Chapter 1        Introduction

1.1       Nonlinear Data Conversion

1.2       Motivation

1.3       Research Goals

1.4       Innovative Contributions

1.5       Achievements

1.6       Document Structure

2.1       Floating Point Converters

2.2       Logarithmic Converters

2.2.1    Logarithmic Pipeline Converters

2.2.2    Two-Step Logarithmic Converters

2.3       Piecewise Linear Converters

2.4       Oversampled Converters

2.4.2    Sigma-Delta Converters

2.5       Nonlinear Conversion Using Pulse Width Modulation

2.5.1    Modified Integrating ADC

2.5.2    PWM Average Approximation

2.6       Nonlinear Conversion Using a Lookup Table

2.7       Other Architectures

2.9       Conclusions

Chapter 3        Proposed Logarithmic ADC

3.1       Proposed Logarithmic ADC Architecture

3.2       Voltage-to-Time Conversion Element

3.3       Regeneration detection

3.4       Sources of nonlinearity

3.4.2    S3 switch resistance

3.4.3    Regeneration detection circuitry

3.4.4    Thermal Noise

3.5       Architecture Variants

3.5.1    Multiple Simultaneous Conversions

3.5.2    Polarity and magnitude independent conversion

3.7       Conclusions

Chapter 4        Logarithmic VTC Design

4.1       Determination of key design parameters

4.1.1    Sampling capacitors

4.1.2    Total transconductance

4.1.3    Degeneration resistors

4.1.4    Sampling switches

4.1.5    Regeneration detection

4.2       Simulaton Results

4.2.1    Process variations

4.2.2    Input referred noise and offset

4.3       Conclusions

Chapter 5        Circuit and Layout Level Validation

5.1       Configuration chain

5.2       Frequency divider

5.3       Frequency output pad

5.4       Voltage-to-time conversion elements

5.6       Programmable delay block

5.7       Common mode voltage effect on the regeneration detection voltage

5.8       Demonstrator integrated circuit layout

5.9       Simulation results

5.10     Conclusions

Chapter 6        Evaluation of the Prototype

6.2       Test Description

6.3       Experimental Results

6.3.1    Performance comparison

6.4       Input range limitation

6.5       Conclusions

Chapter 7        Future Work and Conclusions

7.2       Future Work

7.2.1    Calibration

7.2.2    Improved Conversion Method

References

Mauro Santos (IEEE S'08-M'18) concluded his PhD from Instituto Superior Tecnico, Lisbon in 2018 in the area of microelectronics. His research interests are mainly in analog-to-digital signal conversion, analog and mixed signal IC design and power electronics.

Jorge Manuel Guilherme is a professor at the Instituto Politecnico Tomar since 1996. He works at the Integrated Circuits Group of Instituto de Telecomunicações since 2004. His scientific interests are in the areas of microelectronics, data conversion and power management.

This book presents a novel logarithmic conversion architecture based on cross-coupled inverter. An overview of the current state of the art of logarithmic converters is given where most conventional logarithmic analog-to-digital converter architectures are derived or adapted from linear analog-to-digital converter architectures, implying the use of analog building blocks such as amplifiers. The conversion architecture proposed in this book differs from the conventional logarithmic architectures. Future possible studies on integrating calibration in the voltage to time conversion element and work on an improved conversion architecture derived from the architecture are also presented in this book.