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Advanced heterogeneous memory subsystems for energy-constrained computing

Produktform: Buch / Einband - flex.(Paperback)

Abstract The performance and energy efficiency of today’s computing systems are limited by the underlying main memory architectures. This is due to the widening gap between the CPU performance and the main memory (DRAM) performance (memory wall), as well as the proliferation of several memory-centric applications that demand higher bandwidth, lower access latency, larger capacity, and improved energy efficiency from the main memory. Moreover, DRAMs can not keep pace with the required main memory capacities because of the restrictions in improving the cell density due to the slowdown in scaling and the high leakage power consumption. Emerging Non-Volatile Memory (NVM) technologies, specifically Metal Oxide Resistive Random Access Memory (RRAM), is a promising alternative to DRAM as it offers higher capacity, scalability, and better energy efficiency. However, RRAMs suffer from large access latencies and limited write endurance, making their integration into the main memory subsystem challenging. RRAM technology is still in research or the early stages of production, and thus, there are no accurate architectural models available for system-level design space explorations. This thesis conducted scientific investigations to optimize DRAM as well as to incorporate RRAM into the main memory. The significant outcomes of DRAM research are the advanced refresh techniques and retention error models to optimize DRAM refresh, and an advanced measurement platform to validate these techniques and models via conducting measurements on off-the-shelf commodity DRAMs. The integration of RRAM requires restructuring of the entire main memory subsystem. The primary research contributions in this direction include models and an architectural exploration framework for RRAMs, the architecture of a new 3D-hybrid main memory consisting of DRAM and RRAM, joint design space explorations of the hybrid memory and its controller using hardware and software techniques, and investigations on specific applications for this new memory architecture.weiterlesen

Dieser Artikel gehört zu den folgenden Serien

Sprache(n): Englisch

ISBN: 978-3-9597415-5-2 / 978-3959741552 / 9783959741552

Verlag: RPTU Rheinland-Pfälzische Technische Universität Kaiserslautern Landau

Erscheinungsdatum: 12.10.2021

Seiten: 131

Auflage: 1

Autor(en): Deepak Molly Mathew

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