EMC Analysis Methods and Computational ModelsDescribes and illustrates various modeling techniques which are applicable to the area of EMC and includes material previously available only in international reports or other hard-to-obtain references. Electromagnetic topology, lumped-parameter circuit models, the radiation process, scalar diffraction theory for apertures, transmission line modeling, and models for shielding are among the topics discussed. The accompanying disk contains four programs based on the models developed in the text and can be used to calculate diverse transmission line responses. |
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Page vi
... Field Coupling 3.3.1.1 Weak - Coupling Approximations 3.3.1.2 Calculation of Mutual and Self - Inductances 71 3152 2 2 2 2 72 72 74 77 63 64 67 3.3.2 Electric Field Coupling 3.3.2.1 Weak - Coupling Approximations 81 vi CONTENTS.
... Field Coupling 3.3.1.1 Weak - Coupling Approximations 3.3.1.2 Calculation of Mutual and Self - Inductances 71 3152 2 2 2 2 72 72 74 77 63 64 67 3.3.2 Electric Field Coupling 3.3.2.1 Weak - Coupling Approximations 81 vi CONTENTS.
Page vii
... Coupling Approximations 81 888 82 83 86 3.3.2.2 Calculation of Mutual and Self - Capacitances 3.3.3 General Field Coupling at Low Frequencies 3.3.3.1 Example : Crosstalk Between Two Parallel Traces on a Printed Circuit Board 3.3.4 ...
... Coupling Approximations 81 888 82 83 86 3.3.2.2 Calculation of Mutual and Self - Capacitances 3.3.3 General Field Coupling at Low Frequencies 3.3.3.1 Example : Crosstalk Between Two Parallel Traces on a Printed Circuit Board 3.3.4 ...
Page xii
... FIELD COUPLING USING TRANSMISSION LINE THEORY 321 7.1 Introduction 321 7.2 Two - Wire Transmission Line 326 7.2.1 Derivation of the Telegrapher's Equations with an External Excitation 326 7.2.1.1 First Telegrapher's Equation 327 7.2.1.2 ...
... FIELD COUPLING USING TRANSMISSION LINE THEORY 321 7.1 Introduction 321 7.2 Two - Wire Transmission Line 326 7.2.1 Derivation of the Telegrapher's Equations with an External Excitation 326 7.2.1.1 First Telegrapher's Equation 327 7.2.1.2 ...
Page xxi
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Page xxv
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Contents
LOWFREQUENCY CIRCUIT MODELS | 3 |
INTRODUCTION TO MODELING AND | 4 |
References | 22 |
RADIATION MODELS FOR WIRE ANTENNAS | 113 |
Moments | 175 |
RADIATION DIFFRACTION AND SCATTERING | 183 |
Problems | 217 |
TRANSMISSION LINE THEORY | 223 |
EFFECTS OF A LOSSY GROUND ON TRANSMISSION | 395 |
References | 443 |
SHIELDED CABLES | 451 |
References | 501 |
SHIELDING | 505 |
547 | |
TABLES OF PHYSICAL CONSTANTS | 550 |
GROUNDING RESISTANCE PARAMETERS | 563 |
Common terms and phrases
admittance analysis analytical angle aperture approximate assumed behavior BLT equation braided cable calculated capacitance Chapter characteristic impedance charge components conductor consider current distribution current element current source defined determined developed dielectric discussed E-field EMI source equivalent circuit evaluated example excitation field expression field coupling Fourier transform frequency domain geometry given by Eq Green's function ground plane IEEE Trans illustrates incident field integral equation internal lightning line current located loop lossy low frequencies magnetic field matrix measured method multiconductor line numerical open-circuit penetration per-unit-length plane wave problem propagation constant radiated field radius reference conductor reflection coefficient resonances S₁ scattering shield shown in Figure solution spectrum surface telegrapher's equations termination Thévenin transfer impedance transient response transmission line transmission line model two-port network V₁ vector vertically polarized victim circuit voltage and current voltage source waveform wire Z₁ Z₂