23.2 A 5Gb/s/pin 8Gb LPDDR4X SDRAM with power-isolated LVSTL and split-die architecture with 2-die ZQ calibration scheme

2017 IEEE International Solid-State Circuits Conference (ISSCC) Pub Date : 2017-02-01 DOI:10.1109/ISSCC.2017.7870425

Chang-Kyo Lee, Yoon-Joo Eom, Jin-Hee Park, Junha Lee, Hye-Ran Kim, Kihan Kim, Young-Ryeol Choi, Ho-Jun Chang, Jonghyuk Kim, Jong-Min Bang, Seungjun Shin, Hanna Park, Su-Jin Park, Young-Ryeol Choi, Hoon Lee, Kyong-Ho Jeon, Jae-Young Lee, Hyo-Joo Ahn, Kyoung-Ho Kim, Jung-Sik Kim, Soobong Chang, H. Hwang, Du-Hwi Kim, Yoon-Hwan Yoon, S. Hyun, Joonbae Park, Yoon-Gyu Song, Youn-Sik Park, H. Kwon, Seung-Jun Bae, T. Oh, Indal Song, Yong-Cheol Bae, J. Choi, Kwang-il Park, Seong-Jin Jang, G. Jin

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引用次数: 22

Abstract

With growing demand for low-power mobile applications, such as wearable devices, smart phones and tablet PCs, low-power mobile DRAM has been identified as a mandatory requirement for low-power system designs. The recently developed LPDDR4 [1] is still a power efficient solution because of its architectural approaches and low-voltage-swing terminated logic (LVSTL). However, demand for enhanced power-efficiency beyond LPDDR4 is still increasing for mobile applications. In this work, a 5.0Gbp/s/pin 8Gb LPDDR4X memory with power-isolated low-voltage-swing terminated logic (PI-LVSTL) and a split-die architecture is proposed to enhance power-efficiency and mass production yield.

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23.2 5Gb/s/引脚8Gb LPDDR4X SDRAM，功率隔离LVSTL，分模架构，2模ZQ校准方案

随着可穿戴设备、智能手机和平板电脑等低功耗移动应用的需求不断增长，低功耗移动DRAM已被确定为低功耗系统设计的强制性要求。最近开发的LPDDR4[1]由于其架构方法和低电压摆幅端接逻辑(LVSTL)，仍然是一种节能解决方案。然而，移动应用对LPDDR4以外的更高能效的需求仍在增加。本文提出了一种5.0 gbps /s/引脚的8Gb LPDDR4X内存，采用功率隔离式低电压摆端逻辑(PI-LVSTL)和分片架构，以提高功耗效率和量产率。

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2017 IEEE International Solid-State Circuits Conference (ISSCC)

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