A token scan architecture for low power testing

Author

Huang, Tsung-Chu ; Lee, Kuen- Jong

Author_Institution

Dept. of Electr. Eng., Nat. Cheng Kung Univ., Tainan, Taiwan

fYear

2001

fDate

2001

Firstpage

660

Lastpage

669

Abstract

Presents a novel scan architecture for low-power testing, which employs the techniques of multiphase clocking, token ring, and clock-gating. When the multiphase clocking technique is directly employed to a scan chain, inter-phase skews and large routing area will be the problems. We develop a token scan cell design to address these problems. To reduce the power dissipation due to the clock and scan-in data trees, we propose a novel clock-gating technique that takes advantage of the regularity and periodicity of the token scan chain. Combining the three techniques, the token scan architecture can efficiently reduce the data transitions in the scan circuits as well as the switching activity in both the clock and the scan-in data trees. From experiments, more than 95% of power reduction can be achieved for most circuits with long scan chains

Keywords

application specific integrated circuits; boundary scan testing; clocks; flip-flops; integrated circuit testing; logic testing; low-power electronics; network routing; SOC; clock-gating; data transitions; flipflops; inter-phase skews; low power testing; multiphase clocking; power dissipation; routing area; scan chain; scan-in data trees; switching activity; token ring; token scan architecture; Automatic testing; Built-in self-test; Circuit testing; Clocks; Electronic mail; Power dissipation; Routing; Switching circuits; Token networks; Wire;

fLanguage

English

Publisher

ieee

Conference_Titel

Test Conference, 2001. Proceedings. International

Conference_Location

Baltimore, MD

ISSN

1089-3539

Print_ISBN

0-7803-7169-0

Type

conf

DOI

10.1109/TEST.2001.966686

Filename

966686