The concerns on the continuous scaling of mainstream memory technologies have motivated tremendous investment to emerging memories. Being a promising candidate, spin-transfer torque random access memory (STT-RAM) offers nanosecond access time comparable to SRAM, high integration density close to DRAM, non-volatility as Flash memory, and good scalability. It is well positioned as the replacement of SRAM and DRAM for on-chip cache and main memory applications. However, reliability issue continues being one of the major challenges in STT-RAM memory designs due to the process variations and unique thermal fluctuations, i.e., the stochastic resistance switching property of magnetic devices.ududIn this dissertation, I decoupled the reliability issues as following three-folds: First, the characterization of STT-RAM operation errors often require expensive Monte-Carlo runs with hybrid magnetic-CMOS simulation steps, making it impracticable for architects and system designs; Second, the state of the art does not have sufficiently understanding on the unique reliability issue of STT-RAM, and conventional error correction codes (ECCs) cannot efficiently handle such errors; Third, while the information density of STT-RAM can be boosted by multi-level cell (MLC) design, the more prominent reliability concerns and the complicated access mechanism greatly limit its applications in memory subsystems.ududThus, I present a novel through solution set to both characterize and tackle the above reliability challenges in STT-RAM designs. In the first part of the dissertation, I introduce a new characterization method that can accurately and efficiently capture the multi-variable design metrics of STT-RAM cells; Second, a novel ECC scheme, namely, content-dependent ECC (CD-ECC), is developed to combat the characterized asymmetric errors of STT-RAM at 0->1 and 1->0 bit flipping's; Third, I present a circuit-architecture design, namely state-restricted multi-level cell (SR-MLC) STT-RAM design, which simultaneously achieves high information density, good storage reliability and fast write speed, making MLC STT-RAM accessible for system designers under current technology node. Finally, I conclude that efficient robust (or ECC) designs for STT-RAM require a deep holistic understanding on three different levels-device, circuit and architecture. Innovative ECC schemes and their architectural applications, still deserve serious research and investigation in the near future.
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机译:对主流存储技术的持续扩展的担忧已促使对新兴存储器进行巨额投资。自旋传递扭矩随机存取存储器(STT-RAM)是有前途的候选者,其可提供与SRAM相当的纳秒级访问时间,接近DRAM的高集成密度,非易失性(如闪存)以及良好的可扩展性。它可以很好地替代片上缓存和主存储器应用中的SRAM和DRAM。但是,由于工艺变化和独特的热波动,即磁性器件的随机电阻切换特性,可靠性问题仍然是STT-RAM存储器设计中的主要挑战之一。 ud ud在本文中,我对可靠性问题进行了解耦分为以下三个方面:首先,表征STT-RAM操作错误通常需要昂贵的Monte-Carlo运行以及混合磁性CMOS仿真步骤,这对于架构师和系统设计而言是不切实际的。其次,现有技术对STT-RAM的独特可靠性问题还没有足够的了解,并且传统的纠错码(ECC)不能有效地处理这种错误。第三,虽然可以通过多级单元(MLC)设计来提高STT-RAM的信息密度,但更加突出的可靠性问题和复杂的访问机制极大地限制了其在内存子系统中的应用。 ud ud因此,我提出了一种新颖的方法。通过解决方案集来表征和解决STT-RAM设计中的上述可靠性挑战。在论文的第一部分,我介绍了一种新的表征方法,该方法可以准确,有效地捕获STT-RAM单元的多变量设计指标。其次,开发了一种新颖的ECC方案,即内容相关ECC(CD-ECC),以解决STT-RAM在0-> 1和1-> 0比特翻转时的不对称错误。第三,我提出一种电路架构设计,即状态限制多级单元(SR-MLC)STT-RAM设计,该设计同时实现了高信息密度,良好的存储可靠性和快速的写入速度,从而使MLC STT-RAM易于访问。当前技术节点下的系统设计师。最后,我得出结论,针对STT-RAM的高效鲁棒(或ECC)设计需要对三个不同级别(设备,电路和体系结构)有深刻的全面了解。在不久的将来,创新的ECC方案及其体系结构应用仍然值得认真研究和调查。
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