XStat: Statistical X-filling algorithm for peak capture power reduction in scan tests

A. Satya Trinadh; Seetal Potluri; Shankar Balachandran; Ch Sobhan Babu; V. Kamakoti

doi:10.1166/jolpe.2014.1302

XStat: Statistical X-filling algorithm for peak capture power reduction in scan tests

A. Satya Trinadh
, Seetal Potluri
, Shankar Balachandran
, Ch Sobhan Babu
, V. Kamakoti

Electrical & Computer Engineering

University at Albany

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

9 Scopus citations

Abstract

Excessive power dissipation can cause high voltage droop on the power grid, leading to timing failures. Since test power dissipation is typically higher than functional power, test peak power minimization becomes very important in order to avoid test induced timing failures. Test cubes for large designs are usually dominated by don't care bits, making X-leveraging algorithms promising for test power reduction. In this paper, we show that X-bit statistics can be used to reorder test vectors on scan based architectures realized using toggle-masking flip flops. Based on this, the paper also presents an algorithm namely balanced X-filling that when applied to ITC'99 circuits, reduced the peak capture power by 7.4% on the average and 40.3% in the best case. Additionally XStat improved the running time for Test Vector Ordering and X-filling phases compared to the best known techniques.

Original language	English
Pages (from-to)	107-115
Number of pages	9
Journal	Journal of Low Power Electronics
Volume	10
Issue number	1
DOIs	https://doi.org/10.1166/jolpe.2014.1302
State	Published - Mar 1 2014

Keywords

Design for Testability (DFT)
Peak capture-power
Scan-based testing
Test Vector Ordering (TVO)
X-Bit statistics

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10.1166/jolpe.2014.1302

Cite this

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title = "XStat: Statistical X-filling algorithm for peak capture power reduction in scan tests",

abstract = "Excessive power dissipation can cause high voltage droop on the power grid, leading to timing failures. Since test power dissipation is typically higher than functional power, test peak power minimization becomes very important in order to avoid test induced timing failures. Test cubes for large designs are usually dominated by don't care bits, making X-leveraging algorithms promising for test power reduction. In this paper, we show that X-bit statistics can be used to reorder test vectors on scan based architectures realized using toggle-masking flip flops. Based on this, the paper also presents an algorithm namely balanced X-filling that when applied to ITC'99 circuits, reduced the peak capture power by 7.4\% on the average and 40.3\% in the best case. Additionally XStat improved the running time for Test Vector Ordering and X-filling phases compared to the best known techniques.",

keywords = "Design for Testability (DFT), Peak capture-power, Scan-based testing, Test Vector Ordering (TVO), X-Bit statistics",

author = "Trinadh, \{A. Satya\} and Seetal Potluri and Shankar Balachandran and Babu, \{Ch Sobhan\} and V. Kamakoti",

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doi = "10.1166/jolpe.2014.1302",

language = "English",

volume = "10",

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T2 - Statistical X-filling algorithm for peak capture power reduction in scan tests

AU - Trinadh, A. Satya

AU - Potluri, Seetal

AU - Balachandran, Shankar

AU - Babu, Ch Sobhan

AU - Kamakoti, V.

PY - 2014/3/1

Y1 - 2014/3/1

N2 - Excessive power dissipation can cause high voltage droop on the power grid, leading to timing failures. Since test power dissipation is typically higher than functional power, test peak power minimization becomes very important in order to avoid test induced timing failures. Test cubes for large designs are usually dominated by don't care bits, making X-leveraging algorithms promising for test power reduction. In this paper, we show that X-bit statistics can be used to reorder test vectors on scan based architectures realized using toggle-masking flip flops. Based on this, the paper also presents an algorithm namely balanced X-filling that when applied to ITC'99 circuits, reduced the peak capture power by 7.4% on the average and 40.3% in the best case. Additionally XStat improved the running time for Test Vector Ordering and X-filling phases compared to the best known techniques.

AB - Excessive power dissipation can cause high voltage droop on the power grid, leading to timing failures. Since test power dissipation is typically higher than functional power, test peak power minimization becomes very important in order to avoid test induced timing failures. Test cubes for large designs are usually dominated by don't care bits, making X-leveraging algorithms promising for test power reduction. In this paper, we show that X-bit statistics can be used to reorder test vectors on scan based architectures realized using toggle-masking flip flops. Based on this, the paper also presents an algorithm namely balanced X-filling that when applied to ITC'99 circuits, reduced the peak capture power by 7.4% on the average and 40.3% in the best case. Additionally XStat improved the running time for Test Vector Ordering and X-filling phases compared to the best known techniques.

KW - Design for Testability (DFT)

KW - Peak capture-power

KW - Scan-based testing

KW - Test Vector Ordering (TVO)

KW - X-Bit statistics

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DO - 10.1166/jolpe.2014.1302

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SP - 107

EP - 115

JO - Journal of Low Power Electronics

JF - Journal of Low Power Electronics

IS - 1

ER -

XStat: Statistical X-filling algorithm for peak capture power reduction in scan tests

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Keywords

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