ISU Electrical and Computer Engineering Archives

Low power high speed and high accuracy design methodologies for Pipeline Analog-to- Digital converters

Katyal, Vipul (2008) Low power high speed and high accuracy design methodologies for Pipeline Analog-to- Digital converters. PhD thesis, Iowa State University.

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Different aspects of power optimization of a high-speed, high-accuracy pipeline Analog-to-Digital Converters (ADCs) are considered to satisfy the current and future needs of portable communication devices. First power optimized design strategies for the amplifiers are introduced. Closed form expressions of power w.r.t settling requirements are presented to facilitate a fair comparison and selection of the amplifier structure. Next a new low offset dynamic comparator has been designed. Simulation based sensitivity analysis is performed to demonstrate the robustness of the new comparator with respect to stray capacitances, common mode voltage errors and timing errors. With simplified amplifier power model along with the use of dynamic comparators, a method to optimize the power consumption of a pipeline ADC with kT/C noise constraint is also developed. The total power dependence on capacitor scaling and stage resolution is investigated for a near-optimal solution. After considering the power requirements of a pipeline ADC, design and statistical modeling of over-range protection requirements is investigated. Closed form statistical expressions for the over-range requirements are developed to assist in the allocation of the error budgets to different pipeline blocks. A new over-range protection algorithm is also developed that relaxes the amplifier design and power requirements. Finally, two new CMOS Schmitt trigger designs are proposed which can be used as clock inputs for the pipeline ADC. In the new designs, sizing of the feedback inverters is used for independent trip point control. The new designs have also a modest reduction in sensitivity to process variations along with immunity to the kick-back noise without the addition of path delay.

EPrint Type:Thesis (PhD)
Subjects:Computer Engineering > VLSI > Mixed Circuit VLSI
ID Code:445
Identification Number:Identification Number UNSPECIFIED
Deposited By:Mr. Vipul Katyal
Deposited On:23 July 2008

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