1,163 research outputs found

    Design of pixel-level ADCs for energy-sensitive hybrid pixel detectors

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    Single-photon counting hybrid pixel detectors have shown\ud to be a valid alternative to other types of X-ray imaging\ud devices due to their high sensitivity, low noise, linear behavior\ud and wide dynamic range. One important advantage of these\ud devices is the fact that detector and readout electronics are\ud manufactured separately. This allows the use of industrial\ud state-of-the-art CMOS processes to make the readout\ud electronics, combined with a free choice of detector material\ud (high resistivity Silicon, GaAs or other). By measuring not\ud only the number of X-ray photons but also their energies (or\ud wavelengths), the information content of the image increases,\ud given the same X-ray dose. We have studied several\ud possibilities of adding energy sensitivity to the single photon\ud counting capability of hybrid pixel detectors, by means of\ud pixel-level analog-to-digital converters. We show the results of\ud simulating different kinds of analog-to-digital converters in\ud terms of power, area and speed

    Transistor-Level Synthesis of Pipeline Analog-to-Digital Converters Using a Design-Space Reduction Algorithm

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    A novel transistor-level synthesis procedure for pipeline ADCs is presented. This procedure is able to directly map high-level converter specifications onto transistor sizes and biasing conditions. It is based on the combination of behavioral models for performance evaluation, optimization routines to minimize the power and area consumption of the circuit solution, and an algorithm to efficiently constraint the converter design space. This algorithm precludes the cost of lengthy bottom-up verifications and speeds up the synthesis task. The approach is herein demonstrated via the design of a 0.13 μm CMOS 10 bits@60 MS/s pipeline ADC with energy consumption per conversion of only 0.54 pJ@1 MHz, making it one of the most energy-efficient 10-bit video-rate pipeline ADCs reported to date. The computational cost of this design is of only 25 min of CPU time, and includes the evaluation of 13 different pipeline architectures potentially feasible for the targeted specifications. The optimum design derived from the synthesis procedure has been fine tuned to support PVT variations, laid out together with other auxiliary blocks, and fabricated. The experimental results show a power consumption of 23 [email protected] V and an effective resolution of 9.47-bit@1 MHz. Bearing in mind that no specific power reduction strategy has been applied; the mentioned results confirm the reliability of the proposed approach.Ministerio de Ciencia e Innovación TEC2009-08447Junta de Andalucía TIC-0281

    Design of Low Power and Power Scalable Pipelined ADC Using Current Modulated Power Scale

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    This work represents a power scalable pipelined ADC, which achieves low power variation depends upon the sampling rate and enables variation in throughput. The keys to power scalability at high sampling rates were current modulation-based architecture and the development of novel rapid power-on Op-amp, which can completely and quickly power on/off by the feedback approach. The result achieved in this design is as high as 50 Msps and as low as 1 ksps, keeping some important parameters of ADC as ENOB and SNDR are almost constant. Power variation in ADC has a flexible range from 7.5 µW to 17 mW, which is lower power consumption than previous works

    Modeling and Implementation of A 6-Bit, 50MHz Pipelined ADC in CMOS

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    The pipelined ADC is a popular Nyquist-rate data converter due to its attractive feature of maintaining high accuracy at high conversion rate with low complexity and power consumption. The rapid growth of its application such as mobile system, digital video and high speed data acquisition is driving the pipelined ADC design towards higher speed, higher precision with lower supply voltage and power consumption. This thesis project aims at modeling and implementation of a pipelined ADC with high speed and low power consumption

    A 12-bit, 40 msamples/s, low-power, low-area pipeline analog-to-digital converter in CMOS 0.18 mum technology.

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    With advancements in digital signal processing in recent years, the need for high-speed, high-resolution analog-to-digital converters (ADCs) which can be used in the analog front-end has been increasing. Some examples of these applications are image and video signal processing, wireless communications and asymmetrical digital subscriber line (ADSL). In CMOS integrated circuit design, it is desirable to integrate the digital circuit and the ADC in one microchip to reduce the cost of fabrication. Consequently the power dissipation and area of the ADCs are important design factors. The original contributions in this thesis are as follows. Since the performance of pipeline ADCs significantly depends on the op-amps and comparators circuits, the performance of various comparators is analyzed and the effect of op-amp topology on the performance of pipeline ADCs is investigated. This thesis also presents a novel architecture for design of low-power and low-area pipelined ADCs which will be more useful for very low voltage applications in the future. At the schematic level, a low-power CMOS implementation of the current-mode MDAC is presented and an improved voltage comparator is designed. With the proposed design and the optimization methodology it is possible to reduce power dissipation and area compared with conventional fully differential schemes.Dept. of Electrical and Computer Engineering. Paper copy at Leddy Library: Theses & Major Papers - Basement, West Bldg. / Call Number: Thesis2004 .M64. Source: Masters Abstracts International, Volume: 43-01, page: 0281. Adviser: C. Chen. Thesis (M.A.Sc.)--University of Windsor (Canada), 2004

    Design and Analysis of a Low-Power 8-Bit 500 KS/S SAR ADC for Bio-Medical Implant Devices

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    This thesis project involves the design and analysis of an 8-bit Successive Approximation Register (SAR) Analog to Digital Convertor (ADC), designed for low- power applications such as bio-medical implants. The sampling rate for this ADC is 500 KS/s. The power consumption for the whole SAR ADC system was measured to be 2.1 uW. The novelty of this project is the proposal of an extremely energy efficient comparator architecture. The result is the design of a final ADC with reasonable sampling speed, accuracy and low power consumption. In this project, all the different subsystems have been designed at the transistor level with 45 nm CMOS technology. The logical circuit was designed using Verilog language. It was then synthesized and integrated in the overall system
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