CST MICROWAVE STUDIO

CST MICROWAVE STUDIO®(CST® MWS®) is a specialist tool for the 3D EM simulation of high frequency components. CST MWS’ unparalleled performance is making it first choice in technology leading R&D departments. CST MWS enables the fast and accurate analysis of high frequency (HF) devices such as antennas, filters, couplers, planar and multi-layer structures and SI and EMC effects. Exceptionally user friendly, CST MWS quickly gives you an insight into the EM behavior of your high frequency designs. CST promotes Complete Technology for 3D EM. Users of our software are given great flexibility in tackling a wide application range through the variety of available solver technologies. Beside the flagship module, the broadly applicable Time Domain solver and the Frequency Domain solver, CST MWS offers further solver modules for specific applications. Filters for the import of specific CAD files and the extraction of SPICE parameters enhance design possibilities and save time. In addition, CST MWS can be embedded in various industry standard workflows through the CST STUDIO SUITE® user interface. CST MICROWAVE STUDIO® is seen by an increasing number of engineers as an industry standard development tool.


References in zbMATH (referenced in 12 articles )

Showing results 1 to 12 of 12.
Sorted by year (citations)

  1. Beltayib, Abduladeem; Afifi, Islam; Sebak, Abdel Razik: Excitation of the first high-order mode in ridge gap waveguide (2020)
  2. Ghaderi Aram, Morteza; Beilina, Larisa; Dobsicek Trefna, Hana: Microwave thermometry with potential application in non-invasive monitoring of hyperthermia (2020)
  3. Reddaf, Abdelmalek; Djerfaf, Fatima; Ferroudji, Karim; Boudjerda, Mounir; Hamdi-Chérif, Khaled; Bouchachi, Islem: Modeling of electromagnetic behavior of composite thin layers using genetic algorithm (2020)
  4. Morán-López, Ana; Córcoles, Juan; Ruiz-Cruz, Jorge A.; Montejo-Garai, José R.; Rebollar, Jesús M.: Electromagnetic scattering at the waveguide step between equilateral triangular waveguides (2016)
  5. Bottauscio, Oriano; Chiampi, Mario; Zilberti, Luca: A hybrid FE-BE method for SAR estimate in voxel based human models undergoing MRI (2014)
  6. Jain, S. K.; Sharma, Deepak; Senecha, V. K.; Naik, P. A.; Hannurkar, P. R.: Study of microwave components for an electron cyclotron resonance source: simulations and performance (2014) ioport
  7. Vandekerckhove, Steven; Vandewoestyne, Bart; De Gersem, Herbert; Van Den Abeele, Koen; Vandewalle, Stefan: Mimetic discretization and higher order time integration for acoustic, electromagnetic and elastodynamic wave propagation (2014)
  8. Bottauscio, Oriano; Chiampi, Mario; Zilberti, Luca: A boundary element approach to relate surface fields with the specific absorption rate (SAR) induced in 3-D human phantoms (2011)
  9. Maslovski, Stanislav I.; Morgado, Tiago A.; Silveirinha, Mário G.; Kaipa, Chandra S. R.; Yakovlev, Alexander B.: Generalized additional boundary conditions for wire media (2010)
  10. Johannes Hoffmann, Christian Hafner, Patrick Leidenberger, Jan Hesselbarth, Sven Burger: Comparison of electromagnetic field solvers for the 3D analysis of plasmonic nano antennas (2009) arXiv
  11. Bandyopadhyay, A. K.; Tomassoni, C.; Mongiardo, M.; Omar, A. S.: Generalized multipole technique without redundant multipoles (2005)
  12. Weiland, Thomas; Zagorodnov, Igor: Maxwell’s equations for structures with symmetries (2002)