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

CONTENTS (eN\s98)/  
PREFACE xvii \Btv76*,  
GETTING FILES FROM THE WILEY ftp AND INTERNET SITES xix 5>q|c`&}E  
SYMBOLS LIST AND GLOSSARY xxi iU{F\>  
1 INTRODUCTION 1 kVQKP  U  
1.1 System Design Process / 1 'rU [V
+  
1.2 Organization of the Book / 2 M=e]v9  
1.3 Appendixes / 3 $r9Sn  
1.4 Spreadsheets / 3 vKDRjrF-  
1.5 Test and Simulation / 3 +is;$1rq  
1.6 Practical Skepticism / 4 X#-U  
1.7 References / 5 o8RagSIo8  
2GAIN 7 A5+vzu^  
2.1 Simple Cases / 8 }V?SedsY  
2.2 General Case / 9 ^!1mChf  
2.2.1 S Parameters / 9 KQ xKU?b1  
2.2.2 Normalized Waves / 11 JMw1qPJQ  
2.2.3 T Parameters / 12 v?)J
M+  
vii S[{#AX=0  
viii CONTENTS ge[f/"u  
2.2.4 Relationships Between S and T Parameters / 13 d$kGYMT"  
2.2.5 Restrictions on T Parameters / 14 (D{Fln\  
2.2.6 Cascade Response / 14 +%8c8]2  
2.3 Simplification: Unilateral Modules / 15 qp_k
ILo~  
2.3.1 Module Gain / 15 f5Zx:g  
2.3.2 Transmission Line Interconnections / 16 mTW0_!.  
2.3.3 Overall Response, Standard Cascade / 25 4)-LlYS_d<  
2.3.4 Combined with Bilateral Modules / 28 yEy} PCJ&  
2.3.5 Lossy Interconnections / 32 Nj qUUkc  
2.3.6 Additional Considerations / 38 -d6|D?}S  
2.4 Nonstandard Impedances / 40 v'S}&zmF]  
2.5 Use of Sensitivities to Find Variations / 40 oKiBnj5J  
2.6 Summary / 43 @P4fR7  
Endnotes / 45 #5N#^#r"  
3 NOISE FIGURE 47 MVH^["AeR  
3.1 Noise Factor and Noise Figure / 47 _UYt  
3.2 Modules in Cascade / 49 MMD4b}p  
3.3 Applicable Gains and Noise Factors / 54 "o`N6@[w^  
3.4 Noise Figure of an Attenuator / 55 Wj/.rG&tE  
3.5 Noise Figure of an Interconnect / 56 kp[+Iun?  
3.6 Cascade Noise Figure / 56 7Xm pq&g  
3.7 Expected Value and Variance of Noise Figure / 58 g` 6Xrf  
3.8 Impedance-Dependent Noise Factors / 59 SPeSe/  
3.8.1 Representation / 60 2md1GWyP  
3.8.2 Constant-Noise Circles / 61 0CQ\e1S,#  
3.8.3 Relation to Standard Noise Factor / 62 G{i}z^n  
3.8.4 Using the Theoretical Noise Factor / 64 8k]'P*9ulz  
3.8.5 Summary / 65 ~9
p*zC3M  
3.9 Image Noise, Mixers / 65 WL7R.!P  
3.9.1 Effective Noise Figure of the Mixer / 66 X26gl 'U  
3.9.2 Verification for Simple Cases / 69 1fm\5/}'`1  
3.9.3 Examples of Image Noise / 69 Zk)]=<H  
3.10 Extreme Mismatch, Voltage Amplifiers / 74 m]+g[L?-  
3.10.1 Module Noise Factor / 76 9PVM06   
3.10.2 Cascade Noise Factor / 78 $985q@pV0  
3.10.3 Combined with Unilateral Modules / 79 \D<rT)Tl  
3.10.4 Equivalent Noise Factor / 79 *;(
LKRV  
CONTENTS ix ;-lk#D?n9  
3.11 Using Noise Figure Sensitivities / 79 +L!-JrYHS4  
3.12 Mixed Cascade Example / 80 L=Fm:O'#2  
3.12.1 Effects of Some Resistor T c4N\Cy  
Changes / 81 _LFZ0  
3.12.2 Accounting for Other Reflections / 82 #]oVVf_  
3.12.3 Using Sensitivities / 82 .:*V CDOM  
3.13 Gain Controls / 84 Ti!j  
3.13.1 Automatic Gain Control / 84 D!ToCVos  
3.13.2 Level Control / 86 OnC|9  
3.14 Summary / 88 "?EA G  
Endnotes / 90 kz(%8qi8&  
4 NONLINEARITY IN THE SIGNAL PATH 91 dOqn0Z  
4.1 Representing Nonlinear Responses / 91 (01M0b#  
4.2 Second-Order Terms / 92 :z56!qU  
4.2.1 Intercept Points / 93 cV_nYcLkz  
4.2.2 Mathematical Representations / 95 Lf&p2p?~c  
4.2.3 Other Even-Order Terms / 97 H ZIJKk(  
4.3 Third-Order Terms / 97 PtCwr)B,  
4.3.1 Intercept Points / 99 Y{B|*[xM  
4.3.2 Mathematical Representations / 100 mZDrvTI'  
4.3.3 Other Odd-Order Terms / 101 .%h.b6^  
4.4 Frequency Dependence and Relationship >o>r@;  
Between Products / 102 AiykIER/  
4.5 Nonlinear Products in the Cascades / 103 l!<Nw8+U  
4.5.1 Two-Module Cascade / 104 :kfHILi  
4.5.2 General Cascade / 105 l&(,$RmYp  
4.5.3 IMs Adding Coherently / 106 Xlpu_H|  
4.5.4 IMs Adding Randomly / 108 K~5QL/=1  
4.5.5 IMs That Do Not Add / 109 wLPL9  
4.5.6 Effect of Mismatch on IPs / 110 :Oo(w%BD]  
4.6 Examples: Spreadsheets for IMs in a p-GlGEt_X  
Cascade / 111 ><viJ$i  
4.7 Anomalous IMs / 115 h)"PPI  
4.8 Measuring IMs / 116 ((\s4-  
4.9 Compression in the Cascade / 119 29 L~SMf  
4.10 Other Nonideal Effects / 121 aIpDf|~  
4.11 Summary / 121 KcglpKV`  
Endnote / 122 j` 9pZAF  
x CONTENTS KtUI(*$`  
5 NOISE AND NONLINEARITY 123 {v}f/cu  
5.1 Intermodulation of Noise / 123 Gmi4ffIb3  
5.1.1 Preview / 124 u{,e8. Z  
5.1.2 Flat Bandpass Noise / 125 qgvg MWj  
5.1.3 Second-Order Products / 125 AdesR-e$R  
5.1.4 Third-Order Products / 130 $U<so{xn%  
5.2 Composite Distortion / 133 NQ_H-D\,  
5.2.1 Second-Order IMs (CSO) / 134 Vz!W(+  
5.2.2 Third-Order IMs (CTB) / 136 WLQm|C,  
5.2.3 CSO and CTB Example / 136 9; HR  
5.3 Dynamic Range / 137 `=RJ8u  
5.3.1 Spurious-Free Dynamic Range / 137 p3`'i  
5.3.2 Other Range Limitations / 139 SG2s!Ht  
5.4 Optimizing Cascades / 139 [nJ),9$z_  
5.4.1 Combining Parameters on One Spreadsheet / 139 (n05MwKu\  
5.4.2 Optimization Example / 143 I#zrz3WU  
5.5 Spreadsheet Enhancements / 146 "GEJ9_a[  
5.5.1 Lookup Tables / 146 ".O+";wk  
5.5.2 Using Controls / 147 YQvN;W  
5.6 Summary / 147 \]e"#"v}}_  
Endnotes / 147 :D8V*F6P  
6 ARCHITECTURES THAT IMPROVE LINEARITY 149 ZMy0iQ@  
6.1 Parallel Combining / 149 \C5YVl#  
? bX:Y5o49  
6.1.1 90 Hybrid / 150 |G~LJsXW!v  
? ^]3Y11sI  
6.1.2 180 Hybrid / 152 3*"
$E_%  
6.1.3 Simple Push–Pull / 154 o"->RC  
6.1.4 Gain / 155 V~tq _  
6.1.5 Noise Figure / 156 r`pg`ChHv  
6.1.6 Combiner Trees / 156 G4vXPx%a8  
6.1.7 Cascade Analysis of a Combiner Tree / 157 Zj99]4?9  
6.2 Feedback / 158 Q>] iRx>MZ  
6.3 Feedforward / 159 2--"@@  
6.3.1 Intermods and Harmonics / 160 UM(tM9  
6.3.2 Bandwidth / 161 FN NEh  
6.3.3 Noise Figure / 161 s"#JBw\7  
6.4 Nonideal Performance / 162 %Wkvo-rOq  
6.5 Summary / 163 NDEltG(  
Endnotes / 163 "~0m_brf  
CONTENTS xi ^6bU4bA  
7 FREQUENCY CONVERSION 165 nR-`;lrF~  
7.1 Basics / 165 I$9^i#O'3  
7.1.1 The Mixer / 165 +pZ, RW.D  
7.1.2 Conversion in Receivers / 167 U+F?b\  
7.1.3 Spurs / 168 m{  .'55  
7.1.4 Conversion in Synthesizers and Exciters / 170 t8DySFT  
7.1.5 Calculators / 170 ~^cx a%  
7.1.6 Design Methods / 170 iY1%"x  
7.1.7 Example / 171 eEePK~%c  
7.2 Spurious Levels / 171 IqJ7'X  
7.2.1 Dependence on Signal Strength / 171 uV!Ax*'  
7.2.2 Estimating Levels / 173 x+x6F  
7.2.3 Strategy for Using Levels / 175 NK2Kw{c"iI  
7.3 Two-Signal IMs / 176 9E4H`[EQ  
7.4 Power Range for Predictable Levels / 177 $@"o BCc  
7.5 Spur Plot, LO Reference / 180 o7)<pfif  
7.5.1 Spreadsheet Plot Description / 180 N@lTn}U  
7.5.2 Example of a Band Conversion / 182 8Eyi`~cAiH  
7.5.3 Other Information on the Plot / 184 n#[-1(P  
7.6 Spur Plot, IF Reference / 186 >j5) MF{"  
7.7 Shape Factors / 196 0f}zm8p7.  
7.7.1 Definitions / 197 A9' [x7N  
7.7.2 RF Filter Requirements / 197 `[p*qsp_  
7.7.3 IF Filter Requirements / 200 wWv")dk3i  
7.8 Double Conversion / 202 zV_U/]y  
7.9 Operating Regions / 203 HpSmB[WF  
7.9.1 Advantageous Regions / 203 W+-a@)sh3Q  
7.9.2 Limitation on Downconversion, jFY6}WY)}7  
Two-by-Twos / 206 +dw$IMwb  
7.9.3 Higher Values of m / 209 N=^{FZ  
7.10 Examples / 211 _fx0-S*$  
7.11 Note on Spur Plots Used in This Chapter / 216 mD{<Lp=  
7.12 Summary / 216 '^)Ve:K-.  
Endnotes / 217 OvqCuX  
8 CONTAMINATING SIGNALS IN SEVERE NONLINEARITIES 219 ")'o5V  
8.1 Decomposition / 220 kNP.0  
8.2 Hard Limiting / 223 17AJT  
8.3 Soft Limiting / 223 wYQTG*&h  
xii CONTENTS ||a 5)D  
8.4 Mixers, Through the LO Port / 225 =p,+a/*  
8.4.1 AM Suppression / 225 kwU~kcM  
8.4.2 FM Transfer / 226 P,r9<  
8.4.3 Single-Sideband Transfer / 226 =QFnab?N  
8.4.4 Mixing Between LO Components / 228 23 j{bK  
8.4.5 Troublesome Frequency Ranges in the LO / 228 ~G|u
n}g=  
8.4.6 Summary of Ranges / 235 "jqC3$DKI  
8.4.7 Effect on Noise Figure / 236 knrR%e;  
8.5 Frequency Dividers / 240 QlmZBqK}&  
8.5.1 Sideband Reduction / 240 C` ?6`$Y  
8.5.2 Sampling / 241 -.-je"E  
8.5.3 Internal Noise / 242 "| 0g 1rd  
8.6 Frequency Multipliers / 242 -Zx hh  
8.7 Summary / 243 NWWa
g}  
Endnotes / 244 DG,CL8bv  
9 PHASE NOISE 245 20750G  
9.1 Describing Phase Noise / 245 qR^KvAEQSo  
9.2 Adverse Effects of Phase Noise / 247 ]#=43  
9.2.1 Data Errors / 247 !Z[dK{f"  
9.2.2 Jitter / 248 Dnn$-W|NC  
9.2.3 Receiver Desensitization / 249 ,3l=44*  
9.3 Sources of Phase Noise / 250 8.FBgZh*  
9.3.1 Oscillator Phase Noise Spectrums / 250 EN/>f=%  
9.3.2 Integration Limits / 252 tgXIj5z  
9.3.3 Relationship Between Oscillator S? and L? / 252 q"xIW0Pc  
9.4 Processing Phase Noise in a Cascade / 252 NSH20$A<  
9.4.1 Filtering by Phase-Locked Loops / 253 hfT HP  
9.4.2 Filtering by Ordinary Filters / 254 "~jSG7h  
9.4.3 Implication of Noise Figure / 255 _Mq0QQ42  
9.4.4 Transfer from Local Oscillators / 255 ^j&'2n@9a  
9.4.5 Transfer from Data Clocks / 256 q
plz !=  
9.4.6 Integration of Phase Noise / 258 VN`T:!&  
9.5 Determining the Effect on Data / 258 qu- !XC0p  
9.5.1 Error Probability / 258 Rj 2N+59rg  
9.5.2 Computing Phase Variance, Limits of 7OY<*ny  
Integration / 259 5$Lo]H*  
9.5.3 Effect of the Carrier-Recovery Loop on Phase gdkl,z3N3  
Noise / 260 Seh[".l  
CONTENTS xiii ,RIGV[u  
9.5.4 Effect of the Loop on Additive SFCKD/8  
Noise / 262 VP[
-BK[  
9.5.5 Contribution of Phase Noise to Data M:x?I_JG8  
Errors / 263 4+%;eY.A  
9.5.6 Effects of the Low-Frequency Phase i
J.P&T9  
Noise / 268 `X[L62D  
9.6 Other Measures of Phase Noise / 269 Z0*Lm+d9z  
9.6.1 Jitter / 269 MDn+K#
p  
9.6.2 Allan Variance / 271 37GJ}%Qs  
9.7 Summary / 271 [SGt ~bRJ  
Endnote / 272 eFDhJ  
APPENDIX A OP AMP NOISE FACTOR CALCULATIONS 273 c&r8q]u  
A.1 Invariance When Input Resistor Is Redistributed / 273 PkA_uDhw  
A.2 Effect of Change in Source Resistances / 274 kXimJL_<g  
A.3 Model / 276 ~wG.'d]  
APPENDIX B REPRESENTATIONS OF FREQUENCY BANDS, 8:^`rw4a0  
IF NORMALIZATION 279 ?&#z3c$}  
B.1 Passbands / 279 c@9jc^CJ  
B.2 Acceptance Bands / 279 ;d$PQi  
B.3 Filter Asymmetry / 286 l9"4"+?j<  
APPENDIX C CONVERSION ARITHMETIC 289 ?mKj+Bk2  
C.1 Receiver Calculator / 289 EOJk7  
C.2 Synthesis Calculator / 291 7 j$ |fS  
APPENDIX E EXAMPLE OF FREQUENCY CONVERSION 293 (qd$wv^h  
APPENDIX F SOME RELEVANT FORMULAS 303 <tkxE!xF`J  
F.1 Decibels / 303 k$ k/U  
F.2 Reflection Coefficient and SWR / 304 Lt ;!q b.  
F.3 Combining SWRs / 306 [<SM*fQ>t  
F.3.1 Summary of Results / 306 W:D'k^u  
F.3.2 Development / 307 G{$(t\>8  
F.3.3 Maximum SWR / 308 Q-([3%  
F.3.4 Minimum SWR / 309 Tdtn-  
F.3.5 Relaxing Restrictions / 309 P\<dy?nZ  
F.4 Impedance Transformations in Cables / 310 cpz'upVOZ  
F.5 Smith Chart / 310 /MFy%=0l  
xiv CONTENTS fFP>$  
APPENDIX G TYPES OF POWER GAIN 313 XQL"D)fw  
G.1 Available Gain / 313 [0|g3K!A  
G.2 Maximum Available Gain / 313 %qA@)u53  
G.3 Transducer Gain / 314 U:6 J~  
G.4 Insertion Gain / 315 3 $7TeqfAC  
G.5 Actual Gain / 315 &"GHD{ix  
APPENDIX H FORMULAS RELATING TO IMs AND )9'eckt  
HARMONICS 317 3C'`c=  
H.1 Second Harmonics / 317 `k y>M-  
H.2 Second-Order IMs / 318 cx%[hM09  
H.3 Third Harmonics / 318 ;%"YA  
H.4 Third-Order IMs / 319
c@u)m}V  
H.5 Definitions of Terms / 320 s/[15  
APPENDIX I CHANGING THE STANDARD IMPEDANCE 321 ZqKUz5M4  
I.1 General Case / 321 S~jl%]  
I.2 Unilateral Module / 323 P<P4*cOV  
APPENDIX L POWER DELIVERED TO THE LOAD 325 Y"qKe,
  
APPENDIX M MATRIX MULTIPLICATION 327 |Y'xtOMX  
APPENDIX N NOISE FACTORS—STANDARD AND rN6@=uB  
THEORETICAL 329  E~oQ%X~  
N.1 Theoretical Noise Factor / 329 }p-<+sFo  
N.2 Standard Noise Factor / 331 ,4dES|)sP  
N.3 Stan .. ]jo^P5\h>  
"0x"Xw#I  

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