High robustness energy- and area-efficient dynamic-voltage-scaling 4-phase 4-rail asynchronous-logic Network-on-Chip (ANoC)
We propose an 18-bit 5-interface asynchronouslogic Network-on-Chip (ANoC) router based on the quasi-delayinsensitive (QDI) realization approach for high secured cryptography applications. There are four key features of the proposed ANoC router. First, it embodies the novel high-speed low-power...
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Main Authors: | , , , , |
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Other Authors: | |
Format: | Conference or Workshop Item |
Language: | English |
Published: |
2016
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Subjects: | |
Online Access: | https://hdl.handle.net/10356/82869 http://hdl.handle.net/10220/40387 |
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Institution: | Nanyang Technological University |
Language: | English |
Summary: | We propose an 18-bit 5-interface asynchronouslogic
Network-on-Chip (ANoC) router based on the quasi-delayinsensitive
(QDI) realization approach for high secured
cryptography applications. There are four key features of the
proposed ANoC router. First, it embodies the novel high-speed
low-power Sense-Amplifier Half Buffer 4-rail cells. Second, it is
designed based on QDI protocol, and hence is highly robust
against process-voltage-temperature (PVT) variations. Third, it
is functional for full dynamic voltage scaling from nominal
(VDD=1.2V) to sub-threshold (VDD=0.3V) regions, and is
potentially excellent for low power management applications.
Fourth, it embodies a distributed-based XY routing algorithm to
utilize a 4-bit header of flow control unit (flit) for routing up to
4×4 cluster, hence minimizing the routing overhead. We realize
the proposed ANoC router (@65nm CMOS), and benchmark it
against the reported ANoC router embodying the conventional
Weak-Conditioned Half-Buffer (WCHB) QDI realization
approach. Both our proposed and reported designs feature the
high operation robustness, but our design is 41% more energy efficient,
and 21% more area-efficient than the reported
counterpart. The prototype of ANoC router occupies only 0.105
mm2 and can operate down to 0.3V. At VDD=0.3V, it dissipates 44
fJ per bit and operate 105 ns per flit. |
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