J. Li, Xiao-Qing Zeng, Lei Xie, Jun Chen, Jianyun Zhang, Yawei Guo
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引用次数: 20
摘要
本文介绍了一种以0.18 μ m CMOS工艺实现的10位30 ms /s次采样流水线ADC。ADC采用功率高效的放大器共享架构,在该架构中引入了一组开关,以减少两个放大器共享级之间的影响。为了避免在输入端使用专用的采样保持放大器(SHA)电路,并避免第一乘法数模转换器(MDAC)和闪存输入信号路径之间的匹配要求,在传统的无SHA架构中,这是非常严格的。在全采样率下,样机的微分非线性和积分非线性分别小于0.57和0.8 LSB。当输入频率高达30 MHz时,ADC的有效位数(ENOB)高于9.1,这是30 MS/s时奈奎斯特速率(fs/2)的两倍。ADC从1.8 v电源消耗21.6 mW,占地0.7 mm2,其中还包括带隙和缓冲放大器
A 1.8-V 22-mW 10-bit 30-MS/s Subsampling Pipelined CMOS ADC
This paper describes a 10-bit 30-MS/s subsampling pipelined ADC that is implemented in a 0.18 mum CMOS process. The ADC adopts a power efficient amplifier sharing architecture in which a set of switches is introduced to reduce the influence between the two opamp-sharing successive stages. A new configuration is used in the first stage of the ADC to avoid using a dedicated sample-and-hold amplifier (SHA) circuit at the input and to avoid the matching requirement between the first multiplying digital-to-analog converter (MDAC) and flash input signal paths, which is very strict in a traditional SHA-less architecture. The measured differential and integral nonlinearities of the prototype show less than 0.57 least significant bit (LSB) and 0.8 LSB respectively at full sampling rate. The ADC exhibits higher than 9.1 effective number of bits (ENOB) for input frequencies up to 30 MHz, which is the twofold Nyquist rate (fs/2), at 30 MS/s. The ADC consumes 21.6 mW from a 1.8-V supply and occupies 0.7 mm2, which also includes the bandgap and buffer amplifiers
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