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OverviewOversampling techniques based on sigma-delta modulation are widely used to implement the analog/digital interfaces in CMOS VLSI technologies. This approach is relatively insensitive to imperfections in the manufacturing process and offers numerous advantages for the realization of high-resolution analog-to-digital (A/D) converters in the low-voltage environment that is increasingly demanded by advanced VLSI technologies and by portable electronic systems. In The Design of Low-Voltage, Low-Power Sigma-Delta Modulators, an analysis of power dissipation in sigma-delta modulators is presented, and a low-voltage implementation of a digital-audio performance A/D converter based on the results of this analysis is described. Although significant power savings can typically be achieved in digital circuits by reducing the power supply voltage, the power dissipation in analog circuits actually tends to increase with decreasing supply voltages. Oversampling architectures are a potentially power-efficient means of implementing high-resolution A/D converters because they reduce the number and complexity of the analog circuits in comparison with Nyquist-rate converters. In fact, it is shown that the power dissipation of a sigma-delta modulator can approach that of a single integrator with the resolution and bandwidth required for a given application. In this research the influence of various parameters on the power dissipation of the modulator has been evaluated and strategies for the design of a power-efficient implementation have been identified. The Design of Low-Voltage, Low-Power Sigma-Delta Modulators begins with an overview of A/D conversion, emphasizing sigma-delta modulators. It includes a detailed analysis of noise in sigma-delta modulators, analyzes power dissipation in integrator circuits, and addresses practical issues in the circuit design and testing of a high-resolution modulator. The Design of Low-Voltage, Low-Power Sigma-Delta Modulators will be of interest to practicing engineers and researchers in the areas of mixed-signal and analog integrated circuit design. Full Product DetailsAuthor: Shahriar Rabii , Bruce A. WooleyPublisher: Springer-Verlag New York Inc. Imprint: Springer-Verlag New York Inc. Edition: Softcover reprint of the original 1st ed. 1999 Volume: 483 Dimensions: Width: 15.50cm , Height: 1.10cm , Length: 23.50cm Weight: 0.326kg ISBN: 9781461373223ISBN 10: 1461373220 Pages: 187 Publication Date: 12 October 2012 Audience: Professional and scholarly , Professional & Vocational Format: Paperback Publisher's Status: Active Availability: Manufactured on demand We will order this item for you from a manufactured on demand supplier. Table of Contents1 Introduction.- 1.1 Organization.- 1.2 Simulation Details.- 2 Trends Toward Low-Voltage Power Supplies.- 2.1 Technology Scaling in CMOS Processes.- 2.2 Scaling Theory.- 2.3 Battery Cell Technologies for Portable Electronic Systems.- 2.4 Summary.- 3 Analog-to-Digital Conversion.- 3.1 Analog-to-Digital Converters.- 3.2 Nyquist-Rate A/D Converters.- 3.3 Oversampling A/D Converters.- 3.4 Summary.- 4 Power Dissipation in Sigma-Delta A/D Converters.- 4.1 Power Dissipation in a Sigma-Delta Modulator.- 4.2 Ideal Integrator Power Dissipation.- 4.3 Impact of Circuit Nonidealities.- 4.4 Comparison of Amplifier Topologies.- 4.5 Power Dissipation in the Decimation Filter.- 4.6 Summary.- 5 Design of a Low-Voltage, High-Resolution Sigma-Delta Modulator.- 5.1 Modulator Architecture.- 5.2 Signal Scaling.- 5.3 Integrator Implementation.- 5.4 Circuit Noise.- 5.5 Modulator Specifications.- 5.6 Summary.- 6 Implementation of an Experimental Low-Voltage Modulator.- 6.1 The Integrators.- 6.2 The Operational Amplifiers.- 6.3 The Quantizers.- 6.4 The Clocks.- 6.5 Clock Boosters.- 6.6 Decimation Filtering.- 6.7 Experimental Results.- 6.8 Comparison of the Power Efficiency of A/D Converters.- 6.9 Summary.- 7 Conclusion.- 7.1 Recommendations for Further Investigation.- A Fundamental Limits.- A.1 Power in a Switched-Capacitor Integrator.- A.2 Power in a Continuous-Time Integrator.- A.3 Power in a Switched-Current Integrator.- B Power Dissipation vs. Supply Voltage and Oversampling Ratio.- B.1 Folded Cascode Amplifier.- B.2 Two-Stage Class A Amplifier.- B.3 Two-Stage Class A/AB Amplifier.- C Effects of Capacitor Mismatch.- D Test Setup.ReviewsAuthor InformationTab Content 6Author Website:Countries AvailableAll regions |