An Efficient Analog Compact NBTI Model for Stress and Recovery Based on Activation Energy Maps

An Efficient Analog Compact NBTI Model for Stress and Recovery Based on Activation Energy Maps

Despite considerable research efforts, efficient and accurate analog bias temperature instability (BTI) stress and recovery models are still urgently needed to evaluate aging in circuit simulators. We present a model for arbitrary analog BTI stress based on distributed first-order reactions to model...

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Veröffentlicht in:IEEE transactions on electron devices 2019-11, Vol.66 (11), p.4623-4630
Hauptverfasser: Puschkarsky, K., Reisinger, H., Rott, G. A., Schlunder, Christian, Gustin, W., Grasser, T.
Format: Artikel
Sprache:eng
Schlagworte:
Activation energy
Activation energy maps
Analog circuits
Bias
bias temperature instability (BTI)
capture and emission time (CET)
Computer simulation
Energy recovery
Integrated circuit modeling
modeling
Negative bias temperature instability
recovery
Simulators
Stability analysis
Stress
Stress concentration
Stress measurement
Temperature
Temperature dependence
Temperature measurement
Thermal variables control
Threshold voltage
Voltage measurement
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Beschreibung
Zusammenfassung:Despite considerable research efforts, efficient and accurate analog bias temperature instability (BTI) stress and recovery models are still urgently needed to evaluate aging in circuit simulators. We present a model for arbitrary analog BTI stress based on distributed first-order reactions to model the time dynamics responsible for the threshold voltage shift of BTI. We use a single activation energy map, which includes the voltage and temperature dependence of stress and recovery. To validate the model, we present the calculation of the threshold voltage shift after arbitrary gate bias stress with high accuracy, industry-compatible measurement effort, and stress time-independent computational effort and introduce a model suitable for circuit simulations.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2019.2941889