通过随机解调的模拟-信息转换

2006 IEEE Dallas/CAS Workshop on Design, Applications, Integration and Software Pub Date : 2006-10-01 DOI:10.1109/DCAS.2006.321036

S. Kirolos, J. Laska, M. Wakin, M. Duarte, D. Baron, T. Ragheb, Y. Massoud, Richard Baraniuk

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引用次数: 417

摘要

雷达和通信信号处理中的许多问题都涉及到非常高带宽的射频信号。这对可能尝试使用高速率模数转换器(ADC)对这些信号进行采样的系统提出了严重的挑战，正如Shannon/Nyquist采样定理所规定的那样。然而，在这些情况下，信号的信息水平往往远低于实际带宽，这就提出了是否可以开发更有效的方案来测量此类信号的问题。在本文中，我们提出了一个系统，使用调制，滤波和采样来产生一组低速率的数字测量。我们的“模拟-信息转换器”(AIC)受到压缩感知(CS)理论的启发，该理论指出，在某些字典中具有稀疏表示的离散信号可以从该信号的少量线性投影中恢复。我们将CS理论推广到连续时间稀疏信号，在CS背景下解释我们提出的AIC系统，并讨论有关实现的实际问题

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Analog-to-Information Conversion via Random Demodulation

Many problems in radar and communication signal processing involve radio frequency (RF) signals of very high bandwidth. This presents a serious challenge to systems that might attempt to use a high-rate analog-to-digital converter (ADC) to sample these signals, as prescribed by the Shannon/Nyquist sampling theorem. In these situations, however, the information level of the signal is often far lower than the actual bandwidth, which prompts the question of whether more efficient schemes can be developed for measuring such signals. In this paper we propose a system that uses modulation, filtering, and sampling to produce a low-rate set of digital measurements. Our "analog-to-information converter" (AIC) is inspired by the theory of compressive sensing (CS), which states that a discrete signal having a sparse representation in some dictionary can be recovered from a small number of linear projections of that signal. We generalize the CS theory to continuous-time sparse signals, explain our proposed AIC system in the CS context, and discuss practical issues regarding implementation

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2006 IEEE Dallas/CAS Workshop on Design, Applications, Integration and Software

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