23.1 An 8Gb 12Gb/s/pin GDDR5X DRAM for cost-effective high-performance applications

2017 IEEE International Solid-State Circuits Conference (ISSCC) Pub Date : 2017-02-01 DOI:10.1109/ISSCC.2017.7870424

M. Brox, M. Balakrishnan, M. Broschwitz, Cristian Chetreanu, S. Dietrich, F. Funfrock, Marcos Alvarez Gonzalez, Thomas Hein, Eugen Huber, Daniel Lauber, M. Ivanov, Maksim Kuzmenka, Christian N. Mohr, Francisco Emiliano Munoz, Juan Ocon Garrido, Swetha Padaraju, Sven Piatkowski, Jan Pottgiesser, P. Pfefferl, M. Plan, Jens Polney, Stefan Rau, Michael Richter, Ronny Schneider, R. Seitter, W. Spirkl, M. Walter, Jörg Weller, F. Vitale

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引用次数: 5

Abstract

Over the last years, GDDR5 has emerged as the dominant standard for applications requiring high system bandwidth like graphic cards and game consoles. However, GDDR5 data rates are saturating due to limitations in the clock frequency and column-access cycle time (tCCD). To reach the data rate of 9Gb/s/pin [1], a GDDR5 DRAM has to be clocked at 2.25GHz and operate at a tCCD of 888ps. This combination makes the design of control logic, data path and memory core difficult in a typical DRAM process. Still, the industry is demanding higher system bandwidth to enable continuous improvements in the visual computing arena. For this purpose, an 8Gb GDDR5X DRAM has been developed reaching a data rate of 12Gb/s/pin, which surpasses the fastest published GDDR5 [1] by 33%. This paper introduces GDDR5X and discusses relevant circuit techniques in clock generation, receiver and transmitter design to enable the higher data rates on a conventional DRAM process.

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23.1 8Gb 12Gb/s/引脚GDDR5X DRAM，适用于经济高效的高性能应用

在过去的几年中，GDDR5已经成为图形卡和游戏机等需要高系统带宽的应用程序的主导标准。然而，由于时钟频率和列访问周期时间(tCCD)的限制，GDDR5数据速率趋于饱和。为了达到9Gb/s/引脚[1]的数据速率，GDDR5 DRAM必须以2.25GHz的时钟和888ps的tCCD工作。这种组合使得在典型的DRAM过程中控制逻辑、数据路径和存储核心的设计变得困难。尽管如此，业界仍然要求更高的系统带宽，以实现视觉计算领域的持续改进。为此，已经开发出8Gb GDDR5X DRAM，达到12Gb/s/pin的数据速率，比已发布的最快gddr5[1]高出33%。本文介绍了GDDR5X，并讨论了时钟产生、接收机和发射机设计中的相关电路技术，以实现在传统的DRAM工艺上实现更高的数据速率。

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 IEEE International Solid-State Circuits Conference (ISSCC)

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