Description |
1 online resource (421 p.) |
Series |
Electromagnetic Waves Series |
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Electromagnetic Waves Series
|
Contents |
Intro -- Title -- Copyright -- Contents -- About the authors -- Foreword by Chris M. Hewitt -- Figure border colour key -- Internet link identification -- 1 Introduction -- 1.1 Introduction -- 1.2 Background -- 1.3 Assessment -- 1.4 Problem -- 1.6 Mesh analysis -- 1.7 Approach -- 1.8 Frequency analysis -- 1.9 Transient analysis -- 1.10 Conclusion -- 2 Cross coupling models -- 2.1 Introduction -- 2.2 Step-by-step derivation of the transmission line model -- 2.2.1 Definition of the model -- 2.2.2 Forward propagation -- 2.2.3 Rates of change -- 2.2.4 Line losses -- 2.2.5 Reflections |
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2.2.6 Two-way propagation -- 2.2.7 Boundary conditions -- 2.2.8 The transformation equations -- 2.2.9 Propagation velocity -- 2.2.10 Conclusion -- 2.3 The three-conductor model -- 2.3.1 Primitive capacitance -- 2.3.2 Primitive inductance -- 2.3.3 Primitive impedance -- 2.3.4 Primitive equations -- 2.3.5 Loop equations -- 2.3.6 Circuit equations -- 2.3.7 Definition of parameters -- 2.3.8 General circuit model -- 2.3.9 Relating the theories -- 2.4 The voltage injection transformer -- 2.4.1 Design -- 2.4.2 Characterisation test -- 2.4.3 Worksheet -- 2.4.4 Application |
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2.5 The current monitor transformer -- 2.5.1 Design -- 2.5.2 Assembly -- 2.5.3 Test set-up -- 2.5.4 Circuit model -- 2.5.5 Simulation -- 2.5.6 Definitive circuit model -- 2.5.7 Application -- 2.6 The signal link -- 2.6.1 Test rig -- 2.6.2 Test set-up -- 2.6.3 Current measurement -- 2.6.4 Test results -- 2.6.5 Lumped-parameter model -- 2.6.6 Distributed-parameter model -- 2.6.7 Computation -- 2.6.8 Modelling the peaks -- 2.6.9 Definitive circuit model -- 2.6.10 Applications -- 3 Multi-conductor models -- 3.1 Composite conductors -- 3.1.1 Introduction -- 3.1.2 Concept |
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3.1.3 Twin conductor assembly -- 3.1.4 Differential mode current -- 3.1.5 Component values -- 3.1.6 Circuit model -- 3.1.7 Conclusion -- 3.2 The multi-potential ground -- 3.2.1 Introduction -- 3.2.2 Assembly under review -- 3.2.3 Current distribution -- 3.2.4 Circuit model -- 3.2.5 Differential mode -- 3.2.6 Conclusion -- 3.3 The nature of shielding -- 3.3.1 Introduction -- 3.3.2 Section under review -- 3.3.3 Primitive currents -- 3.3.4 Partial voltages -- 3.3.5 Voltages along elemental conductors -- 3.3.6 Component values for coaxial cable -- 3.3.7 Susceptibility -- 3.3.8 External components |
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3.3.9 Circuit model -- 3.3.10 Conclusion -- 4 Antenna models -- 4.1 The radiation resistance -- 4.1.1 Introduction -- 4.1.2 The dipole antenna -- 4.1.3 Isolated conductor -- 4.1.4 Measurement -- 4.1.5 Modelling -- 4.1.6 Definitive model -- 4.1.7 Conclusion -- 4.2 The virtual conductor -- 4.2.1 Introduction -- 4.2.2 The single conductor -- 4.2.3 Relating L and C to Z -- 4.2.4 Twin conductor assembly -- 4.2.5 Circuit parameters -- 4.2.6 Conclusion -- 4.3 Cable characterisation -- 4.3.1 Introduction -- 4.3.2 Test method -- 4.3.3 Circuit modelling -- 4.3.4 Computations -- 4.3.5 Assessment |
Summary |
The technique described in this book can be used to analyse all the mechanisms involved in the propagation of Electromagnetic Interference (EMI), avoiding the need to invoke the complexities of electromagnetic computation. The book is aimed at electrical and electronic circuit design engineers and EMI/EMC design consultants |
Notes |
Description based upon print version of record |
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4.3.6 Conclusion |
Genre/Form |
Electronic books
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Form |
Electronic book
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Author |
Hewitt, Chris M
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ISBN |
9781839539541 |
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1839539542 |
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