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Introduction to CST MWS

Introduction to CST MWS. EKT 341 By Dr Soh Ping Jack Muhammad Ezanuddin bin Abdul Aziz Cheor Wai Loon Universiti Malaysia Perlis ( UniMAP ). OUTLINE. Introduction to CST MWS. Why 3D electromagnetic simulation tools are needed? 3D simulation methods CST MWS – Simulation example

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Introduction to CST MWS

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  1. Introduction to CST MWS EKT 341 By DrSoh Ping Jack Muhammad Ezanuddin bin Abdul Aziz CheorWai Loon Universiti Malaysia Perlis (UniMAP)

  2. OUTLINE Introduction to CST MWS • Why 3D electromagnetic simulation tools are needed? • 3D simulation methods • CST MWS – Simulation example • Summary

  3. INTRODUCTION Why 3D electromagnetic simulation tools are needed? • Radiating electric & magnetic fields are described by Maxwell´s equations • Analytical calculation by solving the Maxwell´s equations > exact or approximation • Analytical equations are derived for simple antenna structures > dipole, monopole, microstrip antennas

  4. INTRODUCTION Why 3D electromagnetic simulation tools are needed? • Present-day antennas are not simple structures > Complex antenna shapes > Dielectric material (phone covers, antenna radome) > User close to antenna –> absorption • Exact solutions do not exist • Solution is approximated by using computational electromagnetic tools • Numerical solution for the Maxwell´s equations • Do not give exact solution, accuracy depends on the calculation capacity • Arbitrary antenna shapes and materials can be solved

  5. INTRODUCTION Why 3D electromagnetic simulation tools are needed? • User / environment / phone material influence on antenna performance • Specific Absorption Rate (SAR) [W/kg] • Hearing Aid Compatibility (HAC) • Optimized antenna solution for every situation • Location • Size • Form

  6. INTRODUCTION Why 3D electromagnetic simulation tools are needed? Solution is visualized for the designer • Impedance matching • Radiation properties • Surface currents • SAR Prototype manufacturing and measurement rounds are replaced by simulations • Speeds up the design flow Final goal is an efficient antenna for a specific application

  7. INTRODUCTION 3D simulation methods Excitation signal in a certain location of the 3-dimensional space. • This is typically antenna feed assuming 50Ω impedance • Can be also plane wave e.g. In radar cross section simulations Structure is surrounded by boundaries • Open, electric, magnetic • Antenna simulations are typically made with open boundaries -> radiation goes through boundary -> far field approximations are based on the power through boundary Time or frequency domain calculation is made for the excitation • Idea is to calculate wave propagation in simulated structure • When steady-state situation is met -> solver stopped • Criteria can be e.g. The energy of back-reflected signal

  8. INTRODUCTION 3D simulation methods Mesh • Simulated structure is meshed = divided in small subdomains (cubes) or triangular parts • Mesh type depends on the solver type (time or frequency domain) • Mesh is dense in critical points • Surface of the conductors • Feed area • Small details • High permittivity material • High loss material

  9. INTRODUCTION 3D simulation methods Method of Moments, MoM • Full wave solution of Maxwell's integral equations in the frequency domain. • Well suited for models including conductive materials only. One famous simulator is IE3D by Zeland Finite Element Method, FEM • Frequency domain calculation, ideal for low loss and resonance –type structures. Commercial simulator HFSS by Ansoft Finite Difference Time Domain, FDTD • Time domain simulation, good for broadband antennas. Commercial simulators SEMCAD-X by Speag and MWS by CST. Nowadays trend is toward simulation tools with different solvers for different simulation problems !!!

  10. INTRODUCTION CST MWS Computer Simulation Technology CST • Several products for 3D simulation • Microwave Studio is for electromagnetic high frequency problems • FDTD method -> large simulations are relatively fast • Not ideal for high Q resonators • Lately included also frequency domain solver • Widely used by antenna manufacturer and academia

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  19. REFERENCES References • http://cst-simulation.blogspot.com/ • http://www.cst.com/content/products/mws/overview.aspx. • Swanson D.G., Hoefer W. J. R. “Microwave circuit modeling using electromagnetic field simulation

  20. QA Question and answer?

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