All-Digital Circuit-Level Dynamic Variation Monitor for Silicon Debug and Adaptive Clock Control

All-Digital Circuit-Level Dynamic Variation Monitor for Silicon Debug and Adaptive Clock Control

A 45 nm microprocessor integrates an all-digital dynamic variation monitor (DVM) to continuously measure the impact of dynamic parameter variations on circuit-level performance to enhance silicon debug and adaptive clock control. The DVM consists of a tunable replica circuit, a time-to-digital conve...

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Bibliographic Details
Published in:IEEE transactions on circuits and systems. I, Regular papers Vol. 58; no. 9; pp. 2017 - 2025
Main Authors: Bowman, K. A., Tokunaga, C., Tschanz, J. W., Raychowdhury, A., Khellah, M. M., Geuskens, B. M., Lu, Shih-Lien L., Aseron, P. A., Karnik, T., De, V. K.
Format: Journal Article
Language:English
Published: New York IEEE 01-09-2011
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Adaptive circuit
adaptive clocking
Adaptive control systems
Circuits
Clocks
Delay
dynamic variation
Dynamics
Frequency measurement
Microprocessors
Monitoring
Monitors
Placement
Silicon
supply voltage droop
Temperature measurement
variation detector
variation monitor
variation sensor
variation tolerance
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Summary:A 45 nm microprocessor integrates an all-digital dynamic variation monitor (DVM) to continuously measure the impact of dynamic parameter variations on circuit-level performance to enhance silicon debug and adaptive clock control. The DVM consists of a tunable replica circuit, a time-to-digital converter, and multiplexers to measure circuit delay or frequency changes with less than a 1% measured resolution error while capturing clock-to-data correlations. In validating the DVM with microprocessor maximum clock frequency (F MAX ) measurements, an on-die noise injector circuit induces a supply voltage (V CC ) droop at a particular cycle in the test program. The F MAX measurement is then repeated for over a thousand iterations while shifting the droop placement to a different cycle per iteration. Silicon measurements demonstrate the DVM capability of tracking the worst case F MAX reduction to within 1% for a wide range of V CC droop profiles. Furthermore, silicon measurements reveal that F MAX is highly sensitive to the placement and magnitude of a high-frequency V CC droop during program execution, thus highlighting the value of the DVM for silicon debug. In addition, the DVM interfaces with an adaptive clock control circuit to dynamically adjust the clock frequency by changing the divide ratio in the phase-locked loop in response to persistent variations, enabling the microprocessor to adapt to the operating environment for maximum efficiency.
Bibliography:ObjectType-Article-2
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content type line 23
ISSN:1549-8328
1558-0806
DOI:10.1109/TCSI.2011.2163893