Python allows you to create convenient wizards for automating simulation processes or designing reusable components.ĬubeCAD is shared among several EM simulation engines targeted at different types of applications. Both the CAD modeler and data manager are tightly integrated with a powerful Python scripting environment. CubeCAD also features a versatile data management utility for analyzing, plotting and post-processing your simulation data. CubeCAD’s intuitive, mouse-driven, point-and-click tools let you quickly build sophisticated geometrical constructions either from the ground up or by combining imported external structures with native objects. At its core foundation you work with CubeCAD, a general-purpose parametric CAD modeling environment. Using EM.Cube, you can solve problems of different sizes and length scales, varying from a few microns in MEMS devices to several miles in large urban propagation scenes.ĮM.Cube has a highly integrated modular architecture. It features several distinct simulation engines that can solve a wide range of modeling problems such as electromagnetic radiation, scattering, wave propagation in various media, coupling, interference, signal integrity, field interactions with biological systems, etc.
EM.Cube ® is an industry-recognized simulation suite for electromagnetic modeling of RF system engineering problems. More information about CST and its products is available at. Hexahedral, tetrahedral, and surface meshing is available with expert systems and automatic mesh adaption.įeatures include robust optimization, cosimulation with bestinclass tools, powerful scripting capabilities, and userfriendly CAD import & export filters. Modules include general purpose time and frequency domain solvers, an integral equation solver for electrically large structures, and a fast sparameter solver for highly resonant structures. CST's customers operate in industries as diverse as Defense, Telecommunications, Automotive, Electronics, and Medical Equipment.ĬST's flagship product, CST MICROWAVE STUDIO, is a leading edge tool for the fast and accurate simulation of high frequency applications such as antennas, filters, couplers, planar and multilayer structures, SI and EMC. The extensive range of tools integrated in CST STUDIO SUITE enables numerous applications to be analyzed without leaving the userfriendly CST design environment and can offer additional security through cross verification. Its products allow you to characterize, design and optimize electromagnetic devices all before going into the lab or measurement chamber.
#CST MICROWAVE STUDIO DEFINE SURFACE BY EQUATION SOFTWARE#
"The latest additions to the asymptotic solver represent a huge applicability increase in the area of antenna placement and RCS simulation." CST - Computer Simulation Technology AGĬST develops and markets software for the simulation of electromagnetic fields. "The development of an asymptotic solver for CST MICROWAVE STUDIO was in response to many requests from our customers who need to study structures that were, because of their electrical size, simply out of reach of the previously available solver set," stated David Johns, VP Technical Support & Engineering, CST of America. This is interesting in many radar applications. This enables the simulation of an arbitrarily polarized wave incident, or an incident from different directions. Their properties can be set by means of an excitation list. Importing more than one farfield enables the computation of the coupling between several antennas, or of the total farfield including all antennas.įor scattering simulations, many excitation sources can be run in parallel. This makes the calculation of an installed antenna's farfield possible, even for an electrically very large structure such as a ship.
These farfields can be computed by other CST MWS solvers including the transient and frequency domain solvers. The asymptotic solver can now use farfields as excitation sources. With the latest CST STUDIO SUITE 2010 service pack, significant functional enhancements have been made available to our customers.
This solver is based on the shooting bouncing ray method. Computer Simulation Technology (CST) presents substantial improvements to the CST MICROWAVE STUDIO (CST MWS) Asymptotic Solver at MTT-S IMS 2010.Įngineers simulating electrically large structures, either for radar cross section analysis or for antenna placement studies, benefitted from the introduction of an asymptotic solver in CST MICROWAVE STUDIO version 2010.