An ultra high density pseudo dual-port SRAM in 16nm FINFET process for graphics processors

2017 30th IEEE International System-on-Chip Conference (SOCC) Pub Date : 2017-09-01 DOI:10.1109/SOCC.2017.8225996

V. Nautiyal, G. Singla, Lalita Gupta, S. Dwivedi, M. Kinkade

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引用次数: 7

Abstract

In recent times, graphic, audio and video definition has improved due to significant advancement in complex algorithms and video processing techniques. These techniques require heterogeneous and multi-core processors because of their complex computation abilities. Dual-port memories have become an essential component of CPUs because multi-core processors require significant data transfer. However, dual-port memories come at a cost of increased area and leakage. In this paper, an ultra-high-density dual-port SRAM (RADPUHD) architecture is proposed which addresses area and leakage challenges. It is designed and fabricated in 16nm technology. This paper presents use of a single-port bitcell to achieve functionality of dual-port SRAM thus improving area efficiency. The use of latches for Port B signals instead of full flip-flops further reduces area. The proposed design is a bolt-on wrapper around a 6T single-port SRAM. This design achieved a memory density of 8.1Mb/mm2 chip area and achieved 53% area savings and approximately 60% leakage savings when compared to an 8T dual-port SRAM that was also fabricated in 16nm. Silicon results show that the proposed circuit is functional down to a minimum operating voltage of 520mV.

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一种用于图形处理器的16nm FINFET工艺的超高密度伪双端口SRAM

近年来，由于复杂算法和视频处理技术的显著进步，图形、音频和视频清晰度得到了改善。这些技术需要异构和多核处理器，因为它们具有复杂的计算能力。由于多核处理器需要大量的数据传输，双端口存储器已成为cpu的重要组成部分。然而，双端口存储器的代价是增加面积和泄漏。本文提出了一种解决面积和泄漏问题的超高密度双端口SRAM (RADPUHD)架构。它采用16nm技术设计和制造。本文提出使用单端口位元来实现双端口SRAM的功能，从而提高面积效率。使用锁存器的端口B信号，而不是完整的触发器进一步减少面积。提出的设计是围绕6T单端口SRAM的螺栓连接包装。该设计实现了8.1Mb/mm2芯片面积的内存密度，与同样采用16nm工艺制造的8T双端口SRAM相比，节省了53%的面积和大约60%的泄漏。硅测试结果表明，该电路的工作电压可低至520mV。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 30th IEEE International System-on-Chip Conference (SOCC)

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