis of Multilayer Transmission Lines and Circuit Components,” Ph.D. Thesis, 2007.
  15. Y.-J. Li, “Development and Application of the FETI-DPEM Algorithm for Analysis of Three-Dimensional Large-Scale Electromagnetic Problems,” Ph.D. Thesis, 2009.
  16. S. H. Lee, “Efficient Finite Element Electromagnetic Analysis for High-Frequency/ High-Speed Circuits and Multiconductor Transmission Lines ,” Ph.D. Thesis, 2009.
  17. R. Wang, “Incorporation of Feed-Network and Circuit Modeling into the Time-Domain Finite Element Analysis of Antenna Arrays and Microwave Circuits,” Ph.D. Thesis, 2009.
  18. Y. Su, “Calderόn Technique Based Integral Equation Methods in Computational Electromagnetics,” Ph.D. Thesis, 2011 (awarded by University of Electronic Science and Technology of China).
  19. X. L. Li, “Investigation of Explicit Finite-Element Time-Domain Methods and Modeling of Dispersive Media and 3D High-Speed Circuits,” Ph.D. Thesis, 2012.
  20. W. Yao, “Accurate, Efficient, and Stable Domain Decomposition Methods for Analysis of Electromechanical Problems,” Ph.D. Thesis, 2013.
  21. M. F. Xue, “Unified Conformal/Nonconformal Domain Decomposition Methods for Solving Large-Scale Multi-Region Electromagnetic Problems,” Ph.D. Thesis, 2014.
  22. H.-T. Meng, “Investigation of General-Purpose Computing on Graphics Processing Units and its Application to the Finite Element Analysis of Electromagnetic Problems,” Ph.D. Thesis, 2015.
  23. S. Yan, “Computational Modeling and Simulation of Nonlinear Electromagnetic and Multiphysics Problems,” Ph.D. Thesis, 2016.
  24. T. J. Lu, “Multiphysics Modeling and Simulation for Large-Scale Integrated Circuits,” Ph.D. Thesis, 2016.
  25. J. Guan, “Multi-Solver Schemes for Electromagnetic Modeling of Large and Complex Objects,” Ph.D. Thesis, 2017.
  26. Y. J. Zeng, “Modeling and Design of Near-Field Antennas with Periodic Structures,” Ph.D. Thesis, 2017.
  1. N. L. Lu, “Application of Adaptive Absorbing Conditions and Fast Multipole Method to Finite Element Solution of Three-Dimensional Scattering,” M.S. Thesis, 1995 (presently at Intel).
  2. S. T. Carolan, “Hybridization of the Method of Moments and the Shooting-and-Bouncing-Ray Method for Scattering from Large Geometries with Small Protrusions,” M.S. Thesis, 1997 (presently at OpenPort).
  3. Z. M. Feng, “Analysis of Shielded RF Coils Using Moment Methods,” M.S. Thesis, 1997 (continued Ph.D. study at UI, presently at MIT).
  4. K. Donepudi, “Spectral Lanczos Decomposition Method for Time- and Frequency-Domain Analysis of Maxwell’s Equations using FEM,” M.S. Thesis, 1997 (continued Ph.D. study at UI, presently at Intel Corporation).
  5. W. C. Gibson, “Incremental Length Diffraction Coefficients in XPATCH,” M.S. Thesis, 1998 (presently at deciBel Research, Inc.).
  6. M. E. Kowalski, “Modeling, Optimization, and Control of Electromagnetic Oncological Hyperthermia,” M.S. Thesis, 1999 (continued Ph.D. study at UI, presently at SLAC, Stanford University).
  7. E. Dunn, “Iterative Solvers and Preconditioners for Finite Element Analysis of Indoor Wave Propagation,” M.S. Thesis, 2000 (continued as a Ph.D. student at UI, presently at SAIC).
  8. A. E. Yilmaz, “FFT-Based Algorithms for Fast Analysis of Transient Electromagnetic Scattering,” M.S. Thesis, 2000 (continued as a Ph.D. student at UI, presently at UT-Austin).
  9. Z. Lou, “High-Order Finite Element Analysis of Periodic Structures,” M.S. Thesis, 2003 (continued as a Ph.D. student at UI, presently in China).
  10. A. R. Siripuram, “Finite Element Modeling of Microwave Breakdown in Air-Filled Waveguide Devices,” M.S. Thesis, 2004 (jointed SPAWAR).
  11. Y. Zhong, “The Domain Decomposition Method for Finite Element Analysis of Deep Cavities,” M.S. Thesis, 2004 (continued as a Ph.D. student at UI).
  12. R. Hu, “Higher-Order Finite Element Analysis of Anisotropic, Lossy, and Inhomogeneous Waveguides,” M.S. Thesis, 2004 (continued as a Ph.D. student at UI).
  13. Y. J. Li, “Vector Dual-Primal Finite Element Tearing and Interconnecting Method for Solving 3-D Electromagnetic Problems,” M.S. Thesis, 2005 (continued as a Ph.D. student at UI, presently at Cadence).
  14. R. Wang, “Finite Element-Boundary Integral Analysis of Electromagnetic Scattering by Discrete Bodies of Revolution,” M.S. Thesis, 2006 (continued as a Ph.D. student at UI, presently at ADI).
  15. X. L. Li, “Modeling of Electric and Magnetic, Anisotropic, Dispersive and Lossy Materials Using the Time-Domain Finite-Element Method,” M.S. Thesis, 2007 (continued as a Ph.D. student at UI, presently at Cadence).
  16. H. D. Pinto, “Implementation and Experiments with the Discontinuous Galerkin Method for Maxwell’s Equations,” M.S. Thesis, 2009 (Joined NASA Goddard Center).
  17. W. Yao, “Finite Element Analysis of 3D Electric Machine Problems,” M.S. Thesis, 2010 (continued as a Ph.D. student at UI).
  18. H. T. Meng, “Acceleration of Asymptotic Computational Electromagnetics Physical Optics – Shooting and Bouncing Ray (PO-SBR) Method Using CUDA,” M.S. Thesis, 2011 (continued as a Ph.D. student at UI).
  19. S. Yan, “Accuracy Improvement of the Second-Kind Fredholm Integral Equations in Computational Electromagnetics,” M.S. Thesis, 2012 (continued as a Ph.D. student at UI).
  20. P. Chen, “Application of the Time-Domain Finite-Element Method to Analysis of 3D Electric Machine Problems,” M.S. Thesis, 2012 (joined Analog Device, Inc.).
  21. T. J. Lu, “Signal Integrity Analysis of High-Speed Multilayer Interconnects Using the Finite Element Method,” M.S. Thesis, 2012 (continued as a Ph.D. student at UI).
  22. J. Guan, “OpenMP-CUDA Implementation of the Moment Method and Multilevel Fast Multipole Algorithm on Multi-GPU Computing Systems,” M.S. Thesis, 2013 (continued as a Ph.D. student at UI).
  23. Y. J. Zeng, “Full-Wave Analysis of Metallic Structures at Optical Frequencies,” M.S. Thesis, 2014 (continued as a Ph.D. student at UI).

Invited Talks

  1. RF Coil/Field Analysis for Magnetic Resonance Imaging (MRI),” The 6th Annual Little Rock Workshop on Advances in MR Engineering, Robert Allerton Conference Center, University of Illinois, Urbana, IL, June 2, 1997.
  2. New Developments of Hybrid Finite Element Methods for Scattering and Radiation by Complex Targets,” National Radio Science Meeting, Boulder, CO, Jan. 9-13, 1996.
  3. Hybridization in Computational Electromagnetics,” Annual Conference of Electro-magnetic Code Consortium (EMCC), May 1998.
  4. Hybridization in Computational Electromagnetics,” H-Infinity Meeting of the Defense Research Initiative Program, San Diego, CA, June 1998.
  5. Hybridization in Computational Electromagnetics,” Southwest Jiaotong University, China, Aug. 1998.
  6. Hybridization in Computational Electromagnetics,” (Plenary talk) International Conference on Microwave and Millimeter Wave Technology, Beijing, China, Aug. 1998.
  7. The Finite Element Method for Electromagnetic Field Computation,” Workshop on Computational Electromagnetics in Magnetic Resonance, College Station, TX, June 1998.
  8. Finite Element Method and FFT Based Methods in CEM,” 1998 Antenna Applications Symposium, Allerton Park, Monticello, IL, Sept. 1998.
  9. On the IE-AP Method,” Mission Research Corporation, Dayton, OH, April 1999.
  10. Computational Electromagnetics for Antenna Modeling,” Second H-Infinity Workshop of the Defense Research Initiative Program, Arlington, VA, June 1999.
  11. Computational Electromagnetics: A Brief Overview,” Air Force Research Laboratory, Dayton, OH, Sept. 8, 1999.
  12. Higher-Order Methods for Computational Electromagnetics,” Annual Conference of Electromagnetic Code Consortium (EMCC), St. Louis, MO, May 2000.
  13. Electromagnetic Analysis and Design in Magnetic Resonance Imaging,” Medtronic, Minneapolis, Minnesota, May 2000.
  14. Fast Algorithms for Electromagnetic Modeling of Microstrip Problems,” International Microwave Conference, Boston, June 2000.
  15. Fast Electromagnetic Modeling of Multilayer Microstrip Antennas and Circuits,” (Plenary talk) 5th International Symposium on Antennas, Propagation, and EM Theory, Beijing, China, Aug. 2000.
  16. Fast Electromagnetic Modeling of Multilayer Microstrip Antennas and Circuits,” Department of Electronic Engineering, City University of Hong Kong & MTT/AP/LEO Chapter, IEEE HK Section, Oct. 2000.
  17. Fast Algorithms for Electromagnetic Modeling of Microstrip Problems,” Third H-Infinity Workshop of the Defense Research Initiative Program, Annapolis, VA, Oct. 2000.
  18. Higher-Order Methods for Computational Electromagnetics,” Department of Electronic Engineering, City University of Hong Kong & MTT/AP/LEO Chapter, IEEE HK Section, March 28, 2001.
  19. Fast Electromagnetic Modeling of Multilayer Microstrip Antennas and Circuits,” Department of Electronic Engineering, Chinese University of Hong Kong, May 2, 2001.
  20. Higher-Order Methods for Computational Electromagnetics,” Anhui University, Hefei, China, May 10, 2001.
  21. Fast Electromagnetic Modeling of Multilayer Microstrip Antennas and Circuits,” University of Science and Technology of China, May 11, 2001.
  22. A Novel Hybridization of Higher-Order Finite Element and Boundary Integral Methods for Electromagnetic Scattering and Radiation Problems,” Annual Conference of Electromagnetic Code Consortium (EMCC), Kauai, Hawaii, May 28 – June 1, 2001.
  23. A Novel Hybridization of Higher-Order Finite Element and Boundary Integral Methods for Electromagnetic Scattering Problems,” Air Force Institute of Technology, Dayton, Ohio, November 8, 2001.
  24. A Novel Hybridization of Higher-Order Finite Element and Boundary Integral Methods for Electromagnetic Scattering Problems,” AFOSR Electromagnetics Workshop, San Antonio, TX, January 2002.
  25. Prediction of Radar Cross Section of Jet Engine Inlets,” Annual Conference of Electromagnetic Code Consortium (EMCC), Albuquerque, New Mexico, May 2002.
  26. Finite Element Analysis of Electromagnetic Scattering and Radiation Problems in the Time Domain,” Annual Conference of Electromagnetic Code Consortium (EMCC), Albuquerque, New Mexico, May 2002.
  27. The Fascinating World of Computational Electromagnetics,” ECE Undergraduate seminar, University of Illinois, October 2002.
  28. The Finite Element Method for Computational Electromagnetics: Recent Progress, Current Status, and Future Directions,” SIP/CEA/CEN Joint Forum--Use of High Performance Computing in Interdisciplinary Engineering, College Park, MD, November 6, 2002.
  29. Recent Advances in the Finite Element Method for Computational Electromagnetics,” Institute of Mathematical Science, National University of Singapore, February 25, 2003.
  30. The Finite Element Method for Computational Electromagnetics: Recent Progress, Current Status, and Future Directions,” Institute of Mathematical Science, National University of Singapore, February 27, 2003.
  31. Scattering Analysis of a Large Body with Deep Cavities,” Annual Conference of Electromagnetic Code Consortium (EMCC), Hampton, Virginia, May 2003.
  32. A Fully High-Order Finite-Element Simulation of Scattering by Deep Cavities,” Annual Conference of Electromagnetic Code Consortium (EMCC), Hampton, Virginia, May 2003.
  33. The Finite Element Method for Computational Electromagnetics: Recent Progress, Current Status, and Future Directions,” Stanford University, September 2003.
  34. Finite Element Analysis of Electromagnetic Scattering and Radiation Problems in the Time Domain,” AFRL, Kirtland AFB, Albuquerque, New Mexico, Feb. 2004.
  35. Computational Electromagnetics and Acoustics,” PET Annual Tech Review, Austin, TX, March 2004.
  36. The Finite Element Method for Computational Electromagnetics: Recent Progress, Current Status, and Future Directions,” Michigan State University, April 8, 2004.
  37. The Finite Element Method for Computational Electromagnetics: Recent Progress, Current Status, and Future Directions,” Ohio State University, April 22, 2004.
  38. CEA PET Annual Technical Review: Accomplishments and Future Vision,” Annual Conference of Electromagnetic Code Consortium (EMCC), Seattle, WA, May 2004.
  39. The Finite Element Method for Computational Electromagnetics: Recent Progress, Current Status, and Future Directions,” Southeast University, August 27, 2004.
  40. The Fascinating World of Computational Electromagnetics,” Nanjing University, August 31, 2004.
  41. The Fascinating World of Computational Electromagnetics,” Peking University, November 23, 2004.
  42. The Finite Element Method for Computational Electromagnetics: Recent Progress, Current Status, and Future Directions,” Peking University, November 24, 2004.
  43. Higher-Order Accurate Solutions of 3D Wave Scattering,” Peking University, November 25, 2004.
  44. A Quantitative Study of Luneberg Lens Reflectors,” UIUC ECE 590 Electromagnetics, Optics and Remote Sensing Seminar Series, January 2005.
  45. Computational Electromagnetics and Acoustics (CEA): KY4 Accomplishments and Future Vision,” PET Annual Tech Review, Columbus, OH, March 2005.
  46. Electromagnetic Simulation of Antennas and Arrays with Accurate Modeling of Antenna Feeds and Feed Networks,” Annual Conference of Electromagnetic Code Consortium (EMCC), Cincinnati, OH, May 2005.
  47. CEA PET Annual Technical Review: Serving DOD Users in Computational Electromagnetics and Acoustics,” Annual Conference of Electromagnetic Code Consortium (EMCC), Cincinnati, OH, May 2005.
  48. The Finite Element Method for Computational Electromagnetics,” Lockheed Martin Corporation, Sunnyvale, CA, November 2005.
  49. Development of Time-Domain Electromagnetic Simulation Techniques for Analysis of Broadband Antennas and Arrays,” AFOSR Electromagnetics Workshop, San Antonio, TX, January 10-13, 2006.
  50. CEA PET Annual Technical Review: Serving DOD Users in Computational Electromagnetics and Acoustics,” Annual Conference of Electromagnetic Code Consortium (EMCC), Tucson, AZ, May 2006.
  51. A Systematic Numerical Convergence Study of Typical Computational Electromagnetics Schemes,” Annual Conference of Electromagnetic Code Consortium (EMCC), Tucson, AZ, May 2006.
  52. Time-Domain Finite Element Method for Analysis of Broadband Antennas and Arrays,” Annual Conference of Electromagnetic Code Consortium (EMCC), Tucson, AZ, May 2006.
  53. Back to Reality: Solving Maxwell’s Equations in the Time Domain Using the Finite Element Method,” UIUC ECE 590 Electromagnetics, Optics and Remote Sensing Seminar Series, September 2006.
  54. A Fast Full-Wave Analysis of Large-Scale 3-D Photonic Crystal Problems Using the FETI-EM Method,” SPAWAR, San Diego, November 30, 2006.
  55. A Fast Full-Wave Analysis of Large-Scale 3-D Photonic Crystal Problems Using the FETI-EM Method,” University of New Mexico, December 1, 2006.
  56. A Fast Full-Wave Analysis of Large-Scale Phased-Array Antenna and Photonic Crystal Problems Using the FETI-EM Method,” AFOSR Electromagnetics Workshop, San Antonio, TX, January 9-11, 2007.
  57. CEA PET Annual Technical Review: Serving DOD Users in Computational Electromagnetics and Acoustics,” Annual Conference of Electromagnetic Code Consortium (EMCC), San Diego, CA, May 2007.
  58. A Fast Full-Wave Analysis of Large-Scale Phased-Array Antenna and Photonic Band-Gap Problems Using the FETI-EM Method,” Annual Conference of Electromagnetic Code Consortium (EMCC), San Diego, CA, May 2007.
  59. A Highly Efficient Domain Decomposition Method for the Finite Element Computation of Electromagnetic Fields: Application to Large-Scale Phased-Array Antennas and Photonic Crystal Problems,” IEEE AP/MTT Hong Kong Joint Chapter, City University of Hong Kong, January 18, 2008.
  60. Fast Time-Domain Computational Techniques and Their Applications in EMC,” 2008 International Symposium on Electromagnetic Compatibility Technology, Wuhan, China, January 2008.
  61. Back to Reality: Solving Maxwell’s Equations in the Time Domain Using the Finite Element Method,” IEEE AP/MTT Hong Kong Joint Chapter, City University of Hong Kong, February 26, 2008.
  62. The Fascinating World of Computational Electromagnetics,” University of Macau/IEEE Macau CAS/COM Joint-Chapter, February 28, 2008.
  63. Fast Time-Domain Computational Techniques and Their Applications in EMC,” IEEE AP/MTT Hong Kong Joint Chapter, City University of Hong Kong, March 4, 2008.
  64. The Fascinating World of Computational Electromagnetics,” University of Hong Kong, April 2, 2008.
  65. Electromagnetic Simulation of Large-Scale Photonic Crystal Problems,” University of Hong Kong, April 16, 2008.
  66. A Highly Efficient Domain Decomposition Method for the Finite Element Computation of Electromagnetic Fields: Application to Large-Scale Phased-Array Antennas and Photonic Crystal Problems,” Institute of High Performance Computing, Singapore, May 23, 2008.
  67. The Fascinating World of Computational Electromagnetics,” Shanghai Jiao Tong University, Shanghai, China, June 6, 2008.
  68. Back to Reality: Solving Maxwell’s Equations in the Time Domain Using the Finite Element Method,” Shanghai Jiao Tong University, Shanghai, China, June 7, 2008.
  69. “A Highly Efficient Domain Decomposition Method for the Finite Element Computation of Electromagnetic Fields: Application to Large-Scale Phased-Array Antennas and Photonic Crystal Problems,” Zhejiang University, Hangzhou, China, June 7, 2008.
  70. The Fascinating World of Computational Electromagnetics,” Beijing Institute of Technology, Beijing, June 12, 2008.
  71. Back to Reality: Solving Maxwell’s Equations in the Time Domain Using the Finite Element Method,” Beijing Institute of Technology, Beijing, June 18, 2008.
  72. Fast Time-Domain Computational Techniques and Their Applications in EMC,” Beijing Institute of Technology, Beijing, June 19, 2008.
  73. A Highly Efficient Domain Decomposition Method for the Finite Element Computation of Electromagnetic Fields: Application to Large-Scale Phased-Array Antennas and Photonic Crystal Problems,” Beijing Institute of Technology, Beijing, June 20, 2008.
  74. Finite Element Domain Decomposition Analysis of Large-Scale Electromagnetic Problems,” Northrop Grumman, Los Angles, CA, November 11, 2008.
  75. Finite Element Analysis of Phased-Array Antennas,” Global Chinese Microwave Summit, Hefei, China, November 16, 2008.
  76. Finite Element Analysis of Phased-Array Antennas,” Southeast University, Nanjing, November 19, 2008.
  77. Incorporation of Feed-Network and Circuit Modeling into the Time-Domain Finite Element Analysis of Antennas and Phased Arrays,” AFOSR Electromagnetics Workshop, San Antonio, TX, January 6-8, 2009.
  78. A Highly Efficient Domain Decomposition Method for the Finite Element Computation of Electromagnetic Fields: Application to Large-Scale Phased-Array Antennas and Photonic Crystal Problems,” Michigan State University, East Lansing, MI, March 18, 2009.
  79. A Novel, Highly Efficient Domain Decomposition Technique for the Finite Element Computation of Electromagnetic Fields: Application to Large-Scale Phased-Array Antennas and Photonic Crystal Problems,” University of Michigan, Ann Arbor, MI, April 22, 2009.
  80. Incorporation of Circuit and Lumped-Network Modeling into the Time-Domain Finite Element Analysis,” Annual Conference of Electromagnetic Code Consortium (EMCC), Oklahoma City, OK, May 2009.
  81. 25 Years of Progress and Future Challenges in Finite Element Methodologies and Applications,” University of Electronic Science and Technology in China, Chengdu, China, August 11, 2009.
  82. A Dual-field Domain Decomposition Method for Time-Domain Finite Element Computation of Electromagnetic Fields,” 19th International Conference on Domain Decomposition Methods, Zhanjiajie, Hunan, August 18, 2009.
  83. Novel, Highly Efficient Domain Decomposition Techniques for Solving Large-Scale Electromagnetic Problems,” University of North Carolina, Charlotte, NC, Sept. 23, 2009.
  84. The Fascinating World of Computational Electromagnetics,” North China Electric Power University, Beijing, April 17, 2010.
  85. Fast Time-Domain Computational Techniques and Their Applications in EMC,” North China Electric Power University, Beijing, April 17, 2010.
  86. Recent Progress in Computational Electromagnetics with a Focus on the Finite Element and Boundary Element Methods,” ECE 590I-CEME Tele-Seminar, University of Illinois, May 3 & 10, 2010.
  87. Novel, Highly Efficient Domain Decomposition Techniques for Finite Element Computation of Electromagnetic Fields,” University of Texas, Austin, TX, May 14, 2010.
  88. 25 Years of Progress and Future Challenges in Finite Element Methodologies and Applications,” A-Star Institute of High Performance Computing/IEEE AP/MTT Singapore Chapter, Singapore, June 29, 2010.
  89. Fast Time-Domain Computational Techniques and Their Applications in EMC,” A-Star Institute of High Performance Computing, Singapore, July 1, 2010.
  90. 25 Years of Progress and Future Challenges in Finite Element Methodologies and Applications,” Nanyang Technological University/IEEE AP/MTT Singapore Chapter, Singapore, July 2, 2010.
  91. Finite Element Analysis of Antennas and Phased Arrays in the Time Domain,” 34th Annual Antenna Applications Symposium, Allerton Conference Center, Monticello, IL, September 22, 2010.
  92. Novel, Highly Efficient Domain Decomposition Techniques for Finite Element Computation of Electromagnetic Fields,” University of Houston, Houston, TX, November 12, 2010.
  93. Prediction of Radar Cross Section of Jet Engine Inlets,” LibertyWorks, Rolls-Royce North American Technologies Inc., Indianapolis, IN, December 7, 2010.
  94. Time-Domain Finite Element Analysis of Electromagnetic Radiation and Scattering and Microwave Circuits,” 2011 IEEE International Workshop on Antenna Technology, Hong Kong, March 7-9, 2011.
  95. Finite Element Analysis of Antennas and Phased Arrays in the Time Domain,” City University of Hong Kong, March 10, 2011.
  96. On the V&V of the FETI-EM for Simulating the NRL Dual-Polarized Vivaldi Phased Array,” Annual Conference of Electromagnetic Code Consortium (EMCC), San Diego, CA, May 2011.
  97. Finite Element Analysis of Antennas and Phased Arrays in the Time Domain,” International Workshop on Computational Electromagnetics, Chengdu, June 5, 2011.
  98. Novel, Highly Efficient Domain Decomposition Techniques for Finite Element Computation of Electromagnetic Fields,” Nanjing University of Science and Technology, Nanjing, China, June 15, 2011.
  99. On the Challenges of Numerical Computation of Electromagnetic Scattering from a Large, Deep, and Perfectly Conducting Open Cavity,” USNC/URSI National Radio Science Meeting, Spokane, WA, July 4, 2011.
  100. Fundamentals and Advances in Full-Wave Characterization of Interconnects for PCB Signal Integrity Applications,” 20th Conference on Electrical Performance of Electronic Packaging and Systems (EPEPS), San Jose, CA, Oct. 2011 (Embedded Tutorial with D. Nagle and J. Tan).
  101. Finite Element Analysis of Antennas and Phased Arrays in the Time Domain,” A-Star Institute of High Performance Computing/IEEE AP/MTT Singapore Chapter, Singapore, January 13, 2012.
  102. Time-Domain Finite Element Method for Electromagnetic Analysis” (Plenary talk), 28th International Review of Progress in Applied Computational Electromagnetics, Columbus, OH, April 10-14, 2012.
  103. Recent Progress and Future Challenges in the Finite Element Method for Electromagnetic Analysis,” Department of Information Science and Electronic Engineering, Zhejiang University, June 29, 2012.
  104. Computational Electromagnetics: The Past, Present, and Future,” Department of Information Science and Electronic Engineering, Zhejiang University, July 2, 2012.
  105. Finite Element Analysis of Antennas and Phased Arrays in the Time Domain,” Advanced Communication Center, Tel-Aviv University, Israel, July 30, 2012.
  106. Domain Decomposition Methods for FEM Modeling of Large-Scale Phased Arrays,” Advanced Communication Center, Tel-Aviv University, Israel, July 30, 2012.
  107. Computational Electromagnetics: The Past, Present, and Future,” Department of School of Computer Science and Technology, Zhejiang University, December 14, 2012.
  108. From the Finite Element Method to the Discontinuous Galerkin Method,” International Workshop on Electromagnetic Theory, Modeling and Simulations, Chengdu, June 8, 2013.
  109. From the Finite Element Method to the Discontinuous Galerkin Method,” International Forum on New-Wave of Computational Electromagnetics and Application to Advanced Microelectronics, Zhejiang University, Hangzhou, June 14, 2013.
  110. Domain Decomposition Methods for the Finite Element Analysis of Large-Scale Electromagnetic Problems,” 2013 ACES International Workshop on Computational Electromagnetics Methods and Applications, Harbin, China, November 19, 2013.
  111. Computational Electromagnetics: The Past, Present, and Future,” Institute of Electronics, Chinese Academy of Science, Beijing, China, November 22, 2013.
  112. Domain Decomposition Methods for the Finite Element Analysis of Large-Scale Electromagnetic Problems,” 30th International Review of Progress in Applied Computational Electromagnetics, Jacksonville, FL, March 2014.
  113. Domain Decomposition Methods for the Finite Element Analysis of Large-Scale Electromagnetic Problems,” International Forum on New-Wave of Computational Electromagnetics and Application to Advanced Microelectronics, Zhejiang University, Hangzhou, May 2014.
  114. Domain Decomposition Methods for the Finite Element Analysis of Large-Scale Electromagnetic Problems,” International Workshop on Electromechanical Coupling, Xidian University, Xi’an, May 2014.
  115. Computational Electromagnetics: The Past, Present, and Future,” Hunan University, Changsha, China, November 25, 2014.
  116. Computational Electromagnetics: The Past, Present, and Future,” Jiangsu Normal University, Xuzhou, China, January 14, 2015.
  117. From FETD to DGTD for Computational Electromagnetics,” 31st International Review of Progress in Applied Computational Electromagnetics, Williamsburg, VA, March 2015.
  118. From FETD to DGTD for Computational Electromagnetics,” Southeast University, Nanjing, China, May 12, 2015.
  119. Domain Decomposition Methods for the Finite Element Analysis of Large-Scale Electromagnetic Problems,” Nanjing University of Science and Technology, Nanjing, China, May 13, 2015.
  120. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities,” International Workshop on Electromagnetic Theory, Modeling and Simulations, Chengdu, June 4, 2015.
  121. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities,” Zhejiang University, Hangzhou, June 11, 2015.
  122. The Finite Element Time-Domain Method for Computational Electromagnetics,” International Workshop on Electromechanical Coupling, Xidian University, Xi’an, June 15, 2015.
  123. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities,” (invited Speaker) IEEE MTT-S International Conference on Numerical Electromagnetic and Multiphysics Modeling and Optimization for RF, Microwave, and Terahertz Applications, Ottawa, Canada, August 11, 2015.
  124. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities,” Computational Science and Engineering Seminar, University of Illinois at Urbana-Champaign, September 23, 2015.
  125. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” Jiangsu Normal University, Xuzhou, China, January 7, 2016.
  126. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, Southeast University, Nanjing, China, January 8, 2016.
  127. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” 2nd IEEE International Conference on Computational Electromagnetics (ICCEM 2016), Guangzhou, China, February 23-25, 2016.
  128. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” Hangzhou University of Electronic Science and Technology, Hangzhou, China, February 26, 2016.
  129. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” Michigan State University, East Lansing, MI, April 4, 2016.
  130. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, University of Houston/IEEE APS Houston Chapter, TX, April 8, 2016.
  131. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” International Workshop on Electromechanical Coupling, Xidian University, Xi’an, June 5, 2016.
  132. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, Xidian University, Xi’an, June 6, 2016.
  133. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, Beihan University, Beijing, June 8, 2016.
  134. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” International Microwave Forum, Nanjing, June 12, 2016.
  135. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, Macquarie University, Sydney, September 12, 2016.
  136. Finite Element Modeling of Electromagnetic Properties of Highly Complex Composite Materials , ” Distinguished Lecture, EM-MTF, Rotorua, New Zealand, September 15, 2016.
  137. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” Shanghai Jiaotong University, Shanghai, October 8, 2016.
  138. Some Recent Developments in Numerical Modeling of Electromagnetic Fields , ” West Lake Symposium in Electromagnetic Sensing (WISES), Hangzhou, November 15, 2016.
  139. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, National Technological University, Singapore, February 23, 2017.
  140. Interface-Enriched Generalized Finite Element Method , Multi-Solver Schemes, and Dynamic hp-Adaptation for Computational Electromagnetics,” National University of Singapore, IEEE Singapore MTT/AP Chapter, February 24, 2017.
  141. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, IEEE Malaysia AP/MTT/EMC Joint Chapter, University of Technology in Malaysia, February 27, 2017.
  142. Multi-Physics Modeling in Computational Electromagnetics: Technical Challenges and Potential Solutions , ” International Workshop on High-Performance Computing for Electromagnetic and Multiphysics Modeling, Haning, Zhejiang, May 13, 2017.
  143. Interface-Enriched Generalized Finite Element Method , Multi-Solver Schemes, and Dynamic hp-Adaptation for Computational Electromagnetics,” International Workshop on Electromagnetic Theory, Modeling and Simulations, Chengdu, June 13, 2017.
  144. CEM Challenges in Multi-Physics Modeling and Simulation , ” International Review of Progress in Applied Computational Electromagnetics (ACES), Suzhou, China, August 2017.
  145. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, Harbin Institute of Technology, China, August 7, 2017.
  146. Multi-Physics Modeling in Computational Electromagnetics: Challenges and Opportunities , ” IEEE APS Distinguished Lecture, Chongqing University, China, August 10, 2017.