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Table of contents
Introduction
1.1 Outline
2 Motivation and State of the Art
2.1 Introduction
2.2 UniVed Multi-Level Design Environment for Mixed Signal Systems
2.3 State of the art of Mixed-Signal Design and Simulation tools
2.3.1 Mixed Signal Systems Modeling and simulation
2.3.2 Systematic Circuit Analysis and Design
2.4 Major Contributions
2.4.1 Mixed Signal Systems Modeling with SystemC AMS
2.4.2 ReVned Behavioral Modeling of Analog and RF Components
2.4.3 Analog and RF Circuit Analysis and Performance Evaluation
2.4.4 Systematic Circuit-Level Design and Optimization of Analog and RF Circuits .
2.4.5 UniVed Multi-Level Design Environment for Mixed Signal Systems
2.5 Conclusion
3 Mixed Signal Systems Modeling with SystemC AMS
3.1 Introduction
3.2 SystemC AMS
3.2.1 Models of Computation
3.2.2 Modeling using Timed Data Flow Model of Computation
3.3 Wireless Sensor Network Node Model
3.3.1 ADC Model
3.3.2 Microcontroller Model
3.3.3 RF Transceiver Model
3.3.4 Simulation Results
3.4 Baseband Equivalent Modeling for Fast RF simulation
3.4.1 Baseband Equivalent Technique
3.4.2 SystemC AMS Implementation
3.5 Conclusion
4 ReVned Behavioral Modeling of Analog and RF Components
4.1 Introduction
4.2 Model ReVnement of Analog Components
4.2.1 Gain
4.2.2 Noise
4.2.3 Implementation
4.2.4 Results
4.3 Model ReVnement of RF Components
4.3.1 Gain
4.3.2 Noise
4.3.3 Nonlinearity
4.3.4 Implementation
4.3.5 Results
4.4 Model ReVnement of Sine Wave Source Component
4.4.1 Non-idealities
4.4.2 Implementation
4.4.3 Results
4.5 Conclusion
5 Analog and RF Circuit Analysis and Performance Evaluation
5.1 Introduction
5.2 Motivation
5.3 ModiVed Nodal Analysis
5.3.1 The MNA library based on Maxima
5.3.2 Task Scheduling for a Systematic Circuit Analysis and Performance Evaluation
5.4 Linear Performance Evaluation
5.4.1 Voltage Gain
5.4.2 Input Impedance
5.4.3 Output Noise
5.5 Nonlinear Performance Evaluation
5.5.1 Nonlinearity modeling in analog integrated circuits
5.5.2 Volterra kernels
5.5.3 Direct Performance Calculation
5.5.4 Systematic Nonlinear Performance Evaluation
5.6 Conclusion
6 Systematic Circuit-Level Design and Optimization of Analog and RF Circuits
6.1 Introduction
6.2 Proposed Circuit-Level Design Flow
6.2.1 Transistor and Passive Elements Biasing/Sizing
6.2.2 Performance Evaluation
6.2.3 Optimization Procedure
6.3 Case Study I: GmC Integrator
6.3.1 DC Biasing
6.3.2 Transistor and Passive Elements Sizing
6.3.3 Performance Evaluation
6.3.4 Optimization Procedure
6.3.5 Design Examples
6.4 Case Study II: Low Noise AmpliVer
6.4.1 DC Biasing
6.4.2 Transistor and Passive Elements Sizing
6.4.3 Performance Evaluation
6.4.4 Optimization Procedure
6.4.5 Design examples
6.5 Conclusion
7 UniVed Multi-Level Design Environment for Mixed Signal Systems
7.1 Introduction
7.2 The UniVed Multi-Level Design Flow
7.3 Case Study I: GmC Integrator Design for Sigma-Delta ADC
7.3.1 Design Flow
7.3.2 Results
7.4 Case Study II: Low Noise AmpliVer Design for ZigBee RF Transceiver
7.4.1 Design Flow
7.4.2 ZigBee RF Receiver Architecture And Implementation
7.4.3 Results
7.5 Conclusion
8 Conclusion and Future Work
8.1 Conclusion
8.2 Future Work
9 List of Publications
A SystemC AMS: Timed Data Flow Modeling
A.1 Modeling using Timed Data Flow Model of Computation
A.1.1 AmpliVer Model
A.1.2 1-bit DAC Model
A.1.3 Rate Transition
A.1.4 Modulator Model
A.2 Hierarchical Modeling
A.2.1 Transmitter Model
A.3 The Testbench.
A.3.1 Digital Pulse Source Model
A.3.2 The Main Function
B ModiVed Nodal Analysis library for Maxima language
References
