TY - GEN
T1 - A process-variation-aware multi-scenario high-level synthesis algorithm for distributed-register architectures
AU - Igawa, Koki
AU - Shi, Youhua
AU - Yanagisawa, Masao
AU - Togawa, Nozomu
N1 - Funding Information:
This research is supported in part by NEDO.
Publisher Copyright:
© 2015 IEEE.
PY - 2016/2/12
Y1 - 2016/2/12
N2 - In order to tackle a process-variation problem, we can define several scenarios, each of which corresponds to a particular LSI behavior, such as a typical-case scenario and a worst-case scenario. By designing a single LSI chip which realizes multiple scenarios simultaneously, we can have a process-variation-tolerant LSI chip. In this paper, we propose a process-variation-aware low-latency and multi-scenario high-level synthesis algorithm targeting new distributed-register architectures, called HDR architectures. We assume two scenarios, a typical-case scenario and a worst-case scenario, and realize them onto a single chip. We first schedule/bind each of the scenarios independently. After that, we commonize the scheduling/binding results for the typical-case and worst-case scenarios and thus generate a commonized area-minimized floorplan result. Experimental results show that our algorithm reduces the latency of the typical-case scenario by up to 50% without increasing the latency of the worst-case scenario, compared with several existing methods.
AB - In order to tackle a process-variation problem, we can define several scenarios, each of which corresponds to a particular LSI behavior, such as a typical-case scenario and a worst-case scenario. By designing a single LSI chip which realizes multiple scenarios simultaneously, we can have a process-variation-tolerant LSI chip. In this paper, we propose a process-variation-aware low-latency and multi-scenario high-level synthesis algorithm targeting new distributed-register architectures, called HDR architectures. We assume two scenarios, a typical-case scenario and a worst-case scenario, and realize them onto a single chip. We first schedule/bind each of the scenarios independently. After that, we commonize the scheduling/binding results for the typical-case and worst-case scenarios and thus generate a commonized area-minimized floorplan result. Experimental results show that our algorithm reduces the latency of the typical-case scenario by up to 50% without increasing the latency of the worst-case scenario, compared with several existing methods.
KW - hdr architecture
KW - high-level synthesis
KW - interconnection delay
KW - process variation
KW - scenario
UR - http://www.scopus.com/inward/record.url?scp=84962374967&partnerID=8YFLogxK
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U2 - 10.1109/SOCC.2015.7406898
DO - 10.1109/SOCC.2015.7406898
M3 - Conference contribution
AN - SCOPUS:84962374967
T3 - International System on Chip Conference
SP - 7
EP - 12
BT - Proceedings - 28th IEEE International System on Chip Conference, SOCC 2015
A2 - Buchner, Thomas
A2 - Zhao, Danella
A2 - Bhatia, Karan
A2 - Sridhar, Ramalingam
PB - IEEE Computer Society
T2 - 28th IEEE International System on Chip Conference, SOCC 2015
Y2 - 8 September 2015 through 11 September 2015
ER -