Maximilian Reuter, Dakyung Lee, David Riehl, K. Hofmann
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Quick Compact Model Development Through Slow Transient Simulation: An Alternative Approach to Table Models for Emerging Nanodevices
A transient simulation which proceeds slowly, compared to all dynamic processes, can be designed to generate a multi-dimensional quasistationary dataset. In order to characterize an electrical device/circuit, in this work we explore a simulation design based on frequency-nested cosine functions where before an array of quasistationary voltage sweeps was necessary. We present an example of 3 terminal voltages, each in the range of (–1V, 1V), to demonstrate how to plan granularity of a data set. Then we apply this example setup to a novel semiconductor device. Lastly, we present a method to verify if data from the respective transient simulation can indeed be interpreted as quasistationary data. The proposed methods are described in a generic mathematical way to allow transfer to other dynamic systems incorporating fluidic, mechanic or thermic processes.
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