This book includes recent research that focuses on analog integrated circuits and covers three main topics, namely: fundamentals, synthesis and performance. Eleven chapters are divided among these three topics as follows: Chapters One to Four are a part of fundamentals. The first chapter ("e;The Next Generation of Nanomaterials for Designing Analog Integrated Circuits"e;) describes new directions for applying nanomaterials for the design of modern analog circuits. Chapter Two ("e;Application of Nullors in Designing Analog Circuits for Frequency Bandwidth"e;) uses the pathological circuit element known as a nullor to design analog integrated circuits with frequency specifications to accomplish a desired bandwidth. Chapter Three ("e;RC and RL to LC Circuit Conversion, and its Application in Poles and Zeros Identification"e;) details an important property from circuit theory to estimate roots by performing conversions of passive elements. Chapter Four ("e;Enhanced and Improved Symbolic Circuit Analysis Using MATLAB"e;) relays the development of symbolic circuit analysis and focuses on enhancing an already developed symbolic tool to allow the symbolic analysis of large circuits. The synthesis of analog integrated circuits has been a challenge because there is no way to establish general rules to cover the gap between the behavioral and transistor circuit levels of abstraction. In this book, the second topic includes four chapters, from Five to Eight. Chapter Five ("e;On the Synthesis of Sinusoidal Oscillators Using Nullors"e;), just as in Chapter Two, uses the pathological circuit element known as a nullor to perform the synthesis of sinusoidal oscillators, which are quite useful in many electronic systems. Other kinds of oscillators are described in Chapter Six ("e;Synthesis of SRCOs and Multi-Phase Oscillators from State Variables to their Implementation Using CMOS IC Technology"e;) where the synthesis process identifies the resistor that controls the oscillating frequency and applies a state variable approach. Chapter Seven ("e;Evolutionary Optimization in the Design of CMOS Analog Integrated Circuits"e;) shows the application of heuristics for circuit optimization, and how it can be extended to bigger analog integrated circuits. Chapter Eight provides details on the synthesis and design of a CMOS harmonic mixer with output power management for narrowband and wideband wireless communications: the Bluetooth and UWB cases. The third part of this book is devoted to analog circuit performances and includes three chapters. Chapter Nine details the FPGA realization of radio frequency (RF) power amplifier models. In this case, the system is modeled in the analog domain and implemented in the digital one. Chapter Ten "e;White-Box Models of Optimal-Sized Solutions of Analog Integrated Circuits"e;) generates analytical expressions for modeling the dominant behavior of CMOS analog circuits. Finally, Chapter Eleven ("e;Radial Basis Function Surrogate Modeling for the Accurate Design of Analog Circuits"e;) applies modern modeling approaches to accomplish real target specifications and to improve the design of reliable circuits.

This book includes recent research that focuses on analog integrated circuits and covers three main topics, namely: fundamentals, synthesis and performance. Eleven chapters are divided among these three topics as follows: Chapters One to Four are a part of fundamentals. The first chapter ("e;The Next Generation of Nanomaterials for Designing Analog Integrated Circuits"e;) describes new directions for applying nanomaterials for the design of modern analog circuits. Chapter Two ("e;Application of Nullors in Designing Analog Circuits for Frequency Bandwidth"e;) uses the pathological circuit element known as a nullor to design analog integrated circuits with frequency specifications to accomplish a desired bandwidth. Chapter Three ("e;RC and RL to LC Circuit Conversion, and its Application in Poles and Zeros Identification"e;) details an important property from circuit theory to estimate roots by performing conversions of passive elements. Chapter Four ("e;Enhanced and Improved Symbolic Circuit Analysis Using MATLAB"e;) relays the development of symbolic circuit analysis and focuses on enhancing an already developed symbolic tool to allow the symbolic analysis of large circuits. The synthesis of analog integrated circuits has been a challenge because there is no way to establish general rules to cover the gap between the behavioral and transistor circuit levels of abstraction. In this book, the second topic includes four chapters, from Five to Eight. Chapter Five ("e;On the Synthesis of Sinusoidal Oscillators Using Nullors"e;), just as in Chapter Two, uses the pathological circuit element known as a nullor to perform the synthesis of sinusoidal oscillators, which are quite useful in many electronic systems. Other kinds of oscillators are described in Chapter Six ("e;Synthesis of SRCOs and Multi-Phase Oscillators from State Variables to their Implementation Using CMOS IC Technology"e;) where the synthesis process identifies the resistor that controls the oscillating frequency and applies a state variable approach. Chapter Seven ("e;Evolutionary Optimization in the Design of CMOS Analog Integrated Circuits"e;) shows the application of heuristics for circuit optimization, and how it can be extended to bigger analog integrated circuits. Chapter Eight provides details on the synthesis and design of a CMOS harmonic mixer with output power management for narrowband and wideband wireless communications: the Bluetooth and UWB cases. The third part of this book is devoted to analog circuit performances and includes three chapters. Chapter Nine details the FPGA realization of radio frequency (RF) power amplifier models. In this case, the system is modeled in the analog domain and implemented in the digital one. Chapter Ten "e;White-Box Models of Optimal-Sized Solutions of Analog Integrated Circuits"e;) generates analytical expressions for modeling the dominant behavior of CMOS analog circuits. Finally, Chapter Eleven ("e;Radial Basis Function Surrogate Modeling for the Accurate Design of Analog Circuits"e;) applies modern modeling approaches to accomplish real target specifications and to improve the design of reliable circuits.