Broadband opamps for multi-channel communication systems make strong demands on linearity performance. This book, written for Analog CMOS designers, presents a thorough analysis of the nonlinear behaviour of circuits, to obtain opamps with low distortion.
Broadband opamps for multi-channel communication systems make strong demands on linearity performance. This book, written for Analog CMOS designers, presents a thorough analysis of the nonlinear behaviour of circuits, to obtain opamps with low distortion.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
Produktdetails
The Springer International Series in Engineering and Computer Science 720
List of Figures. List of Tables. Symbols and Abbreviations. Foreword. Preface. Acknowledgement. 1: Introduction. 1.1. Motivation. 1.2. Earlier Work. 1.3. Design Issues for Low Nonlinear Distortion. 1.4. Outline. 1.5. Summary. 2: Specification and Analysis of Nonlinear Circuits. 2.1. Linearity Specifications. 2.2. Volterra Series. 2.3. Phasor Method. 2.4. Concluding Remarks. 3: Biasing and Opamp Modeling for Low Distortion. 3.1. Biasing for Robust Linearity Performance. 3.2 Opamp Modeling for Nonlinear Analysis. 4: Nonlinear Analyzes of Feedback Miller Opamp. 4.1. The Non-Inverting. 4.2. The Inverting Configuration. 4.3. Concluding Remarks. 5: Opamp Circuits with High Linearity Performance. 5.1. Measurement System. 5.2. A 1.8V CMOS Opamp with -77.5dB HD2 and HD3 at 80MHz. 5.3. A 3.3V CMOS Opamp with -80dB HD3 at 80 MHz. 5.4. A 3.3V CMOS Current Opamp with -63dB HD3 at 100MHz. 5.5. A 3.3V CMOS Unity-Gain Opamp with -80dB HD3 at 10MHz. 5.6. Concluding Remarks. 6: Conclusions and Discussions. 6.1. Opamp Topologies Versus Linearity. Appendix A:Transistor Model. Appendix B: Closed Loop Opamp Transfer Functions. Appendix C: Open Loop Opamp Transfer Functions.
From the contents: List of Figures.- List of Tables.- Symbols and Abbreviations.- Foreword.- Preface.- Acknowledgement.- 1: Introduction.- 2: Specification and Analysis of Nonlinear Circuits.- 3: Biasing and Opamp Modeling for Low Distortion.- 4: Nonlinear Analyzes of Feedback Miller Opamp.- 5: Opamp Circuits with High Linearity Performance.- 6: Conclusions and Discussions.- Appendix A:Transistor Model. Appendix B: Closed Loop Opamp Transfer Functions. Appendix C: Open Loop Opamp Transfer Functions.
List of Figures. List of Tables. Symbols and Abbreviations. Foreword. Preface. Acknowledgement. 1: Introduction. 1.1. Motivation. 1.2. Earlier Work. 1.3. Design Issues for Low Nonlinear Distortion. 1.4. Outline. 1.5. Summary. 2: Specification and Analysis of Nonlinear Circuits. 2.1. Linearity Specifications. 2.2. Volterra Series. 2.3. Phasor Method. 2.4. Concluding Remarks. 3: Biasing and Opamp Modeling for Low Distortion. 3.1. Biasing for Robust Linearity Performance. 3.2 Opamp Modeling for Nonlinear Analysis. 4: Nonlinear Analyzes of Feedback Miller Opamp. 4.1. The Non-Inverting. 4.2. The Inverting Configuration. 4.3. Concluding Remarks. 5: Opamp Circuits with High Linearity Performance. 5.1. Measurement System. 5.2. A 1.8V CMOS Opamp with -77.5dB HD2 and HD3 at 80MHz. 5.3. A 3.3V CMOS Opamp with -80dB HD3 at 80 MHz. 5.4. A 3.3V CMOS Current Opamp with -63dB HD3 at 100MHz. 5.5. A 3.3V CMOS Unity-Gain Opamp with -80dB HD3 at 10MHz. 5.6. Concluding Remarks. 6: Conclusions and Discussions. 6.1. Opamp Topologies Versus Linearity. Appendix A:Transistor Model. Appendix B: Closed Loop Opamp Transfer Functions. Appendix C: Open Loop Opamp Transfer Functions.
From the contents: List of Figures.- List of Tables.- Symbols and Abbreviations.- Foreword.- Preface.- Acknowledgement.- 1: Introduction.- 2: Specification and Analysis of Nonlinear Circuits.- 3: Biasing and Opamp Modeling for Low Distortion.- 4: Nonlinear Analyzes of Feedback Miller Opamp.- 5: Opamp Circuits with High Linearity Performance.- 6: Conclusions and Discussions.- Appendix A:Transistor Model. Appendix B: Closed Loop Opamp Transfer Functions. Appendix C: Open Loop Opamp Transfer Functions.
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