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目录如下Part 1 Design Technologies and Schemes[52RD.com]
lecture 1 Different Methodology between RF and Digital[52RD.com]
Circuit Design 1 hour[52RD.com]
(0.17 days)[52RD.com]
1.1 Controversy[52RD.com]
1.1.1 Impedance Matching[52RD.com]
1.1.2 Key Parameter[52RD.com]
1.1.3 Circuit Testing and Main Test Equipments[52RD.com]
1.2 Differences of Digital and RF Blocks in a Communication System[52RD.com]
1.2.1 Impedance[52RD.com]
1.2.2 Current drain[52RD.com]
1.2.3 Location[52RD.com]
1.3 Conclusion[52RD.com]
1.4 Notes for High Speed Digital Circuit Design[52RD.com]
[52RD.com]
[52RD.com]
[52RD.com]
Lectue 2 Voltage and Power Transportation 2 hours[52RD.com]
(0.33 days)[52RD.com]
2.1 Voltage Delivered from a Source to a Load[52RD.com]
2.1.1 General Expression of Voltage Delivered from a Source to a Load[52RD.com]
2.1.2 Additional Jitter or Distortion in a Digital Circuit Block[52RD.com]
2.2 Power Delivered from a Source to a Load[52RD.com]
2.2.1 General Expression of Power Delivered from a Source to a Load[52RD.com]
2.2.2 Power Instability[52RD.com]
2.2.3 Additional Power Loss[52RD.com]
2.2.4 Additional Distortion[52RD.com]
2.2.5 Additional Interference[52RD.com]
2.3 Impedance Conjugate Matching [52RD.com]
2.3.1 Maximization of Power Transportation[52RD.com]
2.3.2 Power Transportation without Phase Shift [52RD.com]
2.3.3 Impedance Matching Network[52RD.com]
2.3.4 Necessity of Impedance Matching[52RD.com]
2.4 Additional Effects of Impedance Matching[52RD.com]
2.4.1 Voltage Pumped Up by Means of Impedance Matching[52RD.com]
2.4.2 Power Measurement [52RD.com]
Appendixes [52RD.com]
2A.1 VSWR and Other Reflection and Transmission Coefficients [52RD.com]
2A.2 Relationships between Power (dBm), Voltage (V), and Power (Watt) [52RD.com]
[52RD.com]
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Lecture 3 Impedance Matching in Narrow Band Case 4 hours[52RD.com]
(0.67 days) [52RD.com]
3.1 Introduction[52RD.com]
3.2 Impedance Matching by Means of Return Loss Adjustment[52RD.com]
3.2.1 Return Loss Circles on Smith Chart[52RD.com]
3.2.2 Relationship between Return Loss and Impedance Matching[52RD.com]
3.2.3 Implementation of an Impedance Matching Network[52RD.com]
3.3 Impedance Matching Network Built by One Part[52RD.com]
3.3.2 One Part Inserted into Impedance Matching Network in Series[52RD.com]
3.3.3 One Part Inserted into Impedance Matching Network in Parallel [52RD.com]
3.4 Impedance Matching Network Built by Two Parts[52RD.com]
3.4.1 Regions in the Smith Chart[52RD.com]
3.4.2 Value of Parts[52RD.com]
3.4.3 Selection of Topology[52RD.com]
3.5 Impedance Matching Network Built by Three Parts[52RD.com]
3.5.1 “Π” and “T” Types[52RD.com]
3.5.2 Recommended Topologies[52RD.com]
3.6 Impedance Matching when ZS or ZL is not 50 Ω[52RD.com]
3.7 Parts in an Impedance Matching Network[52RD.com]
Appendixes[52RD.com]
3A.1 Fundamentals of the Smith Chart[52RD.com]
3A.2 Formula for a Two Parts Impedance Matching Network[52RD.com]
3A.3 Topology Restrictions of the Two Parts Impedance Matching Network[52RD.com]
3A.4 Topology Restrictions of the Three Parts Impedance Matching Network[52RD.com]
3A.5 Conversion between “Π” and “T” type Matching Networks[52RD.com]
3A.6 Possible “Π” and “T” Impedance Matching Networks[52RD.com]
[52RD.com]
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Lecture 4 Impedance Matching in Wide Band Case 3 hours[52RD.com]
(0.5 days) [52RD.com]
4.1 Appearance of Narrow and Wide Band Return Loss on Smith Chart [52RD.com]
4.2 Impedance Variation due to Insertion of One Part per Arm[52RD.com]
or per Branch[52RD.com]
4.2.1 An Inductor Inserted into Impedance Matching Network in Series[52RD.com]
4.2.2 A Capacitor Inserted into Impedance Matching Network in Series[52RD.com]
4.2.3 An Inductor Inserted into Impedance Matching Network in Parallel[52RD.com]
4.2.4 A Capacitor Inserted into Impedance Matching Network in Parallel[52RD.com]
4.3 Impedance Variation due to Insertion of Two Parts per Arm[52RD.com]
or per Branch[52RD.com]
4.3.1 Two Parts Connected in Series to Form One Arm[52RD.com]
4.3.2 Two Parts Connected in Parallel to Form One Branch[52RD.com]
4.4 Impedance Matching in IQ Modulator Design for UWB System[52RD.com]
in UWB System[52RD.com]
4.4.1 Gilbert Cell in IQ Modulator[52RD.com]
4.4.2 Impedances of Gilbert Cell[52RD.com]
4.4.3 Impedance Matching for LO, RF and IF Ports Ignoring Bandwidth[52RD.com]
4.4.4 Wide Bandwidth Required in UWB(Ultra Wide Band) System[52RD.com]
4.4.5 Basic Idea to Expand the Bandwidth[52RD.com]
4.4.6 Example#1: Impedance Matching in IQ Modulator Design [52RD.com]
for Group#1 in UWB System[52RD.com]
4.4.7 Example#2: Impedance Matching in IQ Modulator Design[52RD.com]
for Group#3+Group#6 in UWB System[52RD.com]
4.5 Discussion of Wide-band Impedance Matching Network[52RD.com]
4.5.1 Impedance Matching for Gate of MOSFET device[52RD.com]
4.5.2 Impedance Matching for Drain of MOSFET device[52RD.com]
[52RD.com]
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Lecture 5 Impedance and Gain of a Raw Device 2 hours[52RD.com]
(0.33 days) [52RD.com]
5.1 Introduction[52RD.com]
5.2 Miller Effect[52RD.com]
5.3 Small Signal Model of Bipolar Transistor[52RD.com]
5.4 Bipolar Transistor with CE (Common Emitter) Configuration[52RD.com]
5.4.1 Open-circuited Voltage Gain Av,CE of a CE Device[52RD.com]
5.4.2 Short-circuited Current Gain βCE and Frequency Response of a CE Device[52RD.com]
5.4.3 Primary Input and Output Impedances of a CE Device[52RD.com]
5.4.4 Miller Effect on a CE device[52RD.com]
5.4.5 Emitter Degeneration[52RD.com]
5.5 Bipolar Transistor with CB (Common Base) Configuration[52RD.com]
5.5.1. Open-circuited Voltage Gain Av,CB of a CB Device[52RD.com]
5.5.2. Short-circuited Current Gain βCB and Frequency Response of a CB Device[52RD.com]
5.5.3. Input and Output Impedances of a CB Device[52RD.com]
5.6 Bipolar Transistor with CC (Common Collector) Configuration[52RD.com]
5.6.1 Open-circuited Voltage Gain Av,CC of a CC Device[52RD.com]
5.6.2 Short-circuited Current Gain βCC and Frequency Response of a CC Device[52RD.com]
5.6.3 Input and Output Impedances of a CC Device[52RD.com]
5.7 Small Signal Model of MOSFET Transistor[52RD.com]
5.8 Similarity between Bipolar and MOSFET Transistor[52RD.com]
5.8.1 Simplified Model of CS device[52RD.com]
5.8.2 Simplified Model of CG device[52RD.com]
5.8.3 Simplified Model of CD device[52RD.com]
5.9 MOSFET Transistor with CS (Common Source) Configuration[52RD.com]
5.9.1 Open-circuited Voltage Gain Av,CS of a CS Device[52RD.com]
5.9.2 Short-circuited Current Gain βCS and Frequency Response of a CS Device[52RD.com]
5.9.3 Input and Output Impedances of a CS Device[52RD.com]
5.9.4 Source Degeneration[52RD.com]
5.10 MOSFET Transistor with CG (Common Gate) Configuration[52RD.com]
5.10.1 Open-circuited Voltage Gain Av,CG of a CG Device[52RD.com]
5.10.2 Short-circuited Current Gain βCG and Frequency Response of a CG Device [52RD.com]
5.10.3 Input and Output Impedances of a CG Device[52RD.com]
[52RD.com]
5.11 MOSFET Transistor with CD (Common Drain) Configuration[52RD.com]
5.11.1 Open-circuited Voltage Gain Av,CD of a CD Device[52RD.com]
5.11.2 Short-circuited Current Gain βCD and Frequency Response of a CD Device[52RD.com]
5.11.3 Input and Output Impedances of a CD Device[52RD.com]
[52RD.com]
5.12 Comparison of Bipolar and MOSFET Transistor in Various[52RD.com]
Configurations[52RD.com]
[52RD.com]
[52RD.com]
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Lecture 6 Impedance Measurement 1 hours[52RD.com]
(0.17 days) [52RD.com]
6.1 Introduction[52RD.com]
6.2 Scale and Vector Voltage Measurement [52RD.com]
6.2.1 Voltage Measurement by Oscilloscope[52RD.com]
6.2.2 Voltage Measurement by Vector-Voltmeter[52RD.com]
6.3 Direct Impedance Measurement by Network Analyzer[52RD.com]
6.3.1 Direction of Impedance Measurement[52RD.com]
6.3.2 Advantages of Measuring S Parameters[52RD.com]
6.3.3 Theoretical Background of Impedance Measurement by S Parameters[52RD.com]
6.3.4 S Parameter Measurement by Vector-Voltmeter[52RD.com]
6.3.5 Calibration of Network Analyzer[52RD.com]
6.4 Alternative Impedance Measurement by Network Analyzer[52RD.com]
6.4.1 Accuracy of Smith Chart[52RD.com]
6.4.2 Low and High Impedance Measurement[52RD.com]
6.5 Impedance measurement by Assistance of Circulator[52RD.com]
Appendixes[52RD.com]
6A.1 Relationship Between the Impedance in Series and in Parallel[52RD.com]
[52RD.com]
[52RD.com]
[52RD.com]
Lecture 7 Grounding 4 hours[52RD.com]
(0.67 days) [52RD.com]
7.1 Implications of Grounding[52RD.com]
7.2 Possible Grounding Problems Hidden in a Schematic [52RD.com]
7.3 Imperfect or Inappropriate Grounding Examples[52RD.com]
7.3.1 Inappropriate Selection of Bypass Capacitor[52RD.com]
7.3.2 Imperfect Grounding[52RD.com]
7.3.3 Improper Connection[52RD.com]
7.4 “Zero” Capacitor[52RD.com]
7.4.1 What is a “Zero” Capacitor?[52RD.com]
7.4.2 Selection of the “Zero” Capacitor[52RD.com]
7.4.3 Bandwidth of the “Zero” Capacitor[52RD.com]
7.4.4 Combined Effect of Multiple “Zero” Capacitors[52RD.com]
7.4.5 Chip Inductor is a Good Assistant[52RD.com]
7.4.6 “Zero” Capacitor in RFIC Design[52RD.com]
7.5 Quarter Wavelength of Micro Strip Line[52RD.com]
7.5.1 A Runner is a Part in RF Circuitry[52RD.com]
7.5.2 Why the Quarter Wavelength is so Important?[52RD.com]
7.5.3 The Magic of the Open-circuited Quarter-Wavelength Micro Strip Line[52RD.com]
7.5.4 Testing for Width of a Micro Strip Line with a Specific[52RD.com]
Characteristic Impedance[52RD.com]
7.5.5 Testing for the Quarter Wavelength [52RD.com]
Appendixes [52RD.com]
7A.1 Characterizing a Chip Capacitor and Chip Inductor by Means of S21 Testing[52RD.com]
[52RD.com]
[52RD.com]
[52RD.com]
Lecture 8 Equipotentiality and Current Coupling[52RD.com]
on the Ground Surface 2 hours[52RD.com]
(0.33 days) [52RD.com]
8.1 Equipotentiality on the Grounded Surface[52RD.com]
8.1.1 Equipotentiality on the Grounded Surface of a RF cable[52RD.com]
8.1.2 Equipotentiality on the Grounded Surface of a PCB[52RD.com]
8.1.3 Possible Problems of a Large Test PCB[52RD.com]
8.1.4 Coercing Grounding[52RD.com]
8.1.5 Testing for Equipotentiality[52RD.com]
[52RD.com]
8.2 Forward and Return Current Coupling[52RD.com]
8.3.1 “Indifferent Assumption” and the “Great Ignore”[52RD.com]
8.3.2 Reduction of Current Coupling on a PCB[52RD.com]
8.3.3 Reduction of Current Coupling in a IC Die[52RD.com]
8.3.4 Reduction of Current Coupling between Multiple RF Blocks[52RD.com]
8.3.5 A Plausible System Assembly[52RD.com]
[52RD.com]
8.3 PCB and IC Chip with Multi Metallic Layers[52RD.com]
Appendixes [52RD.com]
8A.1 Primary Considerations of a PCB[52RD.com]
[52RD.com]
[52RD.com]
[52RD.com]
Lecture 9 RFIC (Radio Frequency Integrated Circuit) and[52RD.com]
SOC (System on Chip) 4 hours[52RD.com]
(0.67 days) [52RD.com]
9.1 Interference and Isolation[52RD.com]
9.1.1 Existence of Interference in Circuitry[52RD.com]
9.1.2 Definition and Measurement of Isolation[52RD.com]
9.1.3 Main Path of Interference in a RF Module[52RD.com]
9.1.4 Main Path of Interference in a IC Die[52RD.com]
9.2 Shielding for a RF Module by a Metallic Shielding Box[52RD.com]
9.3 Strong Desirability to Develop RFIC[52RD.com]
9.4 Interference Going Along IC Substrate Path[52RD.com]
9.4.1. Experimentation[52RD.com]
9.4.2. Trench[52RD.com]
9.4.3. Guard Ring[52RD.com]
9.5 Solution for Interference Coming from the Sky[52RD.com]
9.6 Common Grounding Rules for RF Module and RFIC Design[52RD.com]
9.6.1. Grounding of Circuit-branches or Blocks in Parallel[52RD.com]
9.6.2. DC Power Supply to Circuit-branches or Blocks in Parallel[52RD.com]
9.7 Bottlenecks in RFIC[52RD.com]
9.7.1 Low Q Inductor and Possible Solution[52RD.com]
9.7.2 “Zero” Capacitors[52RD.com]
9.7.3 Bonding Wires[52RD.com]
9.8 Prospect of SOC[52RD.com]
9.9 What is Next?[52RD.com]
Appendixes[52RD.com]
9A.1 Notes about RFIC layout[52RD.com]
9A.2 Calculation of Quarter Wavelength[52RD.com]
[52RD.com]
[52RD.com]
[52RD.com]
Lecture 10 Manufacturability of Product Design 2 hours[52RD.com]
(0.33 days) [52RD.com]
10.1 Introduction[52RD.com]
10.2 Implication of 6σ Design[52RD.com]
10.2.1 6σ and Yield Rate[52RD.com]
10.2.2 6σ Design for a Circuit Block[52RD.com]
10.3 Approaching 6σ Design[52RD.com]
10.3.1 By Changing Parts’ 6σ Value[52RD.com]
10.3.2 By Replacing a Single Part with Multiple Parts[52RD.com]
10.4 Monte Carlo Analysis [52RD.com]
10.4.1 A BPF (Band Pass Filter)[52RD.com]
10.4.2 Simulation with Monte Carlo Analysis[52RD.com]
10.4.3 Sensitivity of Parts on the Parameter of Performance[52RD.com]
Appendixes[52RD.com]
10A.1 Fundamentals of Random Process[52RD.com]
10A.2 Index Cp, Cpk and Other Parameters Applied in 6σ Design[52RD.com]
10A.3 Table of the Normal Distribution[52RD.com]
[52RD.com]
[52RD.com]
[52RD.com]
[52RD.com]
Part 2 RF System Analysis[52RD.com]
[52RD.com]
[52RD.com]
Lecture 11 Main Parameters and System Analysis 4 hours[52RD.com]
(0.67 days) [52RD.com]
11.1 Introduction[52RD.com]
11.2 Power Gain[52RD.com]
11.2.1 Basic Concept of Reflection Power Gain[52RD.com]
11.2.2 Transducer Gain[52RD.com]
11.2.3 S21 and Various Power Gain in Unilateral Cases[52RD.com]
11.2.4 Power Gain and Impedance Matching[52RD.com]
11.2.5 Power Gain and Voltage Gain[52RD.com]
11.2.6 Cascaded Equations of Gain[52RD.com]
11.3 Noise[52RD.com]
11.3.1 Significance of the Noise Figure[52RD.com]
11.3.2 Noise Figure in a Noisy Two-port Block[52RD.com]
11.3.3 Notes for Noise Figure Testing.[52RD.com]
11.3.4 An Experimental Method to Obtain Noise Parameters[52RD.com]
11.3.5 Cascaded Equations of Noise Figure[52RD.com]
11.3.6 Sensitivity of Receiver[52RD.com]
11.4 Non-linearity[52RD.com]
11.4.1 Non-linearity of Devices[52RD.com]
11.4.2 IP (Intercept point) and IMR (Inter-Modulation Rejection)[52RD.com]
11.4.3 Cascaded Equations of Intercept Point[52RD.com]
11.4.4 Non-linearity and Distortion[52RD.com]
11.5 Other Parameters[52RD.com]
11.5.1 DC Power Supply and Current Drain[52RD.com]
11.5.2 Part Count[52RD.com]
11.6 Examples of RF System Analysis[52RD.com]
Appendixes[52RD.com]
11A.1 Conversion between Watt, Volt, and dBm in a System
Lecture00_Introduction.rar
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with 50 Ω of Input and Output Impedance[52RD.com]
11A.2 VSWR and Other Reflection and Transmission Coefficients
11A.3 Definition of Powers in a Two-port Block by Signal Flow Graph
11A.4 Main Noise Sources[52RD.com] |
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发表于 2008-8-1 11:25:10
