为新兴 3D-IC 设计实现低级 SRAM 缓存的精细分区

IF 2 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IEEE Journal on Exploratory Solid-State Computational Devices and Circuits Pub Date : 2024-09-26 DOI:10.1109/JXCDC.2024.3468386

Sudipta Das;Bhawana Kumari;Siva Satyendra Sahoo;Yukai Chen;James Myers;Dragomir Milojevic;Dwaipayan Biswas;Julien Ryckaert

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引用次数: 0

摘要

扩大芯片内存容量是缓解内存墙瓶颈的主要方法之一。目前正在积极探索利用新型分区的各种 2.5-D/3-D 集成方案，以提高系统性能。然而，对内存宏进行细粒度功能分区的报道并不多见。随着新兴 CMOS 逻辑路线图的出现，静态 RAM (SRAM) 的扩展停滞不前，因此我们提出了利用 CMOS (AuC) 技术范例下的阵列对低级（访问速度更快）高速缓存进行三维分区的方案。我们的研究重点是对 SRAM 位元组和外围电路进行分区和优化，从而实现异构集成，将内存宏的工作频率提高 12%，漏电功率降低 50%。在应用于 64 位移动片上系统 (SoC) CPU 内核时，与 2-D 基线相比，我们实现了高达 60% 的能效提升，与标准逻辑存储器 3-D 分区方案相比，工作频率提高了 14%。

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Toward Fine-Grained Partitioning of Low-Level SRAM Caches for Emerging 3D-IC Designs

Scaling on-chip memory capacity is one of the primary approaches to mitigate memory wall bottlenecks. Various 2.5-D/3-D integration schemes, leveraging novel partitioning, are being actively explored to improve system performance. However, fine-grained functional partitioning of memory macros is not widely reported. As static RAM (SRAM) scaling stagnates with emerging CMOS logic roadmap, we propose a partitioning of low-level (faster access) caches in 3-D using an array under CMOS (AuC) technology paradigm. Our study focuses on partitioning and optimization of SRAM bit-cells and peripheral circuits, enabling heterogeneous integration, achieving up to 12% higher operating frequency with 50% leakage power reduction in the memory macros. Applied on a 64-bit mobile system-on-chip (SoC) CPU core, we achieve up to 60% higher energy efficiency compared with 2-D baseline and 14% increase in operating frequency compared with standard memory-on-logic 3-D partitioning scheme.

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来源期刊

IEEE Journal on Exploratory Solid-State Computational Devices and Circuits COMPUTER SCIENCE, HARDWARE & ARCHITECTURE-

CiteScore

5.00

自引率

4.20%

发文量

审稿时长

13 weeks