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OverviewSwitched capacitor (SC) techniques are well proven to be excellent candidates for implementing critical analogue functions with high accuracy, surpassing other analogue techniques when embedded in mixed-signal CMOS VLSI. Conventional SC circuits are primarily limited in accuracy by a) capacitor matching and b) the accuracy with which a differential amplifier can squeeze charge from one capacitor to another between clock periods. In Switched-Capacitor Techniques for High-Accuracy Filter and ADC Design, alternative SC techniques are proposed which allow the achievement of higher intrinsic analogue functional accuracy than previously possible in such application areas as analogue filter and ADC design. The design philosophy is to create the required functionality without relying on digital calibration or correction means but instead to develop methods which have reduced dependence on both component matching (especially capacitor matching) and parasitic effects (especially parasitic capacitance). However, the proposed techniques are just as amenable to further digital accuracy enhancement via calibration and/or correction as traditional methods. Two popular application areas are explored in the course of this book for exploitation of the proposed techniques, viz. SC filters and algorithmic ADCs - both cyclic and pipelined. Furthermore, efficient system level design procedures are explored in each of these two areas. The validity of the concepts developed and analyzed in Switched-Capacitor Techniques for High-Accuracy Filter and ADC Design has been demonstrated in practice with the design of CMOS SC bandpass filters and algorithmic ADC stages. For example, a 10.7MHz radio IF selectivity filter integrated in standard CMOS, employing the proposed methods, achieves an accuracy greater than ceramic filters. Another example is an ADC with better than 12-bit intrinsic accuracy, albeit capacitors with only 9-bits matching accuracy were used in the realization. The ADC architecture is also very robust and proven in an embedded digital VLSI application in the very newest 65nm CMOS. The power consumptions and silicon areas of the solutions proposed here are lower than other known solutions from the literature. Full Product DetailsAuthor: Patrick J. Quinn , Arthur H.M. van RoermundPublisher: Springer-Verlag New York Inc. Imprint: Springer-Verlag New York Inc. Edition: 2007 ed. Dimensions: Width: 15.50cm , Height: 1.50cm , Length: 23.50cm Weight: 1.210kg ISBN: 9781402062575ISBN 10: 1402062575 Pages: 244 Publication Date: 24 July 2007 Audience: Professional and scholarly , Professional & Vocational Format: Hardback Publisher's Status: Active Availability: Out of print, replaced by POD We will order this item for you from a manufatured on demand supplier. Table of ContentsKey Concepts for Accurate SC Design.- SC Amplifier Design at Black-Box Level.- Amplifier Architectures for SC Applications.- Low-Sensitivity SC BPF Concepts.- High-Accuracy d-QR SC BPF Design and Measurements.- ADC Design at Black-Box Level.- Design Criteria for Cyclic and Pipelined ADCs.- Capacitor Matching Insensitive High-Resolution Low-Power ADC Concept.- High-Accuracy ADC Design and Measurements.ReviewsAuthor InformationProfessor Arthur van Roermund has (co-)authored and edited numerous books for Springer and he is well established within the Analog Circuit Design community Tab Content 6Author Website:Countries AvailableAll regions |