[分享]【资料分享】【pdf】【13卷】SI、PI、EMC 方向的一本宝书   2008年11月出版

资料分享】【pdf】【13分卷】 9[E/^  
<Signal Integrity and Radiated Emission of High-Speed Digital Systems> z,qNuv"W  
信号完整性、电源完整性及电磁兼容  方向的一本宝书   ?fU{?nI}>p  
2008年11月出版（国外最新理论及科研成果的结晶） 'bji2#z[  
Wiley上下载到了电子版，看了内容，深受感动。。。。 pdQaVe7tRo  
/$8& r  
这是一本高速PCB的信号完整性，电源完整性和电磁兼容方面一本不可多见的宝书 >SZuN"r8`  
与以往信号完整性领域的三大宝书内容相比有不少亮点，应该说是该领域最新成果的总结和阐述，理论性和实践性都很强啊。 oPAc6ObOV~  
尤其要写论文的，这本书很有参考价值。 h9A=20fj  
建议搞这方面的朋友们下载来看看。 >&Ye(3w&  
2009年1月在国外出版发行，国内好像买不到。 _n*gj-  
到处网店都搜过了。 K/(Z\lL  
但是可以到国外网店用双币卡买，或者国际信用卡买。 cw BiT  
O>wGJ.  
内容简介： /KiaLS  

Author	Caniggia, Spartaco
Dewey	621.382
Format	Hardcover
ISBN	0470511664
MSRP	150.00
Pages	00552
Publication Date	08/2008
Roles	Caniggia, Spartaco : Author
Roles	Maradei, Francescaromana : Author
Subject	Telecommunications
Subject	Waves & Wave Mechanics

|c]L]
PU  
Before putting digital systems for information technology or telecommunication applications on the market, an essential requirement is to perform tests in order to comply with the limits of radiated emission imposed by the standards. This book provides an investigation into signal integrity (SI) and electromagnetic interference (EMI) problems. Topics such as reflections, crosstalk, switching noise and radiated emission (RE) in high-speed digital systems are covered, which are essential for IT and telecoms applications. The highly important topic of modelling is covered which can reduce costs by enabling simulation data to demonstrate that a product meets design specifications and regulatory limits. According to the new European EMC directive, this can help to avoid the expensive use of large semi-anechoic chambers or open area test sites for radiated emission assessments. Following a short introduction to signalling and radiated interference in digital systems, the book provides a detailed characterization of logic families in terms of static and dynamic characteristic useful for modelling techniques.  Crosstalk in multi-coupled line structures are investigated by analytical, graphical and circuit-based methods, and techniques to mitigate these phenomena are provided. Grounding, filtering and shielding with multilayer PCBs are also examined and design rules given. EA:_PBZ  

• Written by authors with extensive experience in industry and academia.
• Explains basic conceptual problems from a theoretical and practical point of view by using numerous measurements and simulations.
• Presents models for mathematical and SPICE-like circuit simulators.
• Provides examples of using  full-wave codes for SI and RE investigations.
• Companion website containing lists of codes and sample material.

Signal Integrity and Radiated Emission of High-Speed Digital Systems is a valuable resource to industrial designers of information technology, telecommunication equipment and automation equipment as well as to development engineers. It will also be of interest to managers and designers of consumer electronics, and researchers in electronics. 'wLW`GX.  
>Y3zO2Cr  
00W_XhJ  
Contents \>/AF<2"  
List of Examples xiii %&O'>L  
Foreword xvii _=5\$6  
Preface xix dZJU>o'BG  
1 Introduction to Signal Integrity and Radiated Emission in a Digital System 1 w `M/0.)V  
1.1 Power and Signal Integrity 2 &6Wim<*  
1.1.1 Power Distribution Network 3 cJ,`71xop,  
1.1.2 Signal Distribution Network 5 @bFl8-  
1.1.3 Noise Limitations and Design for Characteristic Impedance 7 yK2>ou  
1.2 Radiated Emission 9 \<=.J`o{  
1.2.1 Definition of Radiated Emission Sources 9 kx0w?A8-  
1.2.2 Radiated Emission Standards 11 ]w8h#p  
1.2.3 Radiated Emission from a Real System 17 f`J[u!Ja  
1.3 Signaling and Logic Devices 19 Zg])uM]\2i  
1.3.1 Overshoot, Undershoot and Plateau 20 DqH]FS?]  
1.3.2 Noise Immunity 24 :d~&Dt<c  
1.3.3 Timing Parameters 25 a- /p/ I-%  
1.3.4 Eye Diagram 27 w/0;N`YB  
1.4 Modeling Digital Systems 29 a'G[!"  
1.4.1 Mathematical Tools 29 1kc{`oL  
1.4.2 Spice-Like Circuit Simulators 30 YBk* CW9  
1.4.3 Full-Wave Numerical Tools 31 .fzns20u  
1.4.4 Professional Simulators 34 -fz(]d  
References 34 WdrMp  
2 High-Speed Digital Devices 37 H#`&!p  
2.1 Input/Output Static Characteristic 37 l~`JFWur]  
2.1.1 Current and Voltage Specifications 37 VDy_s8Z#  
2.1.2 Transistor–Transistor Logic (TTL) Devices 39 v@!r$jZ  
2.1.3 Complementary Metal Oxide Semiconductor (CMOS) Devices 42 |R Qa.^.  
2.1.4 Emitter-Coupled Logic (ECL) Devices 44 BGT`) WP  
2.1.5 Low-Voltage Differential Signal (LVDS) Devices 45 :rmi8!o  
2.1.6 Logic Devices Powered and the Logic Level 45 ^
6,}*@  
2.2 Dynamic Characteristics: Gate Delay and Rise and Fall Times 46 #4sSt-s&  
vi Contents i\L7z)u
 
2.3 Driver and Receiver Modeling 48 =?B[oq  
2.3.1 Types of Driver Model 48 oW/H8q<wY  
2.3.2 Driver Switching Currents Path 50 Ac,bf 8C  
2.3.3 Driver Non-Linear Behavioral Model 51 T6rjtq  
2.3.4 Receiver Non-Linear Behavioral Modeling 53 R<>uCF0  
2.4 I/O Buffer Information Specification (IBIS) Models 54 n22OPvp  
2.4.1 Structure of an IBIS Model 54 "FfP&lF/  
2.4.2 IBIS Models and Spice 56 b@1";+(27  
References 58 M<)Vtn  
3 Inductance 59 apm,$Vvjy  
3.1 Loop Inductance 59 H%Sx*|  
3.1.1 Inductances of Coupled Loops 60 MB5X$5it  
3.1.2 Inductances of Thin Filamentary Circuits 62 +m6acu)N.  
3.1.3 Equivalent Circuit of Two Coupled Loops 62 L:_pJP  
3.1.4 L Matrix of Two Coupled Conductors Having a Reference @v\jL+B+m  
Return Conductor 63 4kLTKm:G  
3.1.5 L Calculation of a Three-Conductor Wire-Type Line 65 A%#."2vq~  
3.1.6 Frequency-Dependent Internal Inductance 66
u z>V  
3.2 Partial Inductance 67 -F-,
Gcos  
3.2.1 Partial Inductances of Coupled Loops 67 qQ<7+z<4KP  
3.2.2 Flux Area of Partial Inductance of Thin Filamentary Segments 68 iHOvCrp+X  
3.2.3 Loop Inductance Decomposed into Partial Inductances 70 Fc"+L+h@W  
3.2.4 Self and Mutual Partial Inductance 72 ]O68~+6  
3.2.5 Inductance Between Two Parallel Conductors 74
QtqE&j  
3.2.6 Loop Inductance Matrix Calculation by Partial Inductances 75 p
["20?^  
3.2.7 Partial Inductance Associated with a Finite Ground Plane 76 'P >h2^z  
3.2.8 Solving Inductance Problems in PCBs 77 BG@[m  
3.3 Differential Mode and Common Mode Inductance 79 D|5Fo'O^AV  
3.3.1 Differential Mode Inductance 79 ^t)alNGos  
3.3.2 Common Mode Inductance 80 MW.,}f  
References 81 v.]W{~PI2V  
4 Capacitance 83 u&Y1,:hiL  
4.1 Capacitance Between Conductors 83 ^d/,9L\U  
4.1.1 Definition of Capacitance 83 ^$\#aTyFK  
4.1.2 Partial Capacitance and Capacitance Matrix of Two Coupled `l}r&z(8  
Conductors Having a Reference Return Conductor 85 q}7(w$&  
4.1.3 Capacitance Matrix of n Coupled Conductors Having a Reference 7y>{Y$n  
Return Conductor 86 }KL( -Ui$  
4.2 Differential Mode and Common Mode Capacitance 87 q/\Hh9`  
4.2.1 Differential Mode Capacitance 87 o,y{fv:ki  
4.2.2 Common Mode Capacitance 88 (@u"  
References 89 E@ !~q  
Contents vii QcDtZg\  
5 Reflection on Signal Lines 91 Q%RI;;YyA  
5.1 Electrical Parameters of Interconnects 91 "C%* 'k  
5.1.1 Typical Interconnects 91 UXV>#U?  
5.1.2 Equivalent Circuit of a Short Interconnect 92 ,Z]4`9c  
5.1.3 Lossless Transmission Lines 94 Fk
IT/H  
5.1.4 Transmission-Line Modeling by Using Partial Inductances 96 wo!;Bxo N  
5.2 Incident and Reflected Waves in Lossless Transmission Lines 96 /T/7O  
5.2.1 Resistive Discontinuity 97 ,G(bwE9~  
5.2.2 Capacitive Discontinuity 97 h`p9H2}0  
5.2.3 Reflections in Interconnects Terminated with Resistive Loads 99 bMF`KRP2  
5.2.4 Critical Length of Interconnects 100 c:z<8#A}  
5.2.5 Lattice Diagram for Reflection Calculation 101 !p"Ijz5  
5.2.6 Exact Model of a Lossless Transmission Line 102 Xc@%_6  
5.2.7 Graphical Solution for Line Voltages 105 vJ!<7 l&  
5.3 Signal Distribution Architecture 109 !xZ`()D#  
5.3.1 Point-to-Point Structure 110 0Z~G:$O/i  
5.3.2 Star Structure 110 Uv/?/;si  
5.3.3 Chain Structure 111 'WQ<|(:{  
5.3.4 Bus Structure 112 \wo'XF3:  
5.3.5 H-Tree Structure 112 ,1-#Z"~c  
5.3.6 Comb Structure 112 bG9$&,  
5.4 Line Terminations 114 !F*CEcB  
5.4.1 Th´evenin Termination 114 -qnd
BS  
5.4.2 Series, Parallel, and AC Terminations 117 |zSoA=7?  
5.4.3 Series Termination and Comparison with Other Terminations by <)9E.h  
Circuit Simulations 117 Dmv@ljwO  
5.4.4 Th´evenin Termination Applied to Chain Structures and wrt^0n'r)c  
Circuit Simulations 118 AVv8Hhd  
5.4.5 Series Termination Applied to Chain Structures and Circuit nHi6$} I  
Simulations 120 HTUY|^^D  
5.4.6 Th´evenin Termination Applied to Bus Structures and Circuit Simulations 121 5oIgxy  
5.4.7 Termination and Interconnection Structures 123 ;F'/[l{+  
5.4.8 Termination Performance 123 f0lK,U@P  
References 124 c1Ta!p{%  
6 Crosstalk 125 &8wluOs/5  
6.1 Lumped-Circuit Model of Coupled Lines 126 xu0pY(n^r  
6.1.1 Equivalent Circuit of Two Coupled Lines with a Reference Ground 126 4wQ>HrS)(  
6.1.2 Capacitive Coupling 127 q\6ZmKGnT  
6.1.3 Inductive Coupling 129 :>otlI<0t  
6.1.4 Total Coupling 130 d#G H4+C  
6.1.5 Simulations of Two Coupled Lines 130 :Qra9
; Y  
6.2 Common and Differential Modes 133 |G]M"3^  
6.2.1 Definition of Even and Odd Modes 134 % 2lcc"'  
6.2.2 Equivalent Circuit Based on Even and Odd Modes 136 v/lQ5R1  
viii Contents |#!P!p}  
6.2.3 Equivalent Circuit for the Differential Transmission Mode 137 @#5PPXp  
6.2.4 Simulations of Point-to-Point and Chain Structure by Even and Odd Modes 137 u~a@:D/F{G  
6.3 Models for Digital Devices: Simulation and Measurements 140 QZ51}i  
6.4 General Distributed Model for Lossless Multiconductor Transmission Lines 150 @=1kr ^i  
6.4.1 Equivalent Circuit of n Coupled Lossless Lines 151 cH%#qE3  
6.4.2 Measurements and Simulations of Five Coupled Lines with TTL ,=kQJ|  
and CMOS Devices 152 Arb-,[kwN  
6.5 Techniques to Reduce Crosstalk 157 ]):kMRv  
6.5.1 Fixes to Reduce Crosstalk 157 q+-Bl  
6.5.2 Simulations of Coupled Lines with Grounded Traces used as /_*L8b  
a Shield 158 m`lsUN,  
6.5.3 Full-Wave Numerical Simulations of Two Coupled Lines 158 u0& dDZ  
References 161 C %o^
AR  
7 Lossy Transmission Lines 163  =:-x;  
7.1 Lossy Line Fundamental Parameters 164 {n>W8sN<  
7.1.1 Reflection Mechanism in a Lossy Line 164 KUqD<Jj?  
7.1.2 Skin Effect 167 L>EC^2\  
7.1.3 Proximity Effect 171 #r_&Q`!eU  
7.1.4 Lossy Dielectric Effect 173 UA}oOteG  
7.1.5 Data Transmission with Lossy Lines 175 *b0f)y3RV  
7.2 Modeling Lossy Lines in the Time Domain by the Segmentation Approach [3QKBV1\  
and Vector Fitting Technique 183 HJu;4O($  
7.2.1 Circuit Extraction of Coaxial Cables 184 ^d2bl,1  
7.2.2 Circuit Extraction of Twisted-Pair Cables 195 +b]+5!  
7.3 Modeling Lossy Lines in the Time Domain by the Scattering Parameters _~E&?zR2>"  
Technique 207 U$(AZ|0  
7.4 Conclusions 215 :X6A9jmd  
References 216 Z,osdF  
8 Delta I-Noise 219 9>"To  
8.1 Switching Noise 220 hd}"%
9p  
8.1.1 Power Distribution Network 220 RGim):1e  
8.1.2 Switching Current Path 225 [8QE}TFic  
8.1.3 Design Rules 236 4h[^!up.7  
8.2 Filtering Power Distribution 237 lE?F Wt  
8.2.1 Filtering Multilayer PCBs 237 c}>p"  
8.2.2 Measurement of Power Distribution Network Impedance 244 Ug^v ]B9  
8.2.3 PCB Circuit Model Based on Radial Transmission Line Theory 245 xc+h Fx  
8.3 Ground Bounce 254 G}b LWA  
8.3.1 Ground Bounce Mechanism 255 &t\KKsUtd  
8.3.2 Circuit Simulations to Understand the Ground Bounce Mechanism 256 \WeGO.i-  
8.3.3 Measurements of an LVT Benchmark 257 &ii3Vlyzg  
8.4 Crosstalk and Switching Noise 262 `o~9a N  
8.4.1 Measurements and Simulations of the SQ-Test Board with Three a_0G4@=T  
Coupled Lines and 74AC04 Devices 262 D 4\T`j:  
References 266 ;tF7GjEp  
Contents ix {~ngI<  
9 PCB Radiated Emission 269 t~0}Emgp<(  
9.1 Frequency Characterization of a Digital Signal 270 D'823,-).  
9.1.1 Spectrum of a Trapezoidal Waveform 270  !m
X 2  
9.1.2 Spectrum of Typical Noises 274 iE$/ Rcp  
9.2 The Radiated Emission Problem 276 5'Fh_TXTD  
9.2.1 Radiation from a Wire Antenna 278 `)W}4itm  
9.2.2 Common- and Differential-Mode Currents and Radiations 279 :8~*NSEFd  
9.2.3 Emission Due to Line Asymmetrical Feed 281 jci'q=Vpu  
9.2.4 Differential-Mode Current and Radiated Emission of a =K)au$BE|  
Transmission Line 282 4V`ypFme  
9.2.5 Common-Mode Current and Radiated Emission of a Transmission Line 284 EI29;  
9.2.6 Image Plane 287 .{1MM8 Q  
9.3 Emission from Traces 289 z;_d?S<*m  
9.3.1 Antenna Models for Calculating the Radiation of Microstrip and >Cjb|f3'i}  
Stripline Structures 289 m_z1|zM}o  
9.4 Emission from ICs 295 G*|2qX"o  
9.4.1 Radiated Emission Mechanism from Components in a PCB 296 u&>o1!c*P  
9.5 Emission from a Real PCB 298 vO)nqtw  
9.6 Emission from a PCB with an Attached Cable 303 FFNv'\)  
9.6.1 Sources of Emission 303 f}'E|:Z 7k  
9.6.2 Current- and Voltage-Driven Mechanisms with a Trace in a PCB 303 e_BOzN~c  
9.7 Differential Drivers as Sources of Emission 318 E30VKh |  
9.7.1 Common-Mode Current with Differential Drivers 318 y8KJoVPiM  
9.7.2 Radiated Field Mechanism of UTP and SFTP Cables 319 IRZ?
'Im  
9.8 Emission from a Complex System 327 ega
< {t  
9.8.1 Emission Model of Coaxial Cables 330 f&S,l3H<  
9.8.2 Low-Frequency Model of an Aperture 336 &r;4$7  
9.9 Radiation Diagrams 341 hD>O LoO  
9.10 Points to Remember and Design Rules for Radiated Emission 349 m"!!)
 
References 352 F:CqB|  
10 Grounding in PCBs 355 ;Vad| -  
10.1 Common-Mode Coupling 355 )up!W4h6o  
10.1.1 What is Ground? 356 "yI)F~A  
10.1.2 Ground Loop Coupling and Transfer Impedance 356 l}?'U  
10.1.3 Grounding Strategy 363 46dh@&U  
10.2 Ground and Power Distribution in a Multilayer PCB 365 B%L0g.D"  
10.2.1 Return Path for the Signal 366 `q 4%  
10.2.2 Power (PWR) and Ground (GND) Layer Planning and Topology 370 #n'tpp~O  
10.2.3 Trace Changing Reference Plane 370 ba3_55]  
10.2.4 Split Power Plane 372 q lL6wzq,  
10.2.5 Moats/Barriers and Bridges 373 Cp_YIcnEJ  
10.2.6 Stitches 374 v|XEC[F  
10.3 Grounding at PCB Connectors 375 U&6!2s-  
10.3.1 Ground Noise and Transfer Impedance 375 MOFIR wVZ+  
x Contents j!;?=s  
10.3.2 Pin Assignment 381 ^zv28Wq>  
10.3.3 Grounding a PCB to a Chassis 384 S)[`Bm  
10.3.4 Techniques to Limit Emission from Cables 385 ~T')s-,l,:  
10.4 Partitioning and Modeling 393 wK[xLf  
10.4.1 Modeling the Power Distribution with a Driver for Simulations 400 ?hS n)  
10.5 Points to Remember and Design Rules for Grounding in PCBs 402 Z50]g  
References 406 m.MOn3n]  
11 Measurement and Modeling 409 > @ulvHL  
11.1 Time-Domain Reflectometer (TDR) 410 tF)aNtX4^  
11.1.1 TDR as a ‘Closed-Loop Radar’ 410 ?.:C+*+  
11.1.2 TDR Resolution and Aberrations 412 =^P<D&%q  
11.1.3 TDR and Lossy Lines 415 ipEsR/O  
11.1.4 Differential TDR 416 :G|
Jcl=r  
11.2 Vector Network Analyzer (VNA) 417 1@H3!V4  
11.2.1 Scattering Parameter Definition 417 1(Kd/%]{  
11.2.2 VNA Calibration 420 eD*"#O)W  
11.2.3 Extraction of Equivalent Circuits by S-Parameter Simulations 421 h!f7/)|[o  
11.2.4 Conclusions Concerning VNA Measurements and Simulations 429 (d[)U<  
11.3 Prediction Model Validation by Radiated Emission Measurements 431 =S-'
*
F  
11.3.1 Uncertainty of the EMC Lab for Radiated Field Measurements %cD7}o:u  
and Numerical Simulations 431 eA>O<Z1>  
11.3.2 Modeling the Radiating Source 436 {O
6f1LuH  
11.3.3 Conclusion Concerning Validation of the Numerical Prediction AO9F.A<T5  
Model for Radiated Emission by Comparison with Measurements 439 "~4ULl<i'  
References 440 /0 ,#c2aq  
12 Differential Signaling and Discontinuity Modeling in PCBs 441 ztG_::QtG]  
12.1 Differential Signal Transmission 442 N"b>]Ab] ;  
12.1.1 Single-Ended Versus Differential Signal Transmission 442 4 ~17s`+  
12.1.2 Differential Interconnect with Traces in PCBs and the ATCA Standard 445 #{ M$%l>  
12.1.3 Differential Devices: Signal Level Comparison 447 B_[^<2_  
12.1.4 Differential Signal Distribution and Terminations 447 UKx91a}g  
12.1.5 LVDS Devices 451 
V&DS+'P  
12.2 Modeling Packages and Interconnect Discontinuities in PCBs 466 ()vxTTa  
12 .. #Vanw!  
#nc{MR#R  

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不是吧，还少个第六部分。缺一个卷～～

引用第4楼雨夜屠夫于2008-11-25 09:23发表的 : <qH>[
\  
不是吧，还少个第六部分。缺一个卷～～

$^R[t;  
朋友，麻烦细致一点。一共13卷，后面跟帖中还有呢，呵呵

太黑了，没个都要买啊？？我穷啊，总共就3个，都给你了。郁闷

     A0oC*/  
没研究过这个方面， _R8)%<E  
下载下来看看

谢谢楼主分享

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