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标题: EMC精品书籍分享贴 [打印本页]
作者: baobaozxc1234    时间: 2018-12-23 22:33
标题: EMC精品书籍分享贴
1.电磁兼容导论英文版7 n# g' E' e  L( g
《电磁兼容导论》是机械工业出版社2006年出版的图书,由保罗编著。本书全面系统地讲述电碰兼容(EMC)的基本原理及其应用。, y7 ?2 @% ]( w; F; P
本书全面系统地讲述电碰兼容(EMC)的基本原理及其应用,包括EMC概论、电子系统的EMC要求、电磁场理论、传输线、天线、天件的非理想性能、信号谱、辐射发射和敏感度、传导发射和传导敏感度、串扰、屏蔽、静电放电、
EMC
的系统设计等内容。本书讲述深入浅出,配合典型例证,实用性强。可作为高等院校相关专业电磁容课程教材,也可供EMC设计开发人员参考。" t1 P0 q" [4 i1 B% {* ~
7 v3 j. [" D/ s/ _* R3 a
Contents
6 F# E4 C! ]0 wPreface xvii
8 c3 u! }- q/ ]6 p, _0 Q% A& h1 Introduction to Electromagnetic Compatibility (EMC) 1
0 k! ^2 \( d  ]: L% D1.1 Aspects of EMC 3! q0 Z6 s3 L) m( e4 A
1.2 History of EMC 10% O1 |  K+ c; ]- `/ Q+ G
1.3 Examples 121 B$ V& v/ e) f0 j
1.4 Electrical Dimensions and Waves 14, |+ D- C4 e( W- o# i/ M0 T* o
1.5 Decibels and Common EMC Units 23+ N$ }0 N- O9 y% F9 T. l" o/ U2 `4 `
1.5.1 Power Loss in Cables 32
# R1 `6 \* E' I, J7 M1.5.2 Signal Source Specification 37
8 q7 O+ }+ l0 T! V+ _$ o! x" w  QProblems 432 Z' l& h* c! H7 v
References 48
0 ~# t2 \6 r" \2 EMC Requirements for Electronic Systems 49
" A4 Y  J% k2 s2 T0 ?' Q! Y2.1 Governmental Requirements 50
+ I$ R/ ^( Q7 b; {+ O$ o! M2.1.1 Requirements for Commercial Products Marketed' \( b5 Y7 Z$ h* Y* g4 m
in the United States 50
# f  M- C6 {# M: W: R2.1.2 Requirements for Commercial Products Marketed. P( H, K+ o; ]$ w, n& C: h
outside the United States 559 F+ k- G: U- Y2 E; |6 t' o* d- }
2.1.3 Requirements for Military Products Marketed in the. i* ^+ }5 c5 w8 h! ?* L3 K
United States 60# H' d' \* s" Q* a7 {5 ~
2.1.4 Measurement of Emissions for Verification of Compliance 62) L' Y% P2 u. h" b! z- }
2.1.4.1 Radiated Emissions 64
( c! v6 S* d0 P! F& b2.1.4.2 Conducted Emissions 676 ]* |/ H: ~) g9 e, o: ]
2.1.5 Typical Product Emissions 72
3 E5 ~' _8 Z$ E, W" A7 v) o2.1.6 A Simple Example to Illustrate the Difficulty in Meeting
8 ]7 j4 j; n) Y. V. i- d% ythe Regulatory Limits 782 R" v9 s0 K) o! e3 \/ Q  U# e2 ~
vii; i$ i/ c( V. a& @0 I. \2 a3 {2 i
2.2 Additional Product Requirements 79
% p2 P2 x& y( e; A; b7 Y$ m0 m2.2.1 Radiated Susceptibility (Immunity) 81
5 r) S7 V" f5 G/ i  A2.2.2 Conducted Susceptibility (Immunity) 819 X7 u& e" A( I: j% X# N
2.2.3 Electrostatic Discharge (ESD) 81/ I+ q, {9 ]0 _: N7 ]0 ?5 j! \
2.2.4 Requirements for Commercial Aircraft 82
8 {0 `/ D* H- W* z% M+ d2.2.5 Requirements for Commercial Vehicles 82
2 F- ~9 O+ Z# G  U) B' I. Q2.3 Design Constraints for Products 825 L) G7 u' a, p  }: T/ R
2.4 Advantages of EMC Design 842 l4 |9 B3 [0 \8 K* j) Y2 o4 u
Problems 86: K3 ]  e: b* ]+ V# X! N
References 89/ s0 u' W* j5 l  J
3 Signal Spectra—the Relationship between the Time Domain and
4 h( r: W' _) A. @: s1 l2 r7 h% Xthe Frequency Domain 91
' D* F2 \* A- V4 c. D, N$ `  ~5 U3.1 Periodic Signals 91
8 t7 Z5 ~8 R: m3.1.1 The Fourier Series Representation of Periodic Signals 94
1 s0 ]# f& Y+ k4 V' u, k( }" e3 \* K' t3.1.2 Response of Linear Systems to Periodic Input Signals 1043 m& G3 J- C0 n3 R& j+ A: F
3.1.3 Important Computational Techniques 111* _6 Z- P# l* ?* f) m% Y
3.2 Spectra of Digital Waveforms 118  ]& P, m8 T( S( i) C
3.2.1 The Spectrum of Trapezoidal (Clock) Waveforms 118
! R* h/ G6 v  A3.2.2 Spectral Bounds for Trapezoidal Waveforms 122
6 ~7 {& k5 S' p. @0 y! E3.2.2.1 Effect of Rise/Falltime on Spectral Content 123% d: ~) a: \2 t; A
3.2.2.2 Bandwidth of Digital Waveforms 132! B( Q! u" N' s9 k5 [  C8 z( o
3.2.2.3 Effect of Repetition Rate and Duty Cycle 1368 ?' P) x; c; \, O# o2 y" X
3.2.2.4 Effect of Ringing (Undershoot/Overshoot) 137
- D7 {5 T% i) Q; k0 B4 ~! n3.2.3 Use of Spectral Bounds in Computing Bounds on the
4 n, m2 F  U' C0 s5 z/ ]Output Spectrum of a Linear System 140
! |3 I2 O* g. I+ X- a: ~3.3 Spectrum Analyzers 1427 S2 Z6 r& I( Y4 ]% C  r0 I2 B9 P
3.3.1 Basic Principles 1422 x# v! D  ?4 l- v1 x
3.3.2 Peak versus Quasi-Peak versus Average 146
" A; |( C3 B( f2 A. Z/ \! P( Z  P( w  j0 M) d$ G- F4 P
3.4 Representation of Nonperiodic Waveforms 1481 X) c4 C: b* R7 g0 Y* y
3.4.1 The Fourier Transform 1488 J0 Y6 G6 G1 S) |
3.4.2 Response of Linear Systems to Nonperiodic Inputs 151, e0 l2 `2 y1 L( g5 d1 V
3.5 Representation of Random (Data) Signals 151: f2 ?/ B) E8 L. g( }  w1 _+ X
3.6 Use of SPICE (PSPICE) In Fourier Analysis 155
# Z- v( C1 d) A  q: N) TProblems 167
; }3 `; q- F$ DReferences 175- W! h* y: X# a& e
4 Transmission Lines and Signal Integrity 177. c% E: f* N) C3 K! d
4.1 The Transmission-Line Equations 181! q" i) T* ?/ k% w2 u5 l
4.2 The Per-Unit-Length Parameters 184
$ S1 ^, f) D# ~; `8 q4.2.1 Wire-Type Structures 186
9 g( h6 y# [) H! l5 }viii CONTENTS) N8 k5 ?8 F# W, S5 V
4.2.2 Printed Circuit Board (PCB) Structures 199
7 m. F% `+ d+ }/ S4.3 The Time-Domain Solution 204
3 w, B, M/ O8 {7 M9 U( I  {2 }# q: k3 @! o7 R" a
4.3.1 Graphical Solutions 2047 E  s+ L1 Y/ F
4.3.2 The SPICE Model 2181 e- Q" i7 m, |0 E) o; \# i
4.4 High-Speed Digital Interconnects and Signal Integrity 2255 w1 N- f$ u3 S; ?
4.4.1 Effect of Terminations on the Line Waveforms 2306 `1 X% e5 f2 y5 m9 E& f' ^3 w) Z) N
4.4.1.1 Effect of Capacitive Terminations 2331 ~. ]' S% \0 e/ Y- `1 O
4.4.1.2 Effect of Inductive Terminations 2369 P$ G: e3 [# k; a2 l
4.4.2 Matching Schemes for Signal Integrity 238! `: q. Q: P. i# s" I+ b9 |5 N0 o
4.4.3 When Does the Line Not Matter, i.e., When is Matching
2 Z3 j; @* s. z# J6 b/ N2 [" DNot Required? 244
9 [' b" `8 z$ W, {( y4.4.4 Effects of Line Discontinuities 247$ ?2 M, T, s/ S" h5 A0 L( ]
4.5 Sinusoidal Excitation of the Line and the Phasor Solution 260
. _8 Q! i9 ^& G" p$ s4.5.1 Voltage and Current as Functions of Position 261
! s6 D1 C+ a1 i8 g+ c; N' `) @% }4.5.2 Power Flow 269- u- P  K9 j. N9 x
4.5.3 Inclusion of Losses 270
8 o$ |" B7 ~( A! |0 a( Z4.5.4 Effect of Losses on Signal Integrity 273* l0 D# H3 R5 p! t5 k. d; s+ |
4.6 Lumped-Circuit Approximate Models 2831 s+ U/ m5 x- s& `: X( w( D% i
Problems 287
) w7 B+ H8 H; D  v  IReferences 297
: @( ]2 z& {: l7 c9 h# _5 Nonideal Behavior of Components 2990 C1 G: b. G$ K4 U8 \) k* {8 H
5.1 Wires 300
  \; `+ l2 P& B; t6 a! R5.1.1 Resistance and Internal Inductance of Wires 3046 A5 |) s2 N1 H
5.1.2 External Inductance and Capacitance of Parallel Wires 308# ~( @+ }! x  u9 ~; l
5.1.3 Lumped Equivalent Circuits of Parallel Wires 309
! J2 j5 H- R# R5.2 Printed Circuit Board (PCB) Lands 3126 m3 _4 }5 v( W4 i; v
5.3 Effect of Component Leads 3157 X( l$ e, h, a! ^- n& ~* F3 g6 e
5.4 Resistors 317
& u% ?! v+ U# q* p6 j8 ?$ @5.5 Capacitors 325. |: s$ D; l# R+ t8 m1 a% a
5.6 Inductors 336. d) y% Q/ b. G+ a; E
5.7 Ferromagnetic Materials—Saturation and Frequency Response 3404 n$ T( N0 Y. J! P5 f; i
5.8 Ferrite Beads 3430 r& e2 A1 q, s8 {
5.9 Common-Mode Chokes 346
+ D1 L$ x6 q9 Y' v* L5.10 Electromechanical Devices 352, G) l% G9 }) `/ D( Q7 ]+ [8 B
5.10.1 DC Motors 352
* S# m- n  _5 L$ A) y5.10.2 Stepper Motors 355
$ ?6 H: C& O7 M; y9 M% o5.10.3 AC Motors 355+ e* w6 S; s! K# R
5.10.4 Solenoids 3561 q8 v) c6 Q' Y. ]* n
5.11 Digital Circuit Devices 357/ G/ L( i, m9 i! F) ?7 |9 S
5.12 Effect of Component Variability 3583 a- D4 |' {/ n  D* W
5.13 Mechanical Switches 359
" h% c3 E" p4 D8 q4 S9 ^! O5.13.1 Arcing at Switch Contacts 3605 D# ^: [! I7 V  c
CONTENTS ix# H/ ]* L3 }& k0 s- [  o6 C: A$ u6 y
5.13.2 The Showering Arc 363
, V6 s$ V8 r/ f5.13.3 Arc Suppression 364$ i* m1 b) P1 m& q/ O. b; F
Problems 369
+ b7 u: p9 F  \- l% y$ EReferences 375
3 ?( N8 @8 Q7 k6 g6 Conducted Emissions and Susceptibility 377
* Z) r7 i* N3 V3 D8 h6 ?; Z$ ?0 q6.1 Measurement of Conducted Emissions 378
+ u, p3 F6 i  v4 u! f6.1.1 The Line Impedance Stabilization Network (LISN) 3798 \3 V) I, _6 n% j* i
6.1.2 Common- and Differential-Mode Currents Again 381
) C1 S: O& U2 C0 k$ Q$ e6 o6.2 Power Supply Filters 385% m1 t# g4 z) {. g
6.2.1 Basic Properties of Filters 3853 J, ?/ c. M/ u
6.2.2 A Generic Power Supply Filter Topology 388" K+ S% ?* j! @3 c
6.2.3 Effect of Filter Elements on Common- and
0 M( w1 M" t8 s- }8 L7 n3 o+ [Differential-Mode Currents 390: I% y% c: F* n6 ?3 R* _) O' @0 U
6.2.4 Separation of Conducted Emissions into Commonand
/ S! `! w; |; X( T- \) C& t3 E( u! EDifferential-Mode Components for
, Q4 @/ X* n% I( @1 DDiagnostic Purposes 396
0 }0 q3 M2 {2 K/ S* i% D& a# J6.3 Power Supplies 401
+ W0 X2 L8 T- A! F5 G6.3.1 Linear Power Supplies 405
) R+ x  ?) j# g8 g9 a; R& O6.3.2 Switched-Mode Power Supplies (SMPS) 406
& z& R8 _2 C1 k4 S2 p6.3.3 Effect of Power Supply Components on Conducted$ v/ V# X* W" u2 Q
Emissions 409! r" L6 O* p4 P9 A7 V% K
6.4 Power Supply and Filter Placement 414: d/ E) Q" D/ m* z$ M0 b- b
6.5 Conducted Susceptibility 416! y' P8 S7 U7 K% }
Problems 416! d$ p# w! ^9 [0 ]
References 419" ^. H  ?8 Z0 v& n
7 Antennas 421& O3 h6 C$ U: x& m1 A
7.1 Elemental Dipole Antennas 421
) U. p9 L- Z* M& I4 Z& r$ ~7.1.1 The Electric (Hertzian) Dipole 422
' B/ A' ]* b/ f( K/ f9 ?7.1.2 The Magnetic Dipole (Loop) 4268 e. V# H3 q& @( R$ ?
7.2 The Half-Wave Dipole and Quarter-Wave Monopole Antennas 429
" x. i- G1 A" F- f, Y7.3 Antenna Arrays 440
( \% o2 f8 G" e% g0 q7.4 Characterization of Antennas 448
( V) b$ ^# h/ K! }4 t1 u1 V7.4.1 Directivity and Gain 448
7 c3 k( z! p, Z2 ^* c$ h" \! D7.4.2 Effective Aperture 454
; `# ^" L) @/ o' W& V$ `7.4.3 Antenna Factor 456
" X; \& Q0 u! ^7 X+ F7.4.4 Effects of Balancing and Baluns 460! u2 ^4 e" Z4 a. O) R; ?) M
7.4.5 Impedance Matching and the Use of Pads 463& K; b1 H) O" e1 n% p
7.5 The Friis Transmission Equation 466( Q3 f2 T1 `0 W% ]( x  d
7.6 Effects of Reflections 470
% d; L+ E* y$ q% s: F2 a% x7.6.1 The Method of Images 470
9 V! X+ B' ^3 m5 ^, ux CONTENTS
! e: x9 G2 T: N9 d/ z+ u7 e/ l* a. x7.6.2 Normal Incidence of Uniform Plane Waves on Plane,+ C' ?  p: ?- \6 g* J
Material Boundaries 470
6 s/ ^) |) {# C; N) V1 a0 S$ L# ~6 `7.6.3 Multipath Effects 4795 v" H" Z7 o* Y+ R- Q$ j, ~6 B
7.7 Broadband Measurment Antennas 486
4 V3 G) U0 D! l) G# E7.7.1 The Biconical Antenna 487
) B, d0 z! R4 M( \3 _* a7 L7.7.2 The Log-Periodic Antenna 490
0 ]$ o4 W9 Z" W+ ZProblems 4943 G9 r) |+ Y* l8 R$ |$ n% W$ \
References 501
9 F, c' @8 n# N! s: N7 p: H8 Radiated Emissions and Susceptibility 503
+ H) n3 q  M% t3 w) |$ E8.1 Simple Emission Models for Wires and PCB Lands 504" o8 Q( @, ?; f& }- P- b- e# ~
8.1.1 Differential-Mode versus Common-Mode Currents 504
6 `. B: @, L' t$ X% t8.1.2 Differential-Mode Current Emission Model 5091 D; C$ W+ u: D1 i! d) [. B
8.1.3 Common-Mode Current Emission Model 514
9 b/ q' r1 c4 u. O' q& S8.1.4 Current Probes 518
# |" @, q( B3 b' c' n6 g8.1.5 Experimental Results 523
' x- [2 \9 k7 ~: W, N( p, C+ _8.2 Simple Susceptibility Models for Wires and PCB Lands 533
' d; g3 L. P0 r% y' P; p8.2.1 Experimental Results 544
* p: f" t) F7 n* R8.2.2 Shielded Cables and Surface Transfer Impedance 5462 m/ w: t* O6 Y
Problems 550
# t1 C! |7 b! h6 f+ fReferences 556
5 N) ?" ~' P; N$ r9 Crosstalk 559
& u) F  l% s# Z9.1 Three-Conductor Transmission Lines and Crosstalk 560
" \2 Y" X8 q  L1 j9.2 The Transmission-Line Equations for Lossless Lines 564
% |: ?8 H- Q" K( p" T+ s9.3 The Per-Unit-Length Parameters 5679 n! I3 W, q4 |/ L, Q
9.3.1 Homogeneous versus Inhomogeneous Media 5689 i$ q8 ], M! a; ?) @$ J
9.3.2 Wide-Separation Approximations for Wires 570- F# y- L$ _  w2 K
9.3.3 Numerical Methods for Other Structures 580
) H9 m/ @9 m( `" o/ I* h9.3.3.1 Wires with Dielectric Insulations3 t  W8 K* x) i0 U+ ^0 i2 `- X
(Ribbon Cables) 586
& R7 i& Y+ y1 Q  Y! L. h9.3.3.2 Rectangular Cross-Section Conductors
/ i( |& S) x* v: D& ~(PCB Lands) 590( o9 H7 z) P/ y' a) l8 @, G" ~
9.4 The Inductive–Capacitive Coupling Approximate Model 595
+ j) L" B$ Q1 m/ T  A9.4.1 Frequency-Domain Inductive-Capacitive Coupling
6 |* m  \% k" S, c! AModel 599
  N* m/ z0 ^2 M. [9 v4 Y9.4.1.1 Inclusion of Losses: Common-Impedance
- o, h$ |( F; o5 YCoupling 601
9 e1 Y. \; ?9 Q& J0 _* A4 y9.4.1.2 Experimental Results 6042 m. M7 k+ M) h( ?- n9 G
9.4.2 Time-Domain Inductive–Capacitive Coupling Model 612& W6 h5 k( z" d$ H% Q# d2 ~
9.4.2.1 Inclusion of Losses: Common-Impedance Coupling 616% {8 Z' c0 S+ `; t4 N: l( _
9.4.2.2 Experimental Results 6179 w4 k5 }9 e' H# c
CONTENTS xi4 k  `# R$ F6 ?# q- r
9.5 Lumped-Circuit Approximate Models 624+ [8 p: c3 p5 s, l+ D' A. I
9.6 An Exact SPICE (PSPICE) Model for Lossless, Coupled Lines 624( ~/ L+ z$ S$ r, L3 P2 ^& T8 t
9.6.1 Computed versus Experimental Results for Wires 633
4 Q+ i  L5 T: X' @! u9.6.2 Computed versus Experimental Results for PCBs 640
* S+ K3 L8 v& a/ y+ C  N9.7 Shielded Wires 647
5 r3 |& w, h. R( r4 a9 Q" b8 Y9.7.1 Per-Unit-Length Parameters 648  u4 p% w% D# |3 R$ `/ ^5 z3 @
9.7.2 Inductive and Capacitive Coupling 651
$ A! e4 n( l$ L5 \' o9.7.3 Effect of Shield Grounding 6583 H  `6 d& ~* _
9.7.4 Effect of Pigtails 667
4 V8 s% s7 X3 x5 a9.7.5 Effects of Multiple Shields 669
( q+ E7 A3 T$ [, O' m; `( \2 a9.7.6 MTL Model Predictions 675
, {6 V& Y. U1 K9.8 Twisted Wires 6778 |: f' I, d  I2 y; a
9.8.1 Per-Unit-Length Parameters 681+ E, Q9 D" v  h/ G% s. x; N4 u/ H
9.8.2 Inductive and Capacitive Coupling 685
, p! g  |& ?) u9 s4 \4 {! N; Z9.8.3 Effects of Twist 689
9 G3 y1 k2 r, H+ W$ D/ Z) x0 F9.8.4 Effects of Balancing 698* Q# n9 W; M+ j5 }# \+ U. p' w
Problems 701( l$ s. n: r6 j! S) K4 I
References 710
5 o+ c: q9 i7 f, v! d10 Shielding 713
4 A  Y2 o3 j% s6 `9 ~( ~' K10.1 Shielding Effectiveness 718
# I5 s' I8 A9 X. R  p1 [! S- K( _10.2 Shielding Effectiveness: Far-Field Sources 721
5 Q3 X) S2 N/ N$ H* h) j" w10.2.1 Exact Solution 721, F9 J* r5 w! L' q; Y
10.2.2 Approximate Solution 7255 }4 S8 B0 \& v( s
10.2.2.1 Reflection Loss 725
5 J4 ]) W2 @+ I* z) n. v10.2.2.2 Absorption Loss 728/ X$ U4 {  [& v- R
10.2.2.3 Multiple-Reflection Loss 729
# i+ E% o6 C. ~0 h. `10.2.2.4 Total Loss 731- x; o" s1 K; X2 [9 n
10.3 Shielding Effectiveness: Near-Field Sources 735
2 f9 l2 K6 @. K10.3.1 Near Field versus Far Field 7362 w9 R# r2 |8 k4 m& f. s
10.3.2 Electric Sources 740; [5 Y1 r% v* V! \
10.3.3 Magnetic Sources 740- s" \1 W8 X9 h$ P  Z9 ^; B
10.4 Low-Frequency, Magnetic Field Shielding 742+ u$ i* `5 l8 q% U' P
10.5 Effect of Apertures 7454 L; j0 |- d& X2 j0 s, N2 [: N
Problems 750
3 K$ A- N3 g; O9 ~6 G, \! OReferences 751& p1 Y# c( I; C& f8 Y
11 System Design for EMC 753
: x  n# x. d2 r' S11.1 Changing the Way We Think about Electrical Phenomena 758* `( |* R4 |. t
11.1.1 Nonideal Behavior of Components and the
: M6 J2 A2 q6 nHidden Schematic 758
4 M! r5 J2 [: J' |! _- z- j11.1.2 “Electrons Do Not Read Schematics” 763! \0 o$ [' s7 T7 O8 A9 R
xii CONTENTS
- ~* i, w6 ~( r4 S) C. ]11.1.3 What Do We Mean by the Term “Shielding”? 7667 h5 `9 {& n3 u$ q& c! Y
11.2 What Do We Mean by the Term “Ground”? 768: w3 G  j; h3 X' `/ B! ~3 c) c2 b
11.2.1 Safety Ground 771
' u. Q; z3 x7 {11.2.2 Signal Ground 774
1 x+ [( j0 r! r0 `% D- z# T11.2.3 Ground Bounce and Partial Inductance 7755 ?$ D' F. c5 D$ P1 @9 S$ z
11.2.3.1 Partial Inductance of Wires 781  A3 R8 ]* c! z) B, w7 S
11.2.3.2 Partial Inductance of PCB Lands 7862 i% `! D8 q$ o2 c
11.2.4 Currents Return to Their Source on the Paths of Lowest
6 @. d- t' G# |2 R) UImpedance 787
3 |4 e+ |, `" l& I/ f$ p11.2.5 Utilizing Mutual Inductance and Image Planes to Force% M  x# H; {; K; a  a- V) E
Currents to Return on a Desired Path 793- t9 H# h# b) [; ]- r. J6 P
11.2.6 Single-Point Grounding, Multipoint Grounding, and' ]; w8 P' c% ~
Hybrid Grounding 796
& C, x/ G& M7 w. O5 f3 F11.2.7 Ground Loops and Subsystem Decoupling 802
6 z8 P$ D7 u4 H11.3 Printed Circuit Board (PCB) Design 805' a, I+ e; C8 U& W) s
11.3.1 Component Selection 8058 k$ r* U  a% E( [8 X9 ]2 T
11.3.2 Component Speed and Placement 806( v9 ^5 k% ?2 j9 m
11.3.3 Cable I/O Placement and Filtering 808
1 W: |9 J2 U- ?! f! P% p( u5 m11.3.4 The Important Ground Grid 810
; u3 G: \) S, n0 G& r1 u3 u3 h11.3.5 Power Distribution and Decoupling Capacitors 812
3 W" Q. e7 {7 j- x# Y7 u11.3.6 Reduction of Loop Areas 822+ W" }  X  y6 q! a8 w) A
11.3.7 Mixed-Signal PCB Partitioning 823
- k; P9 i6 W+ m  `$ C# l& A6 I11.4 System Configuration and Design 8277 Y& I6 }8 A( S2 w3 M2 s1 H
11.4.1 System Enclosures 827
% {3 L" f) w: y- D& ?11.4.2 Power Line Filter Placement 8280 q& a8 Y! b8 \0 B$ ?/ e( C5 k
11.4.3 Interconnection and Number of Printed3 l: L. w4 Q0 D- x3 u
Circuit Boards 829
% j- j  N# s$ a9 l  M" C* X% w11.4.4 Internal Cable Routing and Connector Placement 831
. E. e. k4 T2 X" S3 O; }( W; t11.4.5 PCB and Subsystem Placement 832
4 t! @0 l5 A; i) N* H" r11.4.6 PCB and Subsystem Decoupling 832
7 ]- v1 @0 [7 \& [: H11.4.7 Motor Noise Suppression 8320 J' h& ~% c- o# ]& {0 v
11.4.8 Electrostatic Discharge (ESD) 8349 e! }/ F0 i/ p# ]
11.5 Diagnostic Tools 847& R3 C# [1 H' H
11.5.1 The Concept of Dominant Effect in the Diagnosis of
2 h- q; x# W1 j( VEMC Problems 850
  e- H: ~/ Z+ w0 g7 DProblem 8567 f* i0 @9 `/ O& G* y/ f
References 857
3 x- g( y; a/ K! F/ G2 u, IAppendix A The Phasor Solution Method 859
) U: d4 k' G4 i+ |4 RA.1 Solving Differential Equations for Their Sinusoidal,5 u7 P, |9 o& d( @
Steady-State Solution 859& M4 V# D9 q1 P7 I) }
CONTENTS xiii
# C, E% x, K* xA.2 Solving Electric Circuits for Their Sinusoidal,
4 J# L* d& N# M# xSteady-State Response 863
# e: C9 [9 }( Q9 N7 @Problems 867' @) l+ M5 G$ B) K3 H% h& a9 E8 s
References 869
: Q0 L6 i9 q, k$ uAppendix B The Electromagnetic Field Equations and Waves 871& N; c: F6 E6 o  \4 W
B.1 Vector Analysis 872
' ]4 O' A% b" [( G/ H; w  ]" EB.2 Maxwell’s Equations 881
: i6 s8 Q' U2 i; OB.2.1 Faraday’s Law 881+ I0 C, k* x! g, ~2 r8 ~) E/ \
B.2.2 Ampere’s Law 892
$ _0 `' R) K5 k4 X% H! p  cB.2.3 Gauss’ Laws 898
# {2 J! d" l& h$ X" I2 }' ]B.2.4 Conservation of Charge 900
; A+ ^% m* O# i9 lB.2.5 Constitutive Parameters of the Medium 900( D1 ^& z5 S' H. C& i
B.3 Boundary Conditions 902' C: c- {" y: W6 Q) U
B.4 Sinusoidal Steady State 9079 [& Y- _0 {; E# F7 v5 t+ t! z7 K6 x
B.5 Power Flow 909
# z' B$ O! D. a9 g0 _5 m; k2 c! W  g! JB.6 Uniform Plane Waves 9092 d# i5 n) x/ e
B.6.1 Lossless Media 912
; ?# i4 X  h. eB.6.2 Lossy Media 918
. U$ }3 Z/ d: N" a) jB.6.3 Power Flow 922
- ~) ?: l! v# dB.6.4 Conductors versus Dielectrics 923
' V% l" F; g: L& e5 GB.6.5 Skin Depth 925: H( F0 P2 s; O& \' o8 J
B.7 Static (DC) Electromagnetic Field Relations—  B; k/ k1 _- V1 H3 Q; a
a Special Case 927, A; J7 \0 G- d! H! o5 ]( q+ P
B.7.1 Maxwell’s Equations for Static (DC) Fields 927
: ?8 x3 c; D- s7 QB.7.1.1 Range of Applicability for& Z/ @+ @* L" q: M; E! t
Low-Frequency Fields 9282 q1 k% W1 r0 {! u& t( \, h
B.7.2 Two-Dimensional Fields and Laplace’s
: E( T3 V5 Y9 S% L/ L8 AEquation 928. ~" p% t" t0 t) H
Problems 930- U8 L3 T: |% X
References 939
% d% I& u8 i! e! C, f& dAppendix C Computer Codes for Calculating the Per-Unit-Length. @2 q+ f$ c" D2 _% f( ~: P
(PUL) Parameters and Crosstalk of Multiconductor" b' w7 X4 |+ o+ |) I
Transmission Lines 941
$ |0 P* |: i, O; ZC.1 WIDESEP.FOR for Computing the PUL7 y& w8 w9 C, o: o
Parameter Matrices of Widely Spaced Wires 942
. S9 U3 Z; ^- Z- o; N' j$ Q5 K& QC.2 RIBBON.FOR for Computing the PUL Parameter% s3 z$ u* \1 l3 Y- p4 q$ s
Matrices of Ribbon Cables 9478 C) G: e4 w  U6 G& R0 ~
C.3 PCB.FOR for Computing the PUL Parameter0 Q$ X/ b% F# f$ j$ ^  s4 a! @0 F4 S
Matrices of Printed Circuit Boards 9498 f, z5 X* I/ P0 c( R
xiv CONTENTS
/ ?/ ^) y; R2 d+ P$ o5 U- [C.4 MSTRP.FOR for Computing the PUL Parameter4 {4 a3 }: O1 O: U2 a1 ?
Matrices of Coupled Microstrip Lines 951
  u9 y8 U# K' q2 O9 y9 C8 H8 LC.5 STRPLINE.FOR for Computing the PUL1 H8 c2 x/ y( `( @' \* F% L
Parameter Matrices of Coupled Striplines 952
" b$ q9 W/ Y+ W) G- \* b  h2 ~C.6 SPICEMTL.FOR for Computing a SPICE: s/ R. V: l) r
(PSPICE) Subcircuit Model of a Lossless,& a: U/ W% R) q$ B# X, T' V
Multiconductor Transmission Line 954
0 P$ J6 v- W5 e, g% E. G) h/ K4 w: kC.7 SPICELPI.FOR For Computing a SPICE (PSPICE)
1 Z4 Z+ Q: I5 ^+ tSubcircuit of a Lumped-Pi Model of a Lossless,
$ c  a# D& P. NMulticonductor Transmission Line 956
9 R& O* b) B+ Q+ UAppendix D A SPICE (PSPICE) Tutorial 959
$ S* k' w7 H% A' m2 KD.1 Creating the SPICE or PSPICE Program 960
" p  C$ l  u* YD.2 Circuit Description 9614 v" X# ]' J8 }, z, }9 l# c% o
D.3 Execution Statements 966' x+ C$ c3 z" P# Y
D.4 Output Statements 968
& H" s: N; Z+ O. n# v" iD.5 Examples 9703 t5 n7 F" f* o2 B3 C! ]9 q9 y
References 974
9 F+ d/ D$ Z& Y4 PIndex 975/ s' ]9 U  w! r7 l& A8 R( P# ]7 r
- ~* a3 r* g$ e  U( h) K. G5 ?

Wiley.Interscience.Introduction.to.Electromagnetic.Compatibility.Jan.2006-Clayto.rar

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3.Handbook of Electromagnetic Compatibility/ e8 f% b9 d, o7 Y
电磁兼容性手册; K, h: L- ?; D& Z$ A3 A
1995年出版
4 s) T& V* j* d1 R* y! [1 |* P. J5 F作者Reinaldo Perez
% ]5 V" O/ Y& B【无目录】

Handbook of Electromagnetic Compatibility, 1995.part1.rar

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4.EMC for Product Designers
8 S  {9 b4 X. |) g" O+ x/ nTim Williams) [- J# `4 P( |( I" {  `  O

8 f0 |7 A* T% r/ G5 q
4 ~; D  f( v# m! |0 i. _: ]

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EMC for Product Designers.rar

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