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1 Numerical Methods of Electromagnetic Field Theory I (NFT I) Numerische Methoden der Elektromagnetischen Feldtheorie I (NFT I) / 8th Lecture / 8. Vorlesung.

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Presentation on theme: "1 Numerical Methods of Electromagnetic Field Theory I (NFT I) Numerische Methoden der Elektromagnetischen Feldtheorie I (NFT I) / 8th Lecture / 8. Vorlesung."— Presentation transcript:

1 1 Numerical Methods of Electromagnetic Field Theory I (NFT I) Numerische Methoden der Elektromagnetischen Feldtheorie I (NFT I) / 8th Lecture / 8. Vorlesung Universität Kassel Fachbereich Elektrotechnik / Informatik (FB 16) Fachgebiet Theoretische Elektrotechnik (FG TET) Wilhelmshöher Allee 71 Büro: Raum 2113 / 2115 D-34121 Kassel Dr.-Ing. René Marklein marklein@uni-kassel.de http://www.tet.e-technik.uni-kassel.de http://www.uni-kassel.de/fb16/tet/marklein/index.html University of Kassel Dept. Electrical Engineering / Computer Science (FB 16) Electromagnetic Field Theory (FG TET) Wilhelmshöher Allee 71 Office: Room 2113 / 2115 D-34121 Kassel

2 2 3-D FDTD – Derivation of the Discrete Equations / 3D-FDTD – Ableitung der diskreten Gleichungen The first two Maxwells Equations are in differential form / Die ersten beiden Maxwellschen Gleichungen lauten in Differentialform: In Cartesian Coordinates we find for the Curl operator applied to E and H / Im Kartesischen Koordinatensystem finden wir für den Rotationsoperator angewendet auf E und H:

3 3 3-D FDTD – Derivation of the Discrete Equations / 3D-FDTD – Ableitung der diskreten Gleichungen If we insert the last expressions into the first two Maxwells equations are in differential form read / Wenn wir die letzten Ausdrücke in the ersten beiden Maxwellschen Gleichungen in Differentialform einsetzen, erhalten wir: Six decoupled scalar equations! / Sechs entkoppelte skalare Gleichungen!

4 4 3-D FDTD – Derivation of the Discrete Equations / 3D-FDTD – Ableitung der diskreten Gleichungen If we insert the last expressions into the first two Maxwells equations are in differential form we read / Wenn wir die letzten Ausdrücke in die ersten beiden Maxwellschen Gleichungen in Differentialform einsetzen, erhalten wir:

5 5 3-D FDTD – Derivation of the Discrete Equations / 3D-FDTD – Ableitung der diskreten Gleichungen Constitutive equation for homogeneous isotropic materials / Konstituierende Gleichungen für homogene isotrope Materialien:

6 6 3-D FDTD – Derivation of the Discrete Equations / 3D-FDTD – Ableitung der diskreten Gleichungen A part of the discrete curl operator / Ein Teil des diskreten Rotationsoperators

7 7 2-D EM Wave Propagation – 2-D FDTD – TM and TE Case / 2D EM Wellenausbreitung – 2D-FDTD – TM- und TE-Fall 2-D TE Case / 2D-TE-Fall 2-D TM Case / 2D-TM-Fall Dual orthogonal grid system in space / Dual-orthogonales Gittersystem im Raum

8 8 2-D EM Wave Propagation – 2-D FDTD – TM Case/ 2D EM Wellenausbreitung – 2D-FDTD – TM-Fall 2-D TM Case / 2D-TM-Fall Two-dimensional staggered grid system in the 2- D TM case / Zweidimensionales versetztes Gittersystem im 2D-TM-Fall

9 9 Implementation of Boundary Conditions / Implementierung von Randbedingungen Boundary condition for a perfectly electrically conducting (PEC) material / Randbedingung für ein ideal elektrisch leitendes Material Plane wave boundary condition for a vertical incident plane wave / Ebene-Wellen-Randbedingung für eine vertikal einfallende ebene Welle PW BC / EW-RB PW BC / EW-RB PEC BC / IEL-RB PEC BC / IEL-RB Slit / Schlitz PEC BC / IEL-RB Plane wave excitation / Ebene-Wellen-Anregung

10 10 2-D EM Wave Propagation – 2-D FDTD – TM Case/ 2D EM Wellenausbreitung – 2D-FDTD – TM-Fall Ghost components which are allocated outside the simulation area / Geisterkomponenten, welche außerhalb des Simulationsgebietes liegen Ghost grid cells / Geistergitterzelle n Simulation area / Simulationsgebie t

11 11 2-D EM Wave Propagation – 2-D FDTD – TM Case/ 2D EM Wellenausbreitung – 2D-FDTD – TM-Fall Ghost grid cells / Geistergitterzelle n Simulation area / Simulationsgebie t Plane wave excitation / Ebene-Wellen-Anregung Slit / Schlitz

12 12 2-D TM FDTD – Diffraction on a Single Slit / 2D-TM-FDTD – Beugung an einem Spalt

13 13 2-D TM FDTD – Diffraction on a Single Slit / 2D-TM-FDTD – Beugung am Spalt Wave field movie of the H x field component / Wellenfeldfilm der H x -Feldkomponente Wave field movie of the H z field component / Wellenfeldfilm der H z -Feldkomponente Wave field movie of the E y field component / Wellenfeldfilm der E y -Feldkomponente

14 14 2-D TM FDTD – Diffraction on a Double Slit / 2D-TM-FDTD – Beugung am Doppelspalt

15 15 2-D TM FDTD – Diffraction on a Double Slit / 2D-TM-FDTD – Beugung am Doppelspalt Wave field movie of the H x field component / Wellenfeldfilm der H x -Feldkomponente Wave field movie of the H z field component / Wellenfeldfilm der H z -Feldkomponente Wave field movie of the E y field component / Wellenfeldfilm der E y -Feldkomponente

16 16 Photonic Crystals / Photonische Kristalle Joannopoulos, J. D., R. D. Meade, J. N. Winn: Photonic Crystals – Molding the Flow of Light. Princeton University Press, Princeton, 1995. Johnson, S. G.: Photonic Crystals: The Road from Theory to Practice. Kluwer Academic Press, 2001. Links: Photonic Crystals Research at MIT Homepage of Prof. Sajeev John, University of Toronto, Canada

17 17 2-D TM FDTD – Photonic Crystals / 2D-TM-FDTD – Photonische Kristalle

18 18 2-D TM FDTD – Photonic Crystals / 2D-TM-FDTD – Photonische Kristalle Wave field movie of the H x field component / Wellenfeldfilm der H x -Feldkomponente Wave field movie of the H z field component / Wellenfeldfilm der H z -Feldkomponente Wave field movie of the E y field component / Wellenfeldfilm der E y -Feldkomponente

19 19 2-D TM FDTD – Photonic Crystals / 2D-TM-FDTD – Photonische Kristalle Wave field movie of the H x field component / Wellenfeldfilm der H x -Feldkomponente Wave field movie of the H z field component / Wellenfeldfilm der H z -Feldkomponente Wave field movie of the E y field component / Wellenfeldfilm der E y -Feldkomponente

20 20 2-D TM FDTD – Photonic Crystals / 2D-TM-FDTD – Photonische Kristalle

21 21 2-D TM FDTD – Photonic Crystals / 2D-TM-FDTD – Photonische Kristalle

22 22 FDTD and FIT / FDTD und FIT FDTD : Finite Difference Time Domain / Finite Differenzen im Zeitbereich FIT : Finite Integration Technique / Finite Integrationstechnik FDTD Maxwells equations in differential form / Maxwellsche Gleichungen in Differentialform FIT Maxwells equations in integral form / Maxwellsche Gleichungen in Integralform FD approximation of spatial and temporal derivatives / FD- Approximation von räumlichen und zeitlichen Ableitungen FIT approximation of spatial and temporal integrals / FIT-Approximation von räumlichen und zeitlichen Integralen Central difference approximation / Zentrale Differenzen Approximation Mid point rule approximation of a 1-D integral / Mittelpunktsregel-Approximation eines 1D- Integrals

23 23 Definition of Material Cells / Definition der Materialzellen Material cell / Materialzelle

24 24 3-D FIT – Derivation of the Discrete Grid Equations / 3D-FIT – Ableitung der diskreten Gittergleichungen integration cell / -Integrationszelle Field component in the middle / Feldkomponente in der Mitte Approximation error / Approximationsfehler

25 25 3-D FIT – Derivation of the Discrete Grid Equations / 3D-FIT – Ableitung der diskreten Gittergleichungen integration cell / -Integrationszelle

26 26 3-D FIT – Derivation of the Discrete Grid Equations / 3D-FIT – Ableitung der diskreten Gittergleichungen Field component in the middle / Feldkomponente in der Mitte Approximation error / Approximationsfehler

27 27 3-D FIT – Derivation of the Discrete Grid Equations / 3D-FIT – Ableitung der diskreten Gittergleichungen integration cell / -Integrationszelle

28 28 3-D FIT – Derivation of the Discrete Grid Equations / 3D-FIT – Ableitung der diskreten Gittergleichungen integration cell / -Integrationszelle

29 29 3-D FIT – Derivation of the Discrete Grid Equations / 3D-FIT – Ableitung der diskreten Gittergleichungen integration cell / -Integrationszelle

30 30 3-D FIT – Derivation of the Discrete Grid Equations / 3D-FIT – Ableitung der diskreten Gittergleichungen integration cell / -Integrationszelle

31 31 3-D FIT – Derivation of the Discrete Grid Equations / 3D-FIT – Ableitung der diskreten Gittergleichungen

32 32 Dual-Orthogonal Grid System in Space / Dual-orthogonales Gittersystem im Raum 3-D / 3D Global node numbering / Globale Gitternummerierung

33 33 End of Lecture 8 / Ende der 8. Vorlesung

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