Electrical Circuit Theory and Technology John Bird 3Ed 2007

Electrical Circuit Theory and Technology ~'2im[f J  
John Bird i&dMX:fRd  
3rd Edition  %Jc>joU  
2007 ua!g}m
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Electrical Circuit Theory and Technology John Bird 3Ed 2007.part1.rar (2930 K) 下载次数:23 a,U@ !}K  
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Electrical Circuit Theory and Technology John Bird 3Ed 2007.part2.rar (2756 K) 下载次数:26 2eh j2T  
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[contents]
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Part 1 BasicElectrical Engineering Principles Ug|o($CY  
1 Units Associated with Basic ElectricalQuantities l TJqWSV=f  
1.1 SI Units L?5OWVX!v  
1.2 Charge Y8yRQzu  
1.3 Force * 5Y.9g3)Q  
1.4 Work |.zotEh  
1.5 Power :,^pLAt  
1.6 Electrical Potential and E.M.F. 2o5v{W  
1.7 Resistance and Conductance _F1{<" 4  
1.8 Electrical Power and Energy ^v].mV/  
1.9 Summary of Terms, Units and TheirSymbols I=3e@aTZ,  
2 An Introduction to Electric Circuits d.3O1TXK  
2.1 Standard Symbols for ElectricalComponents e!(0y)*  
2.2 Electric Current and Quantity ofElectricity "nK(+Z  
2.3 Potential Difference andResistance zu Jl #3YP  
2.4 Basic Electrical MeasuringInstruments (SlrV8;  
2.5 Linear and Non-Linear Devices GL_a`.=@  
2.6 Ohm’s Law HLy}ta\
 
2.7 Multiples and Sub-Multiples iEf6oM  
2.8 Conductors and Insulators L('G1J}  
2.9 Electrical Power and Energy 6:Nz=sw8  
2.10 Main Effects of Electric Current "wPFQXU  
2.11 Fuses  }Rc8\,  
3 Resistance Variation OgTE^W@  
3.1 Resistance and Resistivity $*{$90Q  
3.2 Temperature Coefficient ofResistance U&mJ_f#M  
4 Batteries ( |1 $zF+  
4.1 Introduction to Batteries b:}`O!UBw  
4.2 Some Chemical Effects ofElectricity 43;@m}|7$  
4.3 The Simple Cell ReCmv/AE  
4.4 Corrosion G'<J8;B* t  
4.5 E.M.F. and Internal Resistance ofa Cell LyB$~wZx~@  
4.6 Primary Cells <4W"ne28  
4.7 Secondary Cells t?0D*!D  
4.8 Cell Capacity $z+iB;x  
4.9 Safe Disposal of Batteries .FnO  
4.10 Fuel Cells y^gazr"  
4.11 Alternative and Renewable EnergySources k]Y#-Q1p~  
Revision Test 1 `1NxS35u  
5 Series and Parallel Networks $e|G#mMd-  
5.1 Series Circuits {q1&4U~'>O  
5.2 Potential Divider S4]xxc  
5.3 Parallel Networks nr>g0_%m  
5.4 Current Division ]8q5k5
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5.5 Relative and Absolute Voltages \"qXlTQ1_9  
5.6 Wiring Lamps in Series and inParallel pX]*&[X?  
6 Capacitors and Capacitance PomX@N}1  
6.1 Introduction to Capacitors ?zKVXK7}0  
6.2 Electrostatic Field .d5|Fs~B  
6.3 Electric Field Strength FV/X&u8~  
6.4 Capacitance W.ud<OKP90  
6.5 Capacitors d{f3R8~Q.  
6.6 Electric Flux Density ! G%LYHx  
6.7 Permittivity ^ZFbp@#U  
6.8 The Parallel Plate Capacitor m%$z&<!  
6.9 Capacitors Connected in Paralleland Series daaEN(  
6.10 Dielectric Strength 'A,&9E{%1  
6.11 Energy Stored ZbYwuyHk(3  
6.12 Practical Types of Capacitor 0:**uion  
6.13 Discharging Capacitors $.}fL;BzVz  
7 Magnetic Circuits '!!w|kd  
7.1 Introduction to Magnetism andMagnetic Circuits ?J+[|*'yK  
7.2 Magnetic Fields Wx&AY"J  
7.3 Magnetic Flux and Flux Density !b*lL#s,Y  
7.4 Magnetomotive Force and MagneticField Strength w.cQ|_  
7.5 Permeability and B–H Curves ?kew[oZ  
7.6 Reluctance Ho?+?YJ#P  
7.7 Composite Series MagneticCircuits ` BH8v  
7.8 Comparison Between Electrical andMagnetic Quantities P sD+?  
7.9 Hysteresis and Hysteresis Loss :YB:)wV,P  
Revision Test 2 :eI.E:/'  
8 Electromagnetism ,{7wvXP  
8.1 Magnetic Field Due to an ElectricCurrent "JSg/optc  
8.2 Electromagnets e+=Ojo#  
8.3 Force on a Current-CarryingConductor bG>pm|/  
8.4 Principle of Operation of aSimple D.C. Motor g?M\Z";  
8.5 Principle of Operation of aMoving Coil Instrument HB\y [:E  
8.6 Force on a Charge /40Z-'Bl=(  
9 Electromagnetic Induction JW&/l  
9.1 Introduction to ElectromagneticInduction f3-=?Z  
9.2 Laws of Electromagnetic Induction UUv&X+Y  
9.3 Rotation of a Loop in a MagneticField g!7/iKj:  
9.4 Inductance Nora<  
9.5 Inductors (^eS
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9.6 Energy Stored TD,W*(b  
9.7 Inductance of a Coil PDX
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9.8 Mutual Inductance {so"xoA^c  
10 Electrical Measuring Instruments andMeasurements 7I`e5\ u  
10.1 Introduction _{,e-_hYM  
10.2 Analogue Instruments N40.GL0s  
10.3 Moving-Iron Instrument KS'? DO  
10.4 The Moving-Coil RectifierInstrument K3?7Hndf2  
10.5 Comparison of Moving-Coil,Moving-Iron and Moving-Coil Rectifier Instruments sRo%=7Z  
10.6 Shunts and Multipliers +J$[RxQ#  
10.7 Electronic Instruments =4y
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10.8 The Ohmmeter 84 _U$d.B'*)z  
10.9 Multimeters #HB]qa  
10.10 Wattmeters pq>"GEN  
10.11 Instrument ‘Loading’ Effect G3 #c  
10.12 The Oscilloscope -zHJ#
 
10.13 Virtual Test and MeasuringInstruments PP&AF?C  
10.14 Virtual Digital StorageOscilloscopes UioLu90 P  
10.15 Waveform Harmonics /wI$}X5o~  
10.16 Logarithmic Ratios l{aXX[E&1  
10.17 Null Method of Measurement 5_M9T3  
10.18 Wheatstone Bridge IZ3w.:A  
10.19 D.C. Potentiometer E$f.&<>T  
10.20 A.C. Bridges ]BCH9%zLj  
10.21 Measurement Errors vN7a)s  
11 Semiconductor Diodes suaTXKjyk+  
11.1 Types of Material B4GgR,P@S  
11.2 Semiconductor Materials G F,/<R#  
11.3 Conduction in SemiconductorMaterials @y9_\mX!s  
11.4 The P-N Junction "sf8~P9qy  
11.5 forward and Reverse Bias 6{
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11.6 Semiconductor Diodes A;w,m{9<  
11.7 Characteristics and MaximumRatings 6ndt1W z  
11.8 Rectification L]kSj$A  
11.9 Zener Diodes T\b e(@r  
11.10 Silicon Controlled Rectifiers F)lDK.  
11.11 Light Emitting Diodes eqs.zL  
11.12 Varactor Diodes V?HC\F-  
11.13 Schottky Diodes 3Zdkf]Gh  
12 Transistors {
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12.1 Transistor Classification qbHb24I  
12.2 Bipolar Junction Transistors(BJT) GK
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12.3 Transistor Action sju. `f>-r  
12.4 Leakage Current 3yDa5q{  
12.5 Bias and Current Flow Kw&J<H  
12.6 Transistor OperatingConfigurations #+QwRmJdT!  
12.7 Bipolar TransistorCharacteristics v%=G~kF}[  
12.8 Transistor Parameters, 118 4'?
kyTO~  
12.9 Current Gain N4}/n  
12.10 Typical BJT Characteristics andMaximum Ratings g-meJhX%  
12.11 Field Effect Transistors !iCY!:  
12.12 Field Effect TransistorCharacteristics MaXgy|yB1  
12.13 Typical FET Characteristics andMaximum Ratings vz,l{0v  
12.14 Transistor Amplifiers 5>"$95D  
12.15 Load Lines Tw`^  
Revision Test 3 JpxJZJ  
Main formulae for Part 1  hPx=3L$  
Part 2 ElectricalPrinciples and Technology Cz Jze  
13 D.C. Circuit Theory me$7\B;wy  
13.1 Introduction nod?v2%   
13.2 Kirchhoff’s Laws Dx/?0F7V  
13.3 The Superposition Theorem lzfaW-nu  
13.4 General D.C. Circuit Theory &I:5<zK{  
13.5 Thevenin’s Theorem ]U! ?{~  
13.6 Constant-Current Source Bh"o{-$p8`  
13.7 Norton’s Theorem nv*q N\i'  
13.8 Thevenin and Norton EquivalentNetworks z(aei(U=  
13.9 Maximum Power Transfer Theorem y!."FoQ  
14 Alternating Voltages and Currents d5\w'@Di  
14.1 Introduction `3SY~&X  
14.2 The A.C. Generator n4Ry)O[.  
14.3 Waveforms 55Y BO
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14.4 A.C. Values d11~mU\  
14.5 The Equation of a SinusoidalWaveform ON~SZa  
14.6 Combination of Waveforms gsqlWfa  
14.7 Rectification 60*2k  
Revision Test 4 ,*Tf9=z  
15 Single-Phase Series A.C. Circuits Nqk*3Q"f  
15.1 Purely Resistive A.C. Circuit sikG}p0mx<  
15.2 Purely Inductive A.C. Circuit D?)91P/R  
15.3 Purely Capacitive A.C. Circuit CQW#o_\  
15.4 R–L Series A.C. Circuit LS+ _y<v=  
15.5 R–C Series A.C. Circuit fDNiU"  
15.6 R–L–C Series A.C. Circuit B4r4PSB>!  
15.7 Series Resonance * h!gjbi  
15.8 Q-Factor /G9wW+1  
15.9 Bandwidth and Selectivity G}&B{Ir  
15.10 Power in A.C. Circuits vXAO#'4tm%  
15.11 Power Triangle and Power Factor xJa  
16 Single-Phase Parallel A.C. Circuits :,Q\!s!  
16.1 Introduction 6FiI\  
16.2 R–L Parallel A.C. Circuit [DC8X P5<  
16.3 R–C Parallel A.C. Circuit 0hnN>?  
16.4 L–C Parallel A.C. Circuit 3u^U\xB  
16.5 LR–C Parallel A.C. Circuit b\Y<1EV^
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16.6 Parallel Resonance and Q-Factor Vi?[yu<F  
16.7 Power Factor Improvement y9{KBM%h  
17 D.C. Transients (Gp/^[.%&  
17.1 Introduction 0WaC.C+2i  
17.2 Charging a Capacitor <3m_} =\  
17.3 Time Constant for a C–R Circuit
$5jQm,V$K  
17.4 Transient Curves for a C–RCircuit 3J32W@}.K  
17.5 Discharging a Capacitor >u ,Ac:  
17.6 Camera Flash %(MaH  
17.7 Current Growth in an L–R Circuit 9i*t3W71]  
17.8 Time Constant for an L–R Circuit [ma'11?G  
17.9 Transient Curves for an L–RCircuit |77.Lqqy,  
17.10 Current Decay in an L–RCircuit, 208 z8G1[ElY  
17.11 Switching Inductive Circuits "9jt2@<  
17.12 The Effect of Time Constant ona Rectangular Waveform lRF04  
18 Operational Amplifiers `|Pfa  
18.1 Introduction to OperationalAmplifiers / Of*II&  
18.2 Some Op Amp Parameters J70#pF  
18.3 Op Amp inverting Amplifier f',n'  
18.4 Op Amp Non-inverting Amplifier ?{NP3  
18.5 Op Amp Voltage-Follower "-88bF~  
18.6 Op Amp Summing Amplifier p#wQW[6  
18.7 Op Amp Voltage Comparator 1N{}G$'Go  
18.8 Op Amp Integrator !1$QNx
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18.9 Op Amp Differential Amplifier ~,WG284  
18.10 Digital to Analogue (D/A)Conversion pwtB{6)VH{  
18.11 Analogue to Digital (A/D)Conversion xeF0^p7Z  
Revision Test 5 zRd^Uks  
19 Three-Phase Systems rU=qr&f"B  
19.1 Introduction 5I`j'j  
19.2 Three-Phase Supply ig5 d-A  
19.3 Star Connection y[:\kI  
19.4 Delta Connection 3gV 17a  
19.5 Power in Three-Phase Systems y
{ %2Q)  
19.6 Measurement of Power in ThreePhase Systems 1@rI4U@D  
19.7 Comparison of Star and DeltaConnections r:]t9y>$<  
19.8 Advantages of Three-PhaseSystems "SJp9s3  
20 Transformers l\xcR]O  
20.1 Introduction  S<#>g s4  
20.2 Transformer Principle ofOperation 1G$fU zS  
20.3 Transformer No-Load PhasorDiagram `U?" {;j {  
20.4 E.M.F. Equation of a Transformer {}kE=L5  
20.5 Transformer On-Load PhasorDiagram V9&7K65-1  
20.6 Transformer Construction SR)G!9z_/  
20.7 Equivalent Circuit of aTransformer S {oW  
20.8 Regulation of a Transformer }^U7NZn<"  
20.9 Transformer Losses andEfficiency 2$?bLvk  
20.10 Resistance Matching I(tMw6C$:  
20.11 Auto Transformers <E/4/ ANN  
20.12 Isolating Transformers g X75zso  
20.13 Three-Phase Transformers y.(Yh1  
20.14 Current Transformers _&)^a)Nu  
20.15 Voltage Transformers v._Q XcE  
Revision Test 6 Hof@,w  
21 D.C. Machines M3P
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21.1 Introduction
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21.2 The Action of a Commutator y.PWh<dI  
21.3 D.C. Machine Construction _;L%? -2c  
21.4 Shunt, Series and CompoundWIndings qM= $,s*  
21.5 E.M.F. Generated in an ArmatureWInding _uwM%M;  
21.6 D.C. Generators 44C"Pl E u  
21.7 Types of D.C. Generator andTheir Characteristics *(wkgn  
21.8 D.C. Machine Losses %Xc50n2Z  
21.9 Efficiency of a D.C. Generator @SeInew;`l  
21.10 D.C. Motors N3O3V5':!  
21.11 Torque of a D.C. Machine wX5Yo{  
21.12 Types of D.C. Motor and TheirCharacteristics R+{QZ'K.qg  
21.13 The Efficiency of a D.C. Motor .'foS>W=t  
21.14 D.C. Motor Starter w=Ai?u  
21.15 Speed Control of D.C. Motors HY
-7{irR~  
21.16 Motor Cooling +yY
xHIOZ(  
22 Three-Phase Induction Motors /e5' YVP  
22.1 Introduction ;w>Dqem  
22.2 Production of a RotatingMagnetic Field KmS$CFsGL  
22.3 Synchronous Speed KZrg4TEVi  
22.4 Construction of a Three-PhaseInduction Motor omz%:'m`~  
22.5 Principle of Operation of aThree Phase Induction Motor {9?++G"\  
22.6 Slip \OPJ*/U  
22.7 Rotor E.M.F. and Frequency .TZ0FxW  
22.8 Rotor Impedance and Current 7X 4/6]*  
22.9 Rotor Copper Loss 7QV@lR<C2R  
22.10 Induction Motor Losses andEfficiency -':;0  
22.11 Torque Equation for anInduction Motor zwJB.4@  
22.12 Induction Motor Torque–SpeedCharacteristics 6d~[j<@2  
22.13 Starting Methods for InductionMotors dpAj9CX(  
22.14 Advantages of Squirrel-CageInduction Motors ~5`p/.L)ZD  
22.15 Advantages of Wound RotorInduction Motor, 290 (bhMo^3/*  
22.16 Double Cage Induction Motor <14,xYpE  
22.17 Uses of Three-Phase InductionMotors ~EIK  
Revision Test 7 z`g4
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Main formulae for Part 2 TwPpZ
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Part 3 AdvancedCircuit Theory and Technology D)shWJRlvW  
23 Revision of Complex Numbers g Va;!  
23.1 Introduction (sM$=M<$  
23.2 Operations involving CartesianComplex Numbers
HGycF|]2  
23.3 Complex Equations %!P^se  
23.4 The Polar form of a ComplexNumber rtM29~c>@  
23.5 Multiplication and DivisionUsing Complex Numbers in Polar form hc7"0mVd{  
23.6 De Moivre’s Theorem — Powers andRoots of Complex Numbers pQ~Y7  
24 Application of Complex Numbers to SeriesA.C. Circuits #h=pU/R  
24.1 Introduction 10tlD<eYb  
24.2 Series A.C. Circuits ;OC~,?O5  
24.3 Further Worked Problems onSeries A.C. Circuits ^.3(o{g  
25 Application of Complex Numbers toParallel A.C. Networks Q9T/@FX  
25.1 Introduction 78M%[7Cq<i  
25.2 Admittance Conductance andSusceptance wFbw3>'a9  
25.3 Parallel A.C. Networks m[aBHA^g  
25.4 Further Worked Problems onParallel A.C. Networks <S[]VXy  
26 Power in A.C. Circuits b'AA*v,b  
26.1 Introduction 7Eb |AR  
26.2 Determination of Power in A.C.Circuits ZG(.Q:1  
26.3 Power Triangle and Power Factor `L~gERW#  
26.4 Use of Complex Numbers forDetermination of Power ?,XrZRF  
26.5 Power Factor Improvement d23;c )'  
Revision Test 8 s!73To}>  
27 A.C. Bridges n[[2<s*YJ  
27.1 Introduction >wSrllmj@  
27.2 Balance Conditions for an A.C.Bridge S?Y%
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27.3 Types of A.C. Bridge Circuit ]?p 9)d=%<  
27.4 Worked Problems on A.C. Bridges r4MPs-}oF  
28 Series Resonance and Q-Factor =;L44.,g  
28.1 Introduction Cx~,wk;=  
28.2 Series Resonance jJ.isr|`  
28.3 Q-Factor ,"en7  
28.4 Voltage Magnification y@XE! L  
28.5 Q-Factors in Series pu-X -j  
28.6 Bandwidth 0*J},#ba$  
28.7 Small Deviations From theResonant Frequency ]v2%hX  
29 Parallel Resonance and Q-Factor m!Y4+KTwD`  
29.1 Introduction G^1 5V'*  
29.2 The LR–C Parallel Network H8
!; XB  
29.3 Dynamic Resistance F)8M9%g5m  
29.4 The LR–CR Parallel Network 4H9mKR  
29.5 Q-Factor in a Parallel Network WRCf[5  
29.6 Further Worked Problems onParallel Resonance and Q-Factor "udA-;!@&  
Revision Test 9 xaN[ru@  
30 Introduction to Network Analysis 5,_DM  
30.1 Introduction _ASyGmO{  
30.2 Solution of SimultaneousEquations Using Determinants z:1"d R   
30.3 Network Analysis UsingKirchhoff’s Laws "!S7D>2y#  
31 Mesh-Current and Nodal Analysis 1S{AGgls5  
31.1 Mesh-Current Analysis Wf!u?nH.5  
31.2 Nodal Analysis z(!K8 T  
32 The Superposition Theorem hQb3 8W[  
32.1 Introduction ntr&? H  
32.2 Using the Superposition Theorem ]0o_- NI  
32.3 Further Worked Problems on theSuperposition Theorem `8 Ann~Z|k  
33 Thévenin’s and Norton’s Theorems tUGnp'r  
33.1 Introduction ee2k..Tq#  
33.2 Thevenin’s Theorem ,DL%oQR  
33.3 Further Worked Problems onThevenin’s Theorem yDapl(  
33.4 Norton’s Theorem Kcu*Z  
33.5 Thevenin and Norton EquivalentNetworks 'Lu d=u{  
Revision Test 10 "?AJ(>wP  
34 Delta-Star and Star-DeltaTransformations g:oB j6$ q  
34.1 Introduction R4_B
P5+  
34.2 Delta and Star Connections ]]Fe:>  
34.3 Delta-Star Transformation }'`iJb\  
34.4 Star-Delta Transformation 61SbBJ6[  
35 Maximum Power Transfer Theorems andImpedance Matching f]4j7K!e]  
35.1 Maximum Power Transfer Theorems |S6L[Uo  
35.2 Impedance Matching *-eDUT|O  
Revision Test 11 ~'#yH#o  
36 Complex Waveforms byJR6f  
36.1 Introduction 0n/+X[%Ti  
36.2 The General Equation for a ComplexWaveform oUd R,;h9  
36.3 Harmonic Synthesis Xk>YiV",?  
36.4 Fourier Series of Periodic andNon-Periodic Functions FZBdQhYF  
36.5 Even and Odd Functions andFourier Series Over Any Range 4k_y;$4WN  
36.6 Rms Value, Mean Value and theform Factor of a Complex Wave gmUX 2x(  
36.7 Power Associated with ComplexWaves jvQpfd  
36.8 Harmonics in Single-PhaseCircuits 'ZFbyt Q2  
36.9 Further Worked Problems onHarmonics in Single-Phase Circuits <Z j>}
 
36.10 Resonance Due to Harmonics a7
U`/*  
36.11 Sources of Harmonics e;8nujdG"  
37 A Numerical Method of Harmonic Analysis bHRRgR`,  
37.1 Introduction Mp`!zwR  
37.2 Harmonic Analysis on Data Givenin Tabular Or Graphical form 230ijq3YG  
37.3 Complex Waveform Considerations #O1%k;BL  
38 Magnetic Materials "}Oj N\  
38.1 Revision of Terms and Units Usedwith Magnetic Circuits $y_P14   
38.2 Magnetic Properties of Materials U[O7}Nsb"  
38.3 Hysteresis and Hysteresis Loss !sVW0JSh  
38.4 Eddy Current Loss T9NTL
\;  
38.5 Separation of Hysteresis andEddy Current Losses aY8QYK ;?^  
38.6 Non-Permanent Magnetic Materials Uz_OUTFM  
38.7 Permanent Magnetic Materials v"YaMbu  
Revision Test 12 gP2<L5&Z,  
39 Dielectrics and Dielectric Loss X1XmaO%A  
39.1 Electric Fields, Capacitance andPermittivity i%GNmD  
39.2 Polarization 2TccIv  
39.3 Dielectric Strength rM0Idc.$&&  
39.4 Thermal Effects F\2<q$Zn+  
39.5 Mechanical Properties N{&Hq4^c  
39.6 Types of Practical Capacitor Dqg01_O9O  
39.7 Liquid Dielectrics and GasInsulation {d '>J<Da  
39.8 Dielectric Loss and Loss Angle =))VxuoN  
40 Field Theory &HBC9Bx/(  
40.1 Field Plotting By CurvilinearSquares ?_`X8Ok  
40.2 Capacitance Between ConcentricCylInders cU_:l.b  
40.3 Capacitance of an Isolated TwinLine ,1 ^IFBJ  
40.4 Energy Stored in an ElectricField g3| 62uDF  
40.5 Induced E.M.F. and Inductance bLSUF`-z  
40.6 Inductance of a Concentric CylInder(Or Coaxial Cable) ^&7gUH*v  
40.7 Inductance of an Isolated TwinLine DQ.;2W  
40.8 Energy Stored in anElectromagnetic Field G-[.BWQ   
41 Attenuators *J3Z.fq%:i  
41.1 Introduction @/8O@^
 
41.2 Characteristic Impedance \Lg{GN.  
41.3 Logarithmic Ratios |wM<n  
41.4 Symmetrical T- and ?-Attenuators p~yGp]yJ9  
41.5 Insertion Loss ms6dl-_t  
41.6 Asymmetrical T- and ?-Sections VmON}bb[zz  
41.7 The L-Section Attenuator Z8I0v$LjR  
41.8 Two-Port Networks in Cascade $O^"OQ_@  
41.9 ABCD Parameters ih=O#f|  
41.10 ABCD Parameters for Networks ==npFjB  
41.11 Characteristic Impedance inTerms of ABCD Parameters 63SmQsv  
Revision Test 13 -\&b&;_  
42 Filter Networks UO(?EELm  
42.1 Introduction Ksff]##H  
42.2 Basic Types of Filter Sections UM}MK  
42.3 The Characteristic Impedance andthe Attenuation of Filter Sections 4Z0Y8y8)  
42. .. 5H2Ugk3  
xM:9XhH1  

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