An asynchronous ternary logic signaling system

Tomaz Felicijian; Steve B. Furber

doi:10.1109/TVLSI.2003.819571

An asynchronous ternary logic signaling system

Tomaz Felicijian, Steve B. Furber

Advanced Processor Technology

Research output: Contribution to journal › Article › peer-review

Abstract

This paper presents a new approach to an on-chip asynchronous transmission system suitable for next generation asynchronous on-chip networks. It implements multivalued logic to reduce the number of wires and a low-voltage swing for lower dynamic power dissipation. Furthermore, the transmission system described here enjoys fully static design and has zero static power consumption. Two versions of the transmitter circuit and the receiver are described. The proposed signaling scheme is compared to a classical dual-rail signaling system with regard to speed, power consumption, and reliability. The simulation results show that the asynchronous ternary logic signaling (ATLS) system delivers over 70% higher bandwidth per wire and consumes over 50% less power than the dual-rail signaling system on 10-mm-long on-chip interconnection.

Original language	English
Pages (from-to)	1114-1119
Number of pages	5
Journal	IEEE Transactions on Very Large Scale Integration (VLSI) Systems
Volume	11
Issue number	6
DOIs	https://doi.org/10.1109/TVLSI.2003.819571
Publication status	Published - Dec 2003

Keywords

Communication system signaling
Digital CMOS
Low voltage
Low-power design
Multivalued logic

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10.1109/TVLSI.2003.819571

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title = "An asynchronous ternary logic signaling system",

abstract = "This paper presents a new approach to an on-chip asynchronous transmission system suitable for next generation asynchronous on-chip networks. It implements multivalued logic to reduce the number of wires and a low-voltage swing for lower dynamic power dissipation. Furthermore, the transmission system described here enjoys fully static design and has zero static power consumption. Two versions of the transmitter circuit and the receiver are described. The proposed signaling scheme is compared to a classical dual-rail signaling system with regard to speed, power consumption, and reliability. The simulation results show that the asynchronous ternary logic signaling (ATLS) system delivers over 70% higher bandwidth per wire and consumes over 50% less power than the dual-rail signaling system on 10-mm-long on-chip interconnection.",

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AB - This paper presents a new approach to an on-chip asynchronous transmission system suitable for next generation asynchronous on-chip networks. It implements multivalued logic to reduce the number of wires and a low-voltage swing for lower dynamic power dissipation. Furthermore, the transmission system described here enjoys fully static design and has zero static power consumption. Two versions of the transmitter circuit and the receiver are described. The proposed signaling scheme is compared to a classical dual-rail signaling system with regard to speed, power consumption, and reliability. The simulation results show that the asynchronous ternary logic signaling (ATLS) system delivers over 70% higher bandwidth per wire and consumes over 50% less power than the dual-rail signaling system on 10-mm-long on-chip interconnection.

KW - Communication system signaling

KW - Digital CMOS

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KW - Low-power design

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JO - IEEE Transactions on Very Large Scale Integration (VLSI) Systems

JF - IEEE Transactions on Very Large Scale Integration (VLSI) Systems

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An asynchronous ternary logic signaling system

Abstract

Keywords

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