[射频]分享：Wiley.-.Ieee.-.Practical.Rf.System.Design.-.Egan

CONTENTS >Vx_Xv`Jwb  
PREFACE xvii A@_>9;   
GETTING FILES FROM THE WILEY ftp AND INTERNET SITES xix l x;87MDs  
SYMBOLS LIST AND GLOSSARY xxi |15!D  
1 INTRODUCTION 1 ?fP3R':s  
1.1 System Design Process / 1 h{_\okC>  
1.2 Organization of the Book / 2 _1Rw~}O  
1.3 Appendixes / 3 %^E7Iqc  
1.4 Spreadsheets / 3 #hn  
1.5 Test and Simulation / 3 "9^b1UH<  
1.6 Practical Skepticism / 4 _#v"sGmN  
1.7 References / 5 <z%**gP~G  
2GAIN 7 M]k Q{(  
2.1 Simple Cases / 8 yKrbGK*=_  
2.2 General Case / 9 ( ./MFf

 
2.2.1 S Parameters / 9 {hOS0).(w7  
2.2.2 Normalized Waves / 11 f U=P$s  
2.2.3 T Parameters / 12 rZ+4kf6S  
vii j7:r8? G  
viii CONTENTS :4
)x  
2.2.4 Relationships Between S and T Parameters / 13 $Bncdf  
2.2.5 Restrictions on T Parameters / 14 E<tR8='F  
2.2.6 Cascade Response / 14 Z~h6^h   
2.3 Simplification: Unilateral Modules / 15 nu+^D$ait  
2.3.1 Module Gain / 15 fsK=]~<g  
2.3.2 Transmission Line Interconnections / 16 ha;fxM]  
2.3.3 Overall Response, Standard Cascade / 25 P5B,= K>r  
2.3.4 Combined with Bilateral Modules / 28 'MX|=K!C  
2.3.5 Lossy Interconnections / 32 fQ1j@{Xa  
2.3.6 Additional Considerations / 38 Oq% TW|a#  
2.4 Nonstandard Impedances / 40 ^S;{;c+'  
2.5 Use of Sensitivities to Find Variations / 40 e<{d{  
2.6 Summary / 43 cy(w*5Upu  
Endnotes / 45 OAiW8BAe  
3 NOISE FIGURE 47 qov<@FvE0  
3.1 Noise Factor and Noise Figure / 47 E0VAhN3G\  
3.2 Modules in Cascade / 49 -0q|AB<  
3.3 Applicable Gains and Noise Factors / 54 P-[})Z=  
3.4 Noise Figure of an Attenuator / 55 |S).,B  
3.5 Noise Figure of an Interconnect / 56 V;RgO}  
3.6 Cascade Noise Figure / 56 mzM95yQ^Z  
3.7 Expected Value and Variance of Noise Figure / 58 OESKLjFt  
3.8 Impedance-Dependent Noise Factors / 59 kl~/tbf
 
3.8.1 Representation / 60 VHqoa>U,*  
3.8.2 Constant-Noise Circles / 61 r)-{~JA!  
3.8.3 Relation to Standard Noise Factor / 62 "|J6*s   
3.8.4 Using the Theoretical Noise Factor / 64 4yqYs>  
3.8.5 Summary / 65 "3]}V=L<5  
3.9 Image Noise, Mixers / 65 &R.5t/x_  
3.9.1 Effective Noise Figure of the Mixer / 66 B%u[gN
Z  
3.9.2 Verification for Simple Cases / 69 <)LR  
3.9.3 Examples of Image Noise / 69 h4KMhr  
3.10 Extreme Mismatch, Voltage Amplifiers / 74 oDD"h,Z  
3.10.1 Module Noise Factor / 76 '{~[e**  
3.10.2 Cascade Noise Factor / 78 ?kZ-,@h:  
3.10.3 Combined with Unilateral Modules / 79 &0[L2x}7  
3.10.4 Equivalent Noise Factor / 79 zRLJ|ejMP  
CONTENTS ix ;*zLf 9i  
3.11 Using Noise Figure Sensitivities / 79 "XV@OjrE  
3.12 Mixed Cascade Example / 80 1}c/l<d  
3.12.1 Effects of Some Resistor IQC[ewk  
Changes / 81 5tkKd4VfL
 
3.12.2 Accounting for Other Reflections / 82 PHT<]:"`<  
3.12.3 Using Sensitivities / 82 -Wmb M]Z  
3.13 Gain Controls / 84 #mUQ@X@K  
3.13.1 Automatic Gain Control / 84 \WnTpl>B  
3.13.2 Level Control / 86 [/*;}NUv  
3.14 Summary / 88 s&o9LdL  
Endnotes / 90 R!/JZ@au<  
4 NONLINEARITY IN THE SIGNAL PATH 91 E(6P%(yt8  
4.1 Representing Nonlinear Responses / 91 f^QC4hf0  
4.2 Second-Order Terms / 92 W3Ee3  
4.2.1 Intercept Points / 93 xc@$z*w  
4.2.2 Mathematical Representations / 95 =$bF[3D  
4.2.3 Other Even-Order Terms / 97 t {1 [Ip  
4.3 Third-Order Terms / 97 }&7kT7ogO  
4.3.1 Intercept Points / 99 i" u|119  
4.3.2 Mathematical Representations / 100 Y~I>mc]  
4.3.3 Other Odd-Order Terms / 101 <G<5)$ S  
4.4 Frequency Dependence and Relationship [~|k;\2 +  
Between Products / 102 2 KH
T!ik  
4.5 Nonlinear Products in the Cascades / 103 t
 3N}):  
4.5.1 Two-Module Cascade / 104 S}h d,"I  
4.5.2 General Cascade / 105 YWd2bRb  
4.5.3 IMs Adding Coherently / 106 8;"%x|iBoL  
4.5.4 IMs Adding Randomly / 108 2+)h!y]  
4.5.5 IMs That Do Not Add / 109 ,)d`_AD+5  
4.5.6 Effect of Mismatch on IPs / 110 ;xw9#.d#D  
4.6 Examples: Spreadsheets for IMs in a 3}phg  
Cascade / 111 w0nbL^f  
4.7 Anomalous IMs / 115  r90tXx  
4.8 Measuring IMs / 116 /@ g 8MUq7  
4.9 Compression in the Cascade / 119 gn/]1NN
fR  
4.10 Other Nonideal Effects / 121 Jia@HrLR  
4.11 Summary / 121 iJ*Wsp  
Endnote / 122 z<!A;.iD  
x CONTENTS qHe H/e%`V  
5 NOISE AND NONLINEARITY 123 DC> R  
5.1 Intermodulation of Noise / 123 \VIY[6sn\M  
5.1.1 Preview / 124 ]<YS7.pT  
5.1.2 Flat Bandpass Noise / 125 &@{`{
  
5.1.3 Second-Order Products / 125 zb[kRo&a0W  
5.1.4 Third-Order Products / 130 JBw2#ry  
5.2 Composite Distortion / 133 jCtk3No  
5.2.1 Second-Order IMs (CSO) / 134 aw lq/
 
5.2.2 Third-Order IMs (CTB) / 136 !<j4*av:G  
5.2.3 CSO and CTB Example / 136 l}-k>fug  
5.3 Dynamic Range / 137 '>1M~B  
5.3.1 Spurious-Free Dynamic Range / 137 UJp'v_hN  
5.3.2 Other Range Limitations / 139 C^'r>0  
5.4 Optimizing Cascades / 139 6A5.n?B{  
5.4.1 Combining Parameters on One Spreadsheet / 139 &,PA+#  
5.4.2 Optimization Example / 143 &@|? %  
5.5 Spreadsheet Enhancements / 146 .j,xh )v"  
5.5.1 Lookup Tables / 146 [3S17tTc3  
5.5.2 Using Controls / 147 Hr}"g@ <  
5.6 Summary / 147 @VOegf+N  
Endnotes / 147 <W3p!  
6 ARCHITECTURES THAT IMPROVE LINEARITY 149 Cb<7?),vK  
6.1 Parallel Combining / 149 or;VmU8$zb  
? gU&+^e >  
6.1.1 90 Hybrid / 150 S=V  
? Ufi#y<dP  
6.1.2 180 Hybrid / 152 O,^s)>c  
6.1.3 Simple Push–Pull / 154 Yyd}>+|<,  
6.1.4 Gain / 155 #k>n5cR@0  
6.1.5 Noise Figure / 156 rmvrv.$3  
6.1.6 Combiner Trees / 156 ZW"f*vwQo  
6.1.7 Cascade Analysis of a Combiner Tree / 157 {df;R|8l  
6.2 Feedback / 158 yVn%Bz' [  
6.3 Feedforward / 159 O\;Lb[`lb  
6.3.1 Intermods and Harmonics / 160 lQ ki58.  
6.3.2 Bandwidth / 161 ;}S_PnwC@  
6.3.3 Noise Figure / 161 H*0g*(  
6.4 Nonideal Performance / 162 DH_~,tK9  
6.5 Summary / 163 [{xY3WS  
Endnotes / 163 Fq+Cr?-  
CONTENTS xi qgEzK  
7 FREQUENCY CONVERSION 165 1#"wfiW  
7.1 Basics / 165 cC$YD]XdIA  
7.1.1 The Mixer / 165 8R\6hYJ%F  
7.1.2 Conversion in Receivers / 167 bL0]Yuh  
7.1.3 Spurs / 168 ,mCf{V]#  
7.1.4 Conversion in Synthesizers and Exciters / 170 U{lf$  
7.1.5 Calculators / 170 5lzbg  
7.1.6 Design Methods / 170 ]x8Y]wAU&{  
7.1.7 Example / 171 %j17QD8  
7.2 Spurious Levels / 171 W2$rC5|  
7.2.1 Dependence on Signal Strength / 171 MU] F'6V  
7.2.2 Estimating Levels / 173 ZT/
f  
7.2.3 Strategy for Using Levels / 175 }2BNy9q@  
7.3 Two-Signal IMs / 176 hB\BFVUSn/  
7.4 Power Range for Predictable Levels / 177 j+AZ!$E  
7.5 Spur Plot, LO Reference / 180 k)F!gV#  
7.5.1 Spreadsheet Plot Description / 180 :&z!o"K  
7.5.2 Example of a Band Conversion / 182 im:[ViR {  
7.5.3 Other Information on the Plot / 184 ^hEN  
7.6 Spur Plot, IF Reference / 186 s2N'Ip  
7.7 Shape Factors / 196 Dqwd=$2%  
7.7.1 Definitions / 197 og+Vr
d  
7.7.2 RF Filter Requirements / 197 SV ~QH&0'  
7.7.3 IF Filter Requirements / 200 tZ@&di:-F  
7.8 Double Conversion / 202 g9g ]X  
7.9 Operating Regions / 203 .uX(-8n ~  
7.9.1 Advantageous Regions / 203 (?XIhpd  
7.9.2 Limitation on Downconversion, MMaS  
Two-by-Twos / 206 .':17 $c`H  
7.9.3 Higher Values of m / 209 ;{iTSsb  
7.10 Examples / 211 G^|b*n!!  
7.11 Note on Spur Plots Used in This Chapter / 216 (qc<'$o  
7.12 Summary / 216 a>8]+@  
Endnotes / 217 l1 08.ao  
8 CONTAMINATING SIGNALS IN SEVERE NONLINEARITIES 219 &l{ctP%q  
8.1 Decomposition / 220 5)k/4l '  
8.2 Hard Limiting / 223 FChW`b&S  
8.3 Soft Limiting / 223 d9e~><bPJ  
xii CONTENTS ^HP$r*  
8.4 Mixers, Through the LO Port / 225 MGwXZ7?E  
8.4.1 AM Suppression / 225 *CF80
DJ  
8.4.2 FM Transfer / 226 32J/   
8.4.3 Single-Sideband Transfer / 226 F [-D +Nka  
8.4.4 Mixing Between LO Components / 228 :nnch?J_  
8.4.5 Troublesome Frequency Ranges in the LO / 228 S$wC{7?f  
8.4.6 Summary of Ranges / 235 K|~!oQ  
8.4.7 Effect on Noise Figure / 236 #vy[v22  
8.5 Frequency Dividers / 240 %(?;`  
8.5.1 Sideband Reduction / 240 vft7-|8T  
8.5.2 Sampling / 241 bfJ<~ss/  
8.5.3 Internal Noise / 242 mpD
xJk!   
8.6 Frequency Multipliers / 242 +ZE"pA^C  
8.7 Summary / 243 F!C<^q~!  
Endnotes / 244 ],R\oMYy|P  
9 PHASE NOISE 245 E'8XXV^I?P  
9.1 Describing Phase Noise / 245 !.@:t`w  
9.2 Adverse Effects of Phase Noise / 247 '{JMWNY  
9.2.1 Data Errors / 247 i+I.>L/S  
9.2.2 Jitter / 248 n3/Bs  
9.2.3 Receiver Desensitization / 249 @{<^rLt  
9.3 Sources of Phase Noise / 250 V~o'L#a  
9.3.1 Oscillator Phase Noise Spectrums / 250 k-s|gC4  
9.3.2 Integration Limits / 252 l!j=em@  
9.3.3 Relationship Between Oscillator S? and L? / 252 r`)'Kd  
9.4 Processing Phase Noise in a Cascade / 252  UiK)m:NU  
9.4.1 Filtering by Phase-Locked Loops / 253 $V<fJpA  
9.4.2 Filtering by Ordinary Filters / 254 `N}'5{I  
9.4.3 Implication of Noise Figure / 255 8rU| Oh  
9.4.4 Transfer from Local Oscillators / 255 UY.o,I>s  
9.4.5 Transfer from Data Clocks / 256
XNvl
x4  
9.4.6 Integration of Phase Noise / 258 )r*F.m{&:  
9.5 Determining the Effect on Data / 258 Pa|*Jcr  
9.5.1 Error Probability / 258 ;uZq_^?:9&  
9.5.2 Computing Phase Variance, Limits of MM@&QaK  
Integration / 259 9dp4&&Z+F  
9.5.3 Effect of the Carrier-Recovery Loop on Phase !]7L9TGn  
Noise / 260 Dg ~k"Ice  
CONTENTS xiii ), VF]  
9.5.4 Effect of the Loop on Additive 5wvh @Sc\  
Noise / 262 Jl6biJx  
9.5.5 Contribution of Phase Noise to Data fx^yC.$2  
Errors / 263 cZ.p  
9.5.6 Effects of the Low-Frequency Phase V5jy,Qi)  
Noise / 268 @2$Uk!  
9.6 Other Measures of Phase Noise / 269 ] TZ/=Id  
9.6.1 Jitter / 269 pwVGe|h%,  
9.6.2 Allan Variance / 271  V2 ;?  
9.7 Summary / 271 +y-3tcI)  
Endnote / 272 ?LvxEQ-g  
APPENDIX A OP AMP NOISE FACTOR CALCULATIONS 273 G [yI[7=d  
A.1 Invariance When Input Resistor Is Redistributed / 273 sC :.}6  
A.2 Effect of Change in Source Resistances / 274 $9Xn.,W  
A.3 Model / 276 r0'a-Mk;  
APPENDIX B REPRESENTATIONS OF FREQUENCY BANDS, yzNDXA.  
IF NORMALIZATION 279 ,MLAW  
B.1 Passbands / 279 4>HQ2S{t  
B.2 Acceptance Bands / 279 FB~IO#E8W  
B.3 Filter Asymmetry / 286 v&66F`
  
APPENDIX C CONVERSION ARITHMETIC 289 raP9rEs  
C.1 Receiver Calculator / 289 g
d]k3XN$f  
C.2 Synthesis Calculator / 291 VjiwW%UOM  
APPENDIX E EXAMPLE OF FREQUENCY CONVERSION 293 e]:(.Wb- 9  
APPENDIX F SOME RELEVANT FORMULAS 303 7.yCs[Z  
F.1 Decibels / 303 ;t.)A3 PL  
F.2 Reflection Coefficient and SWR / 304 \/Zo*/  
F.3 Combining SWRs / 306 ;Q5o38(  
F.3.1 Summary of Results / 306 6LT.ng  
F.3.2 Development / 307 #V[Os!ns  
F.3.3 Maximum SWR / 308 1yc$b+TH  
F.3.4 Minimum SWR / 309 shY8h   
F.3.5 Relaxing Restrictions / 309 `[_p,,}Ir  
F.4 Impedance Transformations in Cables / 310 3?&P^{  
F.5 Smith Chart / 310 NeewV=[%  
xiv CONTENTS e&<=+\ul  
APPENDIX G TYPES OF POWER GAIN 313 E.x<J.[Y  
G.1 Available Gain / 313 WZbRR.TxO  
G.2 Maximum Available Gain / 313 V)oKsO
 
G.3 Transducer Gain / 314 .36]>8  
G.4 Insertion Gain / 315 gb^'u  
G.5 Actual Gain / 315 cS#| _  
APPENDIX H FORMULAS RELATING TO IMs AND >(Wt  
HARMONICS 317 [/J(E\9  
H.1 Second Harmonics / 317 7zNfq.Ni~  
H.2 Second-Order IMs / 318 r8_MIGM'  
H.3 Third Harmonics / 318 l>7?B2^<E  
H.4 Third-Order IMs / 319 |Yi_|']#  
H.5 Definitions of Terms / 320 *>lXCx  
APPENDIX I CHANGING THE STANDARD IMPEDANCE 321 W=K+kB  
I.1 General Case / 321 cm>+f^4?n  
I.2 Unilateral Module / 323 >+[{m<Eq  
APPENDIX L POWER DELIVERED TO THE LOAD 325 %W2 o`W$  
APPENDIX M MATRIX MULTIPLICATION 327 /XuOv(j  
APPENDIX N NOISE FACTORS—STANDARD AND C8 $KVZ  
THEORETICAL 329 kL -f@CD  
N.1 Theoretical Noise Factor / 329 O
j7).U0;#  
N.2 Standard Noise Factor / 331 c8o2* C$  
N.3 Stan .. [hiV#  
4"+v:t)z6{  

未注册仅能浏览部分内容，查看全部内容及附件请先 登录 或 注册

Wiley.-.Ieee.-.Practical.Rf.System.Design.-.Egan is good.

这本书还不错