实例介绍
【实例简介】
SystemVue培训教程,类似于Matlab Simulink,进行算法开发
Contents General Introduction stemMe 3. Objectives Chapter 1: SystemVue Integrated Simulators 1.1. Introduction ,1 1c11 1.2. Traditional Simulation Techniques 1.3. Behavioral Modeling… 131 Data flow simulator 1.3.2. Spectrasys 122 1.3.3 Whatlf Frequency planner 155 13.4 Parameter Sweep ,1a 着1,11 1,11 15 13 Behavioral Optimizatian 177 14. Summary… Chapter 2: RE System Design B: asics 2.1. Introduction 22 Transceiver Design 000 2.3. Receiver Architectures 21 2.3. 1. Super-Heterodyne receivers 222 2.3.2. LOW-IF Receivers 222 2.3.3. Direct-Conversion Receivers 232 2.3.4 Sub-Sampling receivers 233 2.3.5 Receiver Architecture benchmark 24 System-level considerations 81 244 2.41 Figures-of-Merit .244 24.2 Range Equations. 254 2.43. ink b 255 2. 4. 4. Sensitivity and Selectivity “1 Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 2 245. mage Rejection… 287 2.4.6 Phase noise 288 2.47 DC Offset 299 2.5. Nonlinear behavior of re systems 1 299 2.5.1 Intermodulation Distortion 29 2.5.2 Naise Figure .30 2.5.3. In-Band and out -of-Band Interferers and blockers 31 2.5.4. Adjacent Channels 2.5.5. Gain Compression 32 2.5.6. Dynamic Range 344 2.6. Transceiver Design Trade-Offs ∴355 2.6.1. Signal-to-Noise Ratio 355 2.6.2 Frequency Planning 355 27 Basic RF Transceiver Building Blocks 366 271 Antenna…. 377 27.2 Amplifier(Power/Low-Nois .377 2.7.3.Fitr 377 2.7.4 Duplexer .388 2.75Mi 388 2.7.6. Local Oscillator 399 2. 7.7. Detector 399 2.7.8. Analog-to-Digital Conversion 399 2. 8. Summary 40 Chapter 3: Designing RF Systems Using SystemVue 41 ase Study: Long-Term Evolution(LTE) Front-End Design 3.1. Introduction 41 32. Highlights about Design Methodologies and Approaches 3.21 Common desian approaches. 41 3. 2.2. Overview of System-Level Modeling 432 3.3 Case study. L TE Tri-Band receiver desian 444 3.31 LTE Overview 454 Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 3 3.3.2 Receiver Specifications and desian 455 3.4 Summary ∴62 Chapter 4: Introduction to Digital Communications 64 41. Introduction 1 64 4.2 Transmitter 65 43. Receiver 65 4. 4. Channel 65 4.5. Other considerations 65 hapter 5: Transmitter Design 67 5.1. Transmitter Basics .67 5. 2. Input Data 69 Encoding .70 5.4. Mapping nape filter 72 56.1/Q Modulation 96 5Z△ nalyzing the results 98 Chapter 6: Receiver Design 82 Receiver basics 82 6.2 Receiver Subnetwork overview 85 6.3. Demodulator 87 6.4. Matched Filte 88 6.5. Synchronization 6.6. Phase and Timing error correction 91 6. 7. Frequency Error Correction 93 6.8. Channel Estimation 97 6.9. Demapping…… 97 610. Code Correction Chapter Z: System Level modeling .99 Z1 BER 99 7.2 Cross Domain simulation 102 73 HDL Generation. 104 Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 4 Chapter:OFDMIr ansmitter 108 8.1 Introduction 108 8.2 OFDM Frame Structure 111 83. QEDM Payload 1 112 8.4. Pilot signals 113 85. Frequency-to-Time Domain 114 Chapter 9: Spread Spectrum CDMA Tutorial 9.1. Introduction 118 9.2. Lab 1: Bit Generation Pattern 118 9.3. Lab 2: Mapping 125 9. 4. Lab 3: Walsh Code 128 9.5. Lab 4: Filter Design .131 9.6. Lab 5: Modulation 133 9.7 Lab 6: re Link 135 98LabZ: Step 7 Demodulation. .139 9.9 Lab 8: Completed e口 144 9.10. Conclusion.… 152 App Bendix 153 154 Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 5 Acronyms and Abbreviations 3G Third-Generatio 3GPP Third-Generation Partnership Project ACPR Adjacent Channel Power Ratio ADS Advanced Design System AWGn Additive White gaussian noisc ber BIt Error rate CMOS Complementary Metal Oxide Semiconductor cnR Carrier-to-Noise Ratio CPU Central Processing Unit CW Continuous Wave Dc Direct current DR Dynamic Range DSP Digital Signal Processing E-UTRA Evolved UMTS Terrestrial Radio access EVM Error Vector Magnitude FDD Frequency Division Duplex SPL Free-Space Path Loss G Gain Hb Harmonic balance HDL Hardware Description Language IF Intermediate Frequency IMD Intermodulation distortion IP Intellectual Property Lo Local oscillator LOS Line-of-Sight Long Term Evolution MDS Minimum Discernible Signal MIMo Multiple Input Multiple Output Noise Figure OFDM Orthogonal Frequency Division Multiplexing OFDMA Orthogonal Frequency Division Multiple Access P1db 1-dB Compression Point PLL Pha 00 PRB Physical Resource Blocks QPSK Quadrature Phase-Shift Keying R Radio-Frequency SAE System Architecture Evolution SC-FDMA Single Carrier Frequency Division Multiple Access SDF Synchronous Data Flow SINAD Signal-to-Noise and Distortion Ratio SIso Simple Input Simple Output SNr Signal-to-Noise Ratio(also S/N) SP Scattering Parameters SPARCA Spectral Propagation and Root Cause Analysis Ta Transient Analysis TDD Time Division Duplex THD Total Harmonic distortion TOI Third-Order Intercept Point (also IP3) UMTS Universal mobile Telecommunication System vco Voltage-Controlled Oscillator Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 6 VSWR Voltage Standing Wave Ratio XP X-Parameters k Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 7 General Introduction 1. Systeme stemVue is a focused EDA environment for electronic system-level(ESL) design that allows system architects and algorithm developers to innovate the physical layer (PHY) of next generation wireless and aerospace/defense communications systems. It provides unique value to RF, DSP and FPGA/ASIC implementers who rely on both RF and digital signal processing deliver the full value of their hardware platforms SystemVue replaces general-purpose analog, digital and math environments by offering a dedicated playform for ESL design and signal processing realization. SystemVue"speaks RF, "cuts PHY development and verification time in half, and connects to your mainstream EDA flow For more information about SystemVue, please visit: www keysight com/find/eesof-systemvue 2. Scope This primer is intended to highlight the system-level simulation techniques and paradigms included in the Keysight Technologies SystemVue software package Chapters 1-3 focus on how to use this software to architect RF systems, as well as how to model RF blocks. Chapters 4-8 delve into the basics of digital communication and provide an introduction into the theory and structure of a digital radio system 3. Objectives earn how Keysight simulators work for RF system-Level modeling and begin to document this operation with a specific focus on how these simulators can be used for architecting rF systems 2. Learn about and document Keysight's collection of RF models, capturing their ranges of operation, support for linear and nonlinear simulation modes, support for noise, etc 3. Propose a recommended methodology to design RF systems using Keysight SystemE 4. Develop some applications of RF modeling for emerging wireless and aerospace/defense b. Learn the basics of digital communications and the theory and structure of a typical digital radio system 6. Construct the basic components of a digital radio system using SystemVue and nvestigate typical design considerations 7. Simulate and analyze results from System Vue simulations of your digital communication components Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 8 Chapter 1: SystemVue Integrated Simulators 11. Introduction Keysight integrated design environments like Advanced Design System(ADS)and Genesys mostly implement the traditional linear and nonlinear simulation techniques for RF design. These techniques do not cover all the behavioral modeling aspects of digital and RF systems. To complete this set of design tools, SystemVue was created. SystemVue is leading-edge system level design and simulation software developed to support high-level architecting of RF and baseband systems. It includes various simulation technologies covering the baseband and re fields and operating in both frequency and time domains. SystemVue includes the Data Flow Simulator and Spectrasys simulation cores. It also includes a unique tool for IF frequency planning called the WhatiF frequency planner(also provided in ADS and Genesys 2. Traditional Simulation Techniques ADS allows for evaluation of an RF schematic using linear and nonlinear simulation techniques These techniques include, but are not limited to Scattering Parameters(SP) calculation: this kind of simulation evaluates the lin near frequency response of an rf device. It is based on the computation of the network scattering and noise parameters Harmonic Balance(HB): a frequency-domain simulation method used to calculate the steady-state response of a nonlinear re device. It computes, for example, metrics such as total harmonic distortion(THD)and third-order intercept(tod) points Transient Analysis (TA): this is a time-domain simulation technique used to evaluate the rF device response over time DC Circuit Analysis: this allows the computation of the DC properties of an RF circuit Most of these techniques are slow and do not allow the behavioral description of rF systems. For this reason, System Vue incorporates simulation techniques that are capable of fully describing the behavior of an RF system/device, as well as accurately evaluating its time-and frequency-domain parameters 1.3. Behavioral Modeling Keysight introduced a method of architecting and simulating RF systems that is based mainly on behavioral modeling Keysight products such as SystemVue support this method through the data Flow Simulator and spectrasys simulation engines. Behavioral models support difterent types of spectrum. They are also flexible enough to support future spectrum. Furthermore, in Spectrasys each port is by default an input and output pin at the same time with regard to the type of spectrum used Analysis and Design of RF and Digital Systems Using Keysight Systemvue C2014 Keysight Technologies --Page 9 【实例截图】
【核心代码】
SystemVue培训教程,类似于Matlab Simulink,进行算法开发
Contents General Introduction stemMe 3. Objectives Chapter 1: SystemVue Integrated Simulators 1.1. Introduction ,1 1c11 1.2. Traditional Simulation Techniques 1.3. Behavioral Modeling… 131 Data flow simulator 1.3.2. Spectrasys 122 1.3.3 Whatlf Frequency planner 155 13.4 Parameter Sweep ,1a 着1,11 1,11 15 13 Behavioral Optimizatian 177 14. Summary… Chapter 2: RE System Design B: asics 2.1. Introduction 22 Transceiver Design 000 2.3. Receiver Architectures 21 2.3. 1. Super-Heterodyne receivers 222 2.3.2. LOW-IF Receivers 222 2.3.3. Direct-Conversion Receivers 232 2.3.4 Sub-Sampling receivers 233 2.3.5 Receiver Architecture benchmark 24 System-level considerations 81 244 2.41 Figures-of-Merit .244 24.2 Range Equations. 254 2.43. ink b 255 2. 4. 4. Sensitivity and Selectivity “1 Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 2 245. mage Rejection… 287 2.4.6 Phase noise 288 2.47 DC Offset 299 2.5. Nonlinear behavior of re systems 1 299 2.5.1 Intermodulation Distortion 29 2.5.2 Naise Figure .30 2.5.3. In-Band and out -of-Band Interferers and blockers 31 2.5.4. Adjacent Channels 2.5.5. Gain Compression 32 2.5.6. Dynamic Range 344 2.6. Transceiver Design Trade-Offs ∴355 2.6.1. Signal-to-Noise Ratio 355 2.6.2 Frequency Planning 355 27 Basic RF Transceiver Building Blocks 366 271 Antenna…. 377 27.2 Amplifier(Power/Low-Nois .377 2.7.3.Fitr 377 2.7.4 Duplexer .388 2.75Mi 388 2.7.6. Local Oscillator 399 2. 7.7. Detector 399 2.7.8. Analog-to-Digital Conversion 399 2. 8. Summary 40 Chapter 3: Designing RF Systems Using SystemVue 41 ase Study: Long-Term Evolution(LTE) Front-End Design 3.1. Introduction 41 32. Highlights about Design Methodologies and Approaches 3.21 Common desian approaches. 41 3. 2.2. Overview of System-Level Modeling 432 3.3 Case study. L TE Tri-Band receiver desian 444 3.31 LTE Overview 454 Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 3 3.3.2 Receiver Specifications and desian 455 3.4 Summary ∴62 Chapter 4: Introduction to Digital Communications 64 41. Introduction 1 64 4.2 Transmitter 65 43. Receiver 65 4. 4. Channel 65 4.5. Other considerations 65 hapter 5: Transmitter Design 67 5.1. Transmitter Basics .67 5. 2. Input Data 69 Encoding .70 5.4. Mapping nape filter 72 56.1/Q Modulation 96 5Z△ nalyzing the results 98 Chapter 6: Receiver Design 82 Receiver basics 82 6.2 Receiver Subnetwork overview 85 6.3. Demodulator 87 6.4. Matched Filte 88 6.5. Synchronization 6.6. Phase and Timing error correction 91 6. 7. Frequency Error Correction 93 6.8. Channel Estimation 97 6.9. Demapping…… 97 610. Code Correction Chapter Z: System Level modeling .99 Z1 BER 99 7.2 Cross Domain simulation 102 73 HDL Generation. 104 Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 4 Chapter:OFDMIr ansmitter 108 8.1 Introduction 108 8.2 OFDM Frame Structure 111 83. QEDM Payload 1 112 8.4. Pilot signals 113 85. Frequency-to-Time Domain 114 Chapter 9: Spread Spectrum CDMA Tutorial 9.1. Introduction 118 9.2. Lab 1: Bit Generation Pattern 118 9.3. Lab 2: Mapping 125 9. 4. Lab 3: Walsh Code 128 9.5. Lab 4: Filter Design .131 9.6. Lab 5: Modulation 133 9.7 Lab 6: re Link 135 98LabZ: Step 7 Demodulation. .139 9.9 Lab 8: Completed e口 144 9.10. Conclusion.… 152 App Bendix 153 154 Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 5 Acronyms and Abbreviations 3G Third-Generatio 3GPP Third-Generation Partnership Project ACPR Adjacent Channel Power Ratio ADS Advanced Design System AWGn Additive White gaussian noisc ber BIt Error rate CMOS Complementary Metal Oxide Semiconductor cnR Carrier-to-Noise Ratio CPU Central Processing Unit CW Continuous Wave Dc Direct current DR Dynamic Range DSP Digital Signal Processing E-UTRA Evolved UMTS Terrestrial Radio access EVM Error Vector Magnitude FDD Frequency Division Duplex SPL Free-Space Path Loss G Gain Hb Harmonic balance HDL Hardware Description Language IF Intermediate Frequency IMD Intermodulation distortion IP Intellectual Property Lo Local oscillator LOS Line-of-Sight Long Term Evolution MDS Minimum Discernible Signal MIMo Multiple Input Multiple Output Noise Figure OFDM Orthogonal Frequency Division Multiplexing OFDMA Orthogonal Frequency Division Multiple Access P1db 1-dB Compression Point PLL Pha 00 PRB Physical Resource Blocks QPSK Quadrature Phase-Shift Keying R Radio-Frequency SAE System Architecture Evolution SC-FDMA Single Carrier Frequency Division Multiple Access SDF Synchronous Data Flow SINAD Signal-to-Noise and Distortion Ratio SIso Simple Input Simple Output SNr Signal-to-Noise Ratio(also S/N) SP Scattering Parameters SPARCA Spectral Propagation and Root Cause Analysis Ta Transient Analysis TDD Time Division Duplex THD Total Harmonic distortion TOI Third-Order Intercept Point (also IP3) UMTS Universal mobile Telecommunication System vco Voltage-Controlled Oscillator Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 6 VSWR Voltage Standing Wave Ratio XP X-Parameters k Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 7 General Introduction 1. Systeme stemVue is a focused EDA environment for electronic system-level(ESL) design that allows system architects and algorithm developers to innovate the physical layer (PHY) of next generation wireless and aerospace/defense communications systems. It provides unique value to RF, DSP and FPGA/ASIC implementers who rely on both RF and digital signal processing deliver the full value of their hardware platforms SystemVue replaces general-purpose analog, digital and math environments by offering a dedicated playform for ESL design and signal processing realization. SystemVue"speaks RF, "cuts PHY development and verification time in half, and connects to your mainstream EDA flow For more information about SystemVue, please visit: www keysight com/find/eesof-systemvue 2. Scope This primer is intended to highlight the system-level simulation techniques and paradigms included in the Keysight Technologies SystemVue software package Chapters 1-3 focus on how to use this software to architect RF systems, as well as how to model RF blocks. Chapters 4-8 delve into the basics of digital communication and provide an introduction into the theory and structure of a digital radio system 3. Objectives earn how Keysight simulators work for RF system-Level modeling and begin to document this operation with a specific focus on how these simulators can be used for architecting rF systems 2. Learn about and document Keysight's collection of RF models, capturing their ranges of operation, support for linear and nonlinear simulation modes, support for noise, etc 3. Propose a recommended methodology to design RF systems using Keysight SystemE 4. Develop some applications of RF modeling for emerging wireless and aerospace/defense b. Learn the basics of digital communications and the theory and structure of a typical digital radio system 6. Construct the basic components of a digital radio system using SystemVue and nvestigate typical design considerations 7. Simulate and analyze results from System Vue simulations of your digital communication components Analysis and Design of RF and Digital Systems Using Keysight System vue C2014 Keysight Technologies --Page 8 Chapter 1: SystemVue Integrated Simulators 11. Introduction Keysight integrated design environments like Advanced Design System(ADS)and Genesys mostly implement the traditional linear and nonlinear simulation techniques for RF design. These techniques do not cover all the behavioral modeling aspects of digital and RF systems. To complete this set of design tools, SystemVue was created. SystemVue is leading-edge system level design and simulation software developed to support high-level architecting of RF and baseband systems. It includes various simulation technologies covering the baseband and re fields and operating in both frequency and time domains. SystemVue includes the Data Flow Simulator and Spectrasys simulation cores. It also includes a unique tool for IF frequency planning called the WhatiF frequency planner(also provided in ADS and Genesys 2. Traditional Simulation Techniques ADS allows for evaluation of an RF schematic using linear and nonlinear simulation techniques These techniques include, but are not limited to Scattering Parameters(SP) calculation: this kind of simulation evaluates the lin near frequency response of an rf device. It is based on the computation of the network scattering and noise parameters Harmonic Balance(HB): a frequency-domain simulation method used to calculate the steady-state response of a nonlinear re device. It computes, for example, metrics such as total harmonic distortion(THD)and third-order intercept(tod) points Transient Analysis (TA): this is a time-domain simulation technique used to evaluate the rF device response over time DC Circuit Analysis: this allows the computation of the DC properties of an RF circuit Most of these techniques are slow and do not allow the behavioral description of rF systems. For this reason, System Vue incorporates simulation techniques that are capable of fully describing the behavior of an RF system/device, as well as accurately evaluating its time-and frequency-domain parameters 1.3. Behavioral Modeling Keysight introduced a method of architecting and simulating RF systems that is based mainly on behavioral modeling Keysight products such as SystemVue support this method through the data Flow Simulator and spectrasys simulation engines. Behavioral models support difterent types of spectrum. They are also flexible enough to support future spectrum. Furthermore, in Spectrasys each port is by default an input and output pin at the same time with regard to the type of spectrum used Analysis and Design of RF and Digital Systems Using Keysight Systemvue C2014 Keysight Technologies --Page 9 【实例截图】
【核心代码】
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