NVMExplorer: A Framework for Cross-Stack Comparisons of Embedded Non-Volatile Memories
Repeated off-chip memory accesses to DRAM drive up operating power for data-intensive applications, and SRAM technology scaling and leakage power limits the efficiency of embedded memories. Future on-chip storage will need higher density and energy efficiency, and the actively expanding field of eme...
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| creator | Pentecost, Lillian Hankin, Alexander Donato, Marco Hempstead, Mark Wei, Gu-Yeon Brooks, David |
| description | Repeated off-chip memory accesses to DRAM drive up operating power for
data-intensive applications, and SRAM technology scaling and leakage power
limits the efficiency of embedded memories. Future on-chip storage will need
higher density and energy efficiency, and the actively expanding field of
emerging, embeddable non-volatile memory (eNVM) technologies is providing many
potential candidates to satisfy this need. Each technology proposal presents
distinct trade-offs in terms of density, read, write, and reliability
characteristics, and we present a comprehensive framework for navigating and
quantifying these design trade-offs alongside realistic system constraints and
application-level impacts. This work evaluates eNVM-based storage for a range
of application and system contexts including machine learning on the edge,
graph analytics, and general purpose cache hierarchy, in addition to describing
a freely available (http://nvmexplorer.seas.harvard.edu/) set of tools for
application experts, system designers, and device experts to better understand,
compare, and quantify the next generation of embedded memory solutions. |
| doi_str_mv | 10.48550/arxiv.2109.01188 |
| format | Article |
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data-intensive applications, and SRAM technology scaling and leakage power
limits the efficiency of embedded memories. Future on-chip storage will need
higher density and energy efficiency, and the actively expanding field of
emerging, embeddable non-volatile memory (eNVM) technologies is providing many
potential candidates to satisfy this need. Each technology proposal presents
distinct trade-offs in terms of density, read, write, and reliability
characteristics, and we present a comprehensive framework for navigating and
quantifying these design trade-offs alongside realistic system constraints and
application-level impacts. This work evaluates eNVM-based storage for a range
of application and system contexts including machine learning on the edge,
graph analytics, and general purpose cache hierarchy, in addition to describing
a freely available (http://nvmexplorer.seas.harvard.edu/) set of tools for
application experts, system designers, and device experts to better understand,
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data-intensive applications, and SRAM technology scaling and leakage power
limits the efficiency of embedded memories. Future on-chip storage will need
higher density and energy efficiency, and the actively expanding field of
emerging, embeddable non-volatile memory (eNVM) technologies is providing many
potential candidates to satisfy this need. Each technology proposal presents
distinct trade-offs in terms of density, read, write, and reliability
characteristics, and we present a comprehensive framework for navigating and
quantifying these design trade-offs alongside realistic system constraints and
application-level impacts. This work evaluates eNVM-based storage for a range
of application and system contexts including machine learning on the edge,
graph analytics, and general purpose cache hierarchy, in addition to describing
a freely available (http://nvmexplorer.seas.harvard.edu/) set of tools for
application experts, system designers, and device experts to better understand,
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data-intensive applications, and SRAM technology scaling and leakage power
limits the efficiency of embedded memories. Future on-chip storage will need
higher density and energy efficiency, and the actively expanding field of
emerging, embeddable non-volatile memory (eNVM) technologies is providing many
potential candidates to satisfy this need. Each technology proposal presents
distinct trade-offs in terms of density, read, write, and reliability
characteristics, and we present a comprehensive framework for navigating and
quantifying these design trade-offs alongside realistic system constraints and
application-level impacts. This work evaluates eNVM-based storage for a range
of application and system contexts including machine learning on the edge,
graph analytics, and general purpose cache hierarchy, in addition to describing
a freely available (http://nvmexplorer.seas.harvard.edu/) set of tools for
application experts, system designers, and device experts to better understand,
compare, and quantify the next generation of embedded memory solutions.</abstract><doi>10.48550/arxiv.2109.01188</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Emerging Technologies Computer Science - Hardware Architecture |
| title | NVMExplorer: A Framework for Cross-Stack Comparisons of Embedded Non-Volatile Memories |
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