Zero skew differential clock distribution network

Author

Zarrabi, Houman ; Saaied, Haydar ; Al-Khalili, A.J. ; Savaria, Yvon

Author_Institution

Dept. of ECE, Concordia Univ., Montreal, Que.

fYear

2006

fDate

21-24 May 2006

Lastpage

2080

Abstract

Clock uncertainty is a major concern in current high performance clock network design. A differential clocking scheme provides noise immunity and can address this challenge. In this paper, a differential line equivalent delay model is proposed to obtain zero skew differential clock networks. The method is applied to various benchmarks. On average, 97% skew reduction is obtained compared to the solution derived with the classic Elmore model. To improve performance of zero skew differential clock networks, differential buffers based on dynamic threshold transistors are proposed. Incorporation of proposed buffers to low swing zero skew differential clock network shows 25% delay improvement compared to conventional buffers. Moreover, the incorporation of proposed design methods shows 25% and 6% skew variations reduction in presence of power supply variations and crosstalk noise respectively, compared to low swing single-node clock distribution networks

Keywords

buffer circuits; clocks; integrated circuit design; synchronisation; classic Elmore model; clock uncertainty; crosstalk noise; differential buffers; differential clock distribution network; differential clocking scheme; differential line equivalent delay model; dynamic threshold transistors; noise immunity; power supply variations; zero skew clock distribution network; Clocks; Crosstalk; Delay lines; Design methodology; Power supplies; Power system modeling; Power system reliability; Routing; Transistors; Uncertainty;

fLanguage

English

Publisher

ieee

Conference_Titel

Circuits and Systems, 2006. ISCAS 2006. Proceedings. 2006 IEEE International Symposium on

Conference_Location

Island of Kos

Print_ISBN

0-7803-9389-9

Type

conf

DOI

10.1109/ISCAS.2006.1693025

Filename

1693025