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From Wikipedia, the free encyclopedia

WIPL-D is a computational electromagnetics software suite suitable for wide range of engineering applications such as antenna design, antenna placement, radar cross section analysis, EMC, antenna arrays and radomes, microwave circuits, low frequency problems.[1][2][3][4] The name reflects the basic mesh elements used within the method i. e. WIres and PLates, while D designates that material base is not limited to metals only but can as well include Dielectrics.[5]

The seminal work on the numerical kernel has been carried out by professor Branko Kolundzija and professor Antonije Djordjevic back in 1980.[6] In 1989, the first academic version of the software was released.[7] The code was sold in hundreds of copies as Lite version distributed through Artech House.[8] In 2002, the WIPL-D company was established for the commercial distribution of the code as spin-off of/from School of Electrical Engineering (University of Belgrade).[9]

Over the years, the customer base continued to grow worldwide and nowadays WIPL-D software has become an industry standard and a recognized brand in the engineering community.[10][11][12][13][14][15][16][17][18][19][20][21][22][1][2]

The kernel is based on the Method of Moments (MoM), with unique combination of higher order basis functions (HOBF) and quadrilateral mesh.[23] This numerical approach along with utilization of parallel computing, allows that the electrically very large and complex scenarios can be solved in reasonable time using everyday computational resources.[24][25][10]

  1. ^ a b "Electromagnetic Analysis - Full wave solutions to Maxwell's equations". Microwave Journal.
  2. ^ a b "Commercial Electromagnetic Modeling Codes". The Clemson University Vehicular Electronics Laboratory.
  3. ^ "WIPL-D d.o.o. - Company Profile". Microwave Journal.
  4. ^ "WIPL-D official web-site".
  5. ^ Kolundzija, B.M.; Ognjanovic, J.S.; Sarkar, T.K.; Harrington, R.F. (1996). "WIPL: a program for electromagnetic modeling of composite-wire and plate structures". IEEE Antennas and Propagation Magazine. 38 (1): 75–79. doi:10.1109/74.491300.
  6. ^ Kolundžija, Branko M. (2002). Electromagnetic modeling of composite metallic and dielectric structures. Boston: Artech House. ISBN 9780890063606.
  7. ^ Kolundzija, B M (September 1990). "General Entire-Domain Galerkin Method for Electromagnetic Modeling of Composite Wire and Plate Structures". 1990 20th European Microwave Conference: 853–858. doi:10.1109/EUMA.1990.336150.
  8. ^ Kolundzija, Branko M. (2005). WIPL-D microwave : circuit and 3D EM simulation for RF & microwave applications: software and users manual. Norwood, USA: Artech House. ISBN 9781580539654.
  9. ^ Kolundzija, B. (April 2011). "WIPL-D: From university software to company product". Proceedings of the 5th European Conference on Antennas and Propagation (EUCAP): 2844–2846.
  10. ^ a b "nVIDIA GPU Applications Catalogue".
  11. ^ "Characteristic mode analysis". Wikipedia. 29 November 2020.
  12. ^ Vandenbosch, Guy A.E.; Mioc, Francesca; Saporetti, Maria; Foged, L.J. (December 2016). "Bridging the Simulations-Measurements Gap: State of the Art [Meeting Reports]". IEEE Antennas and Propagation Magazine. 58 (6): 12–14. doi:10.1109/MAP.2016.2610189.
  13. ^ "Simulation Comparison between HFSS, CST and WIPL-D for Design of Dipole, Horn and Parabolic Reflector Antenna" (PDF).
  14. ^ "Comparison of software tools for the design of microwave components" (PDF).
  15. ^ "電磁場解析 - Electromagnetic field analysis". Wikipedia (in Japanese). 11 December 2020.
  16. ^ "Benchmark of Characteristic Mode Decomposition – Spherical Shell". Czech Technical University in Prague.
  17. ^ "Emerald - WIPL-D". www.msca-emerald.eu.
  18. ^ "Tools (A-Z) | AWR Software". www.awr.com. 16 April 2019.
  19. ^ "Mutual Coupling of Internal Transmit/Receive Pair in Launch Vehicle Fairing Model Using WIPL-D". ntrs.nasa.gov. NASA Technical Reports Server (NTRS).
  20. ^ "Interfacing WIPL-D with Mechanical CAD Software". ntrs.nasa.gov. NASA Technical Reports Server (NTRS).
  21. ^ "Computational Electromagnetic Tools Applied to the Polarimetric Phased Array Antenna". NOAA/NSSL.
  22. ^ "Partial list of software users". WIPL-D.
  23. ^ Kolundzija, B.M. (July 1999). "Electromagnetic modeling of composite metallic and dielectric structures". IEEE Transactions on Microwave Theory and Techniques. 47 (7): 1021–1032. doi:10.1109/22.775434.
  24. ^ Zoric, D. P.; Olcan, D. I.; Kolundzija, B. M. (July 2011). "Solving electrically large EM problems by using out-of-core solver accelerated with multiple graphical processing units". 2011 IEEE International Symposium on Antennas and Propagation (APSURSI): 1–4. doi:10.1109/APS.2011.6165482.
  25. ^ Zoric, Dusan P.; Olcan, Dragan I.; Kolundzija, Branko M. (April 2014). "Out-of-core solver using GPU-accelerated cluster for MoM-based EM code". The 8th European Conference on Antennas and Propagation (EuCAP 2014): 1176–1180. doi:10.1109/EuCAP.2014.6901982.
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