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A Deep Learning Space Mapping Based Enhancement of Compact Models for Accurate Prediction of Trapping in GaN HEMTs from DC to mm-Wave Frequency

Journal article

Mohd. Yusuf, Smriti Singh, B. Sarkar, A. Dasgupta, Sourajeet Roy
Intelligent Memory Systems, 2023
Semantic Scholar DOI
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APA   Click to copy
Yusuf, M., Singh, S., Sarkar, B., Dasgupta, A., & Roy, S. (2023). A Deep Learning Space Mapping Based Enhancement of Compact Models for Accurate Prediction of Trapping in GaN HEMTs from DC to mm-Wave Frequency. Intelligent Memory Systems.

Chicago/Turabian   Click to copy
Yusuf, Mohd., Smriti Singh, B. Sarkar, A. Dasgupta, and Sourajeet Roy. “A Deep Learning Space Mapping Based Enhancement of Compact Models for Accurate Prediction of Trapping in GaN HEMTs from DC to Mm-Wave Frequency.” Intelligent Memory Systems (2023).

MLA   Click to copy
Yusuf, Mohd., et al. “A Deep Learning Space Mapping Based Enhancement of Compact Models for Accurate Prediction of Trapping in GaN HEMTs from DC to Mm-Wave Frequency.” Intelligent Memory Systems, 2023.

BibTeX   Click to copy 

@article{mohd2023a,
  title = {A Deep Learning Space Mapping Based Enhancement of Compact Models for Accurate Prediction of Trapping in GaN HEMTs from DC to mm-Wave Frequency},
  year = {2023},
  journal = {Intelligent Memory Systems},
  author = {Yusuf, Mohd. and Singh, Smriti and Sarkar, B. and Dasgupta, A. and Roy, Sourajeet}
}

Abstract

In this work, a deep learning space mapping technique has been developed to enable standard compact models to account for sporadic trapping effects in AlGaN/GaN high electron mobility transistors (HEMTs). In the proposed technique, an artificial neural network (ANN) is used to map the input feature space spanning the geometrical, material, bias, and trap-related parameters of a rigorous physics-based model (fine model) of the HEMT to the input feature space of a compact model (coarse model). Consequently, the space mapping augmented compact model is able to retain the high computational efficiency of the standard compact model while gaining the capacity to account for the effects of interface and bulk traps in the HEMT responses from DC to millimeter wave frequencies. In this work, the compact model considered is the industry standard advanced SPICE model for GaN HEMTs (ASM-HEMT).