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Energy-efficient Memory System Design with Spintronics

<p>Modern computing platforms, from servers to mobile devices,
demand ever-increasing amounts of memory to keep up with the growing amounts of
data they process, and to bridge the widening processor-memory gap. A large and
growing fraction of chip area and energy is expended in memories, which face
challenges with technology scaling due to increased leakage, process
variations, and unreliability. On the other hand, data intensive workloads such
as machine learning and data analytics pose increasing demands on memory
systems. Consequently, improving the energy-efficiency and performance of
memory systems is an important challenge for computing system designers.</p>

<p>Spintronic memories, which offer several desirable
characteristics - near-zero leakage, high density, non-volatility and high
endurance - are of great interest for designing future memory systems. However,
these memories are not drop-in replacements for current memory technologies,
viz. Static Random Access Memory (SRAM) and Dynamic Random Access Memory
(DRAM). They pose unique challenges such as variable access times, and require
higher write latency and write energy. This dissertation explores new
approaches to improving the energy efficiency of spintronic memory systems.</p>

<p>The dissertation first explores the design of approximate
memories, in which the need to store and access data precisely is foregone in
return for improvements in energy efficiency. This is of particular interest,
since many emerging workloads exhibit an inherent ability to tolerate
approximations to their underlying computations and data while still producing
outputs of acceptable quality. The dissertation proposes that approximate
spintronic memories can be realized either by reducing the amount of data that
is written to/read from them, or by reducing the energy consumed per access. To
reduce memory traffic, the dissertation proposes approximate memory
compression, wherein a quality-aware memory controller transparently
compresses/decompresses data written to or read from memory. For broader
applicability, the quality-aware memory controller can be programmed to specify
memory regions that can tolerate approximations, and conforms to a specified
error constraint for each such region. To reduce the per-access energy, various
mechanisms are identified at the circuit and architecture levels that yield
substantial energy benefits at the cost of small probabilities of read, write
or retention failures. Based on these mechanisms, a quality-configurable Spin
Transfer Torque Magnetic RAM (STT-MRAM) array is designed in which read/write
operations can be performed at varying levels of accuracy and energy at
runtime, depending on the needs of applications. To illustrate the utility of
the proposed quality-configurable memory array, it is evaluated as an L2 cache
in the context of a general-purpose processor, and as a scratchpad memory for a
domain-specific vector processor.</p>

<p>The dissertation also explores the design of caches with
Domain Wall Memory (DWM), a more advanced spintronic memory technology that offers
unparalleled density arising from a unique tape-like structure. However, this
structure also leads to serialized access to the bits in each bit-cell,
resulting in increased access latency, thereby degrading overall performance.
To mitigate the performance overheads, the dissertation proposes a reconfigurable
DWM-based cache architecture that modulates the active bits per tape with
minimal overheads depending on the application's memory access characteristics.
The proposed cache is evaluated in a general purpose processor and improvements
in performance are demonstrated over both CMOS and previously proposed
spintronic caches.</p>

<p>In summary, the dissertation suggests directions to improve
the energy efficiency of spintronic memories and re-affirms their potential for
the design of future memory systems.</p>

  1. 10.25394/pgs.7479371.v2
Identiferoai:union.ndltd.org:purdue.edu/oai:figshare.com:article/7479371
Date03 January 2019
CreatorsAshish Ranjan (5930180)
Source SetsPurdue University
Detected LanguageEnglish
TypeText, Thesis
RightsCC BY 4.0
Relationhttps://figshare.com/articles/Energy-e_cient_Memory_System_Design_with_Spintronics/7479371

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