Differential current-mode sensing for efficient on-chip global signaling

Author

Tzartzanis, Nestoras ; Walker, William W.

Author_Institution

Fujitsu Labs. of America, Sunnyvale, CA, USA

Volume

40

Issue

11

fYear

2005

Firstpage

2141

Lastpage

2147

Abstract

We present a new on-chip signaling method that relies on differential current-mode sensing to improve both delay and energy dissipation compared to conventional inverter repeaters. The proposed method can be used for point-to-point as well as N-to-1 connections. Several experimental point-to-point transceivers with different interconnect length and an inverter repeater-based interconnect were implemented in 0.11 μm, 1.2V CMOS. Hardware measurements indicate that the proposed current-sensed transceiver produces 65% of the delay/mm of a repeater-based transceiver while dissipating 51% of its average switching energy/mm for a 10 mm interconnect. An additional 10% energy reduction relative to the inverter-repeater transceiver is possible if shorter current pulses are transmitted through the interconnect.

Keywords

CMOS integrated circuits; current-mode circuits; integrated circuit design; integrated circuit interconnections; transceivers; 0.11 micron; 1.2 V; 10 mm; CMOS integrated circuits; conventional inverter repeaters; current pulses; current-mode signaling; current-mode transceiver; energy dissipation; inverter-repeater transceiver; on-chip global interconnects; on-chip signaling method; Capacitance; Clocks; Delay; Energy dissipation; Energy measurement; Integrated circuit interconnections; Inverters; Repeaters; Transceivers; Transmitters; Current-mode signaling; current-mode transceiver; on-chip global interconnects;

fLanguage

English

Journal_Title

Solid-State Circuits, IEEE Journal of

Publisher

ieee

ISSN

0018-9200

Type

jour

DOI

10.1109/JSSC.2005.857351

Filename

1522553