用于缩短比特流长度的噪声整形二进制到随机转换器

IF 5.1 2区 计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS
Kleanthis Papachatzopoulos;Vassilis Paliouras
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引用次数: 0

摘要

对于定点精度要求适中的应用来说,随机计算因其复杂性最低而备受关注。在这些系统中,随机比特流对数据样本进行编码。导出的比特流用于处理。位流长度决定了位串行实现的计算延迟和位并行实现的硬件复杂度。噪声整形是一种反馈技术,可将量化噪声移至信号相关带宽之外。本文提出了一种以噪声整形为基础的技术,可减少实现特定信噪比(SQNR)所需的随机比特流长度。该技术通过将二进制采样编码为随机流的数字单元(以下称为二进制-随机转换器)来实现。此外,还推导出了比特流长度缩减与信号带宽相关的公式。分析了实现拟议技术的一阶和二阶转换器。通过将随机转换器置于噪声整形环路内部或外部,介绍了两种不同的架构。在信号质量水平相同的情况下,与传统的二进制到随机转换器进行了定量比较,发现所提出的比特流长度缩减效果更好。与传统方法不同的是,本文采用的比特流长度不是二的幂次,并提出了一种改进的随机到二进制转换方案,作为拟议的二进制到随机转换器的一部分。与传统转换器相比,一阶和二阶转换器在等长比特流和低信号带宽条件下的 SQNR 分别提高了 29.8 dB 和 42.1 dB。所研究的转换器采用 28 纳米 FDSOI 技术设计和合成,适用于各种位宽。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Noise-Shaping Binary-to-Stochastic Converters for Reduced-Length Bit-Streams
Stochastic computations have attracted significant attention for applications with moderate fixed-point accuracy requirements, as they offer minimal complexity. In these systems, a stochastic bit-stream encodes a data sample. The derived bit-stream is used for processing. The bit-stream length determines the computation latency for bit-serial implementations and hardware complexity for bit-parallel ones. Noise shaping is a feedback technique that moves the quantization noise outside the bandwidth of interest of a signal. This article proposes a technique that builds on noise shaping and reduces the length of the stochastic bit-stream required to achieve a specific Signal-to-Quantization-Noise Ratio (SQNR). The technique is realized by digital units that encode binary samples into stochastic streams, hereafter called as binary-to-stochastic converters. Furthermore, formulas are derived that relate the bit-stream length reduction to the signal bandwidth. First-order and second-order converters that implement the proposed technique are analyzed. Two architectures are introduced, distinguished by placing a stochastic converter either inside or outside of the noise-shaping loop. The proposed bit-stream length reduction is quantitatively compared to conventional binary-to-stochastic converters for the same signal quality level. Departing from conventional approaches, this article employs bit-stream lengths that are not a power of two, and proposes a modified stochastic-to-binary conversion scheme as a part of the proposed binary-to-stochastic converter. Particularly, SQNR gains of 29.8 dB and 42.1 dB are achieved for the first-order and second-order converters compared to the conventional converters for equal-length bit-streams and low signal bandwidth. The investigated converters are designed and synthesized at a 28-nm FDSOI technology for a range of bit widths.
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来源期刊
IEEE Transactions on Emerging Topics in Computing
IEEE Transactions on Emerging Topics in Computing Computer Science-Computer Science (miscellaneous)
CiteScore
12.10
自引率
5.10%
发文量
113
期刊介绍: IEEE Transactions on Emerging Topics in Computing publishes papers on emerging aspects of computer science, computing technology, and computing applications not currently covered by other IEEE Computer Society Transactions. Some examples of emerging topics in computing include: IT for Green, Synthetic and organic computing structures and systems, Advanced analytics, Social/occupational computing, Location-based/client computer systems, Morphic computer design, Electronic game systems, & Health-care IT.
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