Impact of Self-Heating in Wire Interconnection on Timing

Impact of Self-Heating in Wire Interconnection on Timing

This paper evaluates impact of self-heating in wire interconnection on signal propagation delay in an upcoming 32nm process technology, using practical physical parameters. This paper examines a 64-bit data transmission model as one of the most heating cases. Experimental results show that the maxim...

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Veröffentlicht in:IEICE Transactions on Electronics 2010/03/01, Vol.E93.C(3), pp.388-392
Hauptverfasser: KANAMOTO, Toshiki, OKUMURA, Takaaki, FURUKAWA, Katsuhiro, TAKAFUJI, Hiroshi, KUROKAWA, Atsushi, HACHIYA, Koutaro, SAKATA, Tsuyoshi, TANAKA, Masakazu, NAKASHIMA, Hidenari, MASUDA, Hiroo, SATO, Takashi, HASHIMOTO, Masanori
Format: Artikel
Sprache:eng
Schlagworte:
Delay
delay variation
Drivers
interconnect
Interconnection
Nanocomposites
Nanomaterials
Nanostructure
parasitic resistance
self-heat
SoC
temperature
thermal
Time measurements
Wire
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Zusammenfassung:This paper evaluates impact of self-heating in wire interconnection on signal propagation delay in an upcoming 32nm process technology, using practical physical parameters. This paper examines a 64-bit data transmission model as one of the most heating cases. Experimental results show that the maximum wire temperature increase due to the self-heating appears in the case where the ratio of interconnect delay becomes largest compared to the driver delay. However, even in the most significant case which induces the maximum temperature rise of 11.0°C, the corresponding increase in the wire resistance is 1.99% and the resulting delay increase is only 1.15%, as for the assumed 32nm process. A part of the impact reduction of wire self-heating on timing comes from the size-effect of nano-scale wires.
ISSN:0916-8524
1745-1353
1745-1353
DOI:10.1587/transele.E93.C.388