Total-ionizing-dose induced timing window violations in CMOS microcontrollers

Zachary J. Diggins; Nagabhushan Mahadevan; Daniel Herbison; Gabor Karsai; Brian D. Sierawski; Eric Barth; E. Bryn Pitt; Robert A. Reed; Ronald D. Schrimpf; Robert A. Weller; Michael L. Alles; Arthur Witulski

doi:10.1109/TNS.2014.2368125

Total-ionizing-dose induced timing window violations in CMOS microcontrollers

Zachary J. Diggins
, Nagabhushan Mahadevan
, Daniel Herbison
, Gabor Karsai
, Brian D. Sierawski
, Eric Barth
, E. Bryn Pitt
, Robert A. Reed
, Ronald D. Schrimpf
, Robert A. Weller
, Michael L. Alles
, Arthur Witulski

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

5 Scopus citations

Abstract

The total-ionizing-dose robustness of low power microcontrollers is investigated. Experiments reveal that with increasing total ionizing dose (TID), the 'Timing Window Violations,'i.e., inability of the instruction set to execute within the clock-cycle(s) lead to failures in microcontroller operations. Clock frequency and supply voltage of the microcontroller are varied to determine the maximum clock frequency at which the microcontroller can execute software subroutines without failure. Low power microcontrollers from two different manufacturers were tested. The maximum clock frequency decreases with increasing TID for both parts. A model for the degradation based on analysis of circuit level timing models is presented. The microcontroller robustness implications for system designers and ASIC designers are discussed.

Original language	English
Article number	6966811
Pages (from-to)	2979-2984
Number of pages	6
Journal	IEEE Transactions on Nuclear Science
Volume	61
Issue number	6
DOIs	https://doi.org/10.1109/TNS.2014.2368125
State	Published - Dec 1 2014
Externally published	Yes

Keywords

Microcontrollers
Total ionizing dose (TID)
propagation delay
timing window

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10.1109/TNS.2014.2368125

Cite this

Diggins, Z. J., Mahadevan, N., Herbison, D., Karsai, G., Sierawski, B. D., Barth, E., Pitt, E. B., Reed, R. A., Schrimpf, R. D., Weller, R. A., Alles, M. L., & Witulski, A. (2014). Total-ionizing-dose induced timing window violations in CMOS microcontrollers. IEEE Transactions on Nuclear Science, 61(6), 2979-2984. Article 6966811. https://doi.org/10.1109/TNS.2014.2368125

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abstract = "The total-ionizing-dose robustness of low power microcontrollers is investigated. Experiments reveal that with increasing total ionizing dose (TID), the 'Timing Window Violations,'i.e., inability of the instruction set to execute within the clock-cycle(s) lead to failures in microcontroller operations. Clock frequency and supply voltage of the microcontroller are varied to determine the maximum clock frequency at which the microcontroller can execute software subroutines without failure. Low power microcontrollers from two different manufacturers were tested. The maximum clock frequency decreases with increasing TID for both parts. A model for the degradation based on analysis of circuit level timing models is presented. The microcontroller robustness implications for system designers and ASIC designers are discussed.",

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AU - Diggins, Zachary J.

AU - Mahadevan, Nagabhushan

AU - Herbison, Daniel

AU - Karsai, Gabor

AU - Sierawski, Brian D.

AU - Barth, Eric

AU - Pitt, E. Bryn

AU - Reed, Robert A.

AU - Schrimpf, Ronald D.

AU - Weller, Robert A.

AU - Alles, Michael L.

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N2 - The total-ionizing-dose robustness of low power microcontrollers is investigated. Experiments reveal that with increasing total ionizing dose (TID), the 'Timing Window Violations,'i.e., inability of the instruction set to execute within the clock-cycle(s) lead to failures in microcontroller operations. Clock frequency and supply voltage of the microcontroller are varied to determine the maximum clock frequency at which the microcontroller can execute software subroutines without failure. Low power microcontrollers from two different manufacturers were tested. The maximum clock frequency decreases with increasing TID for both parts. A model for the degradation based on analysis of circuit level timing models is presented. The microcontroller robustness implications for system designers and ASIC designers are discussed.

AB - The total-ionizing-dose robustness of low power microcontrollers is investigated. Experiments reveal that with increasing total ionizing dose (TID), the 'Timing Window Violations,'i.e., inability of the instruction set to execute within the clock-cycle(s) lead to failures in microcontroller operations. Clock frequency and supply voltage of the microcontroller are varied to determine the maximum clock frequency at which the microcontroller can execute software subroutines without failure. Low power microcontrollers from two different manufacturers were tested. The maximum clock frequency decreases with increasing TID for both parts. A model for the degradation based on analysis of circuit level timing models is presented. The microcontroller robustness implications for system designers and ASIC designers are discussed.

KW - Microcontrollers

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KW - propagation delay

KW - timing window

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Total-ionizing-dose induced timing window violations in CMOS microcontrollers

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Keywords

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