Paradigm shift - smaller, better, faster: #imec presents #chip scaling roadmap

Paradigm shift - smaller, better, faster: #imec presents #chip scaling roadmap https://t.co/Nlay0RmnbM #semi https://t.co/KbTqTb9VPY

— Wladek Grabinski (@wladek60) Feb 3, 2023

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February 03, 2023 at 10:33AM
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[paper] Tang, X., Shen, H., Zhao, S. et al. #Flexible #brain–#computer #interfaces

[paper] Tang, X., Shen, H., Zhao, S. et al. #Flexible #brain–#computer #interfaces. Nat Electron (2023). https://t.co/7ei1DjEDv4 https://t.co/ku9TzOgvgX #semi https://t.co/061ERANncp

— Wladek Grabinski (@wladek60) Feb 3, 2023

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February 03, 2023 at 08:30AM
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RT @UMichECE: This chip by @SaliganeMehdi is part of the #opensource #semi hardware movement to democratize #IC design, a movement supported by many, including @NIST and @Google Read more: https://t.co/BVufryP3j2 https://t.co/Pkvocdinma

RT @UMichECE: This chip by @SaliganeMehdi is part of the #opensource #semi hardware movement to democratize #IC design, a movement supported by many, including @NIST and @Google Read more: https://t.co/BVufryP3j2 https://t.co/Pkvocdinma

— Wladek Grabinski (@wladek60) Feb 2, 2023

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February 02, 2023 at 11:55AM
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[paper] Zener diode compact modeling and simulation

Mike Brinson

Modelling and simulation of Zener diode noise in the time domain

International Journal of Numerical Modelling Electronic Networks Devices and Fields

January 2023

DOI: 10.1002/jnm.3090

1 Centre for Communications Technology, London Metropolitan University, London, UK.

Abstract: This paper presents a new time domain Zener diode compact model for transient noise simulation. SPICE2 and SPICE3 use piece-wise linear time dependent sources for generating complex waveforms. This approach is not practical when applied to randomly generated noise. Today, through on-going improvements to freely available Circuit simulation tools, SPICE noise generation has moved to a new level. Ngspice, for example, computes white Gaussian noise ‘on-the-fly' as transient Simulation progresses. The proposed model has a simple behavioral structure that supports time domain shot, flicker, and thermal noise. The physical properties of the proposed model are introduced in the second section. This is followed by an evaluation of model performance in the third and fourth sections, including static DC, dynamic Charge, and transient noise characterization. Finally, the fifth section summarizes the conclusions of the research.

FIG: QuCS-S/Ngspice Zener diode behavioural model: subcircuit schematic drawing; intermediate equations and limexp function definition.

DATA AVAILABILITY STATEMENT: Data Sharing not applicable to this article as no datasets were generated or analyzed during the current study.

[paper] DMT-core: A Python Toolkit for Semiconductor Device Engineers

Mario Krattenmacher^1,2, Markus Müller^1,2, Pascal Kuthe^1,2, and Michael Schröter^1,2

DMT-core: A Python Toolkit for Semiconductor Device Engineers

Journal of Open Source Software, 7(75), 4298

DOI: 10.21105/joss.04298

1 CEDIC, TU Dresden, Dresden (D)

2 SemiMod GmbH, Dresden (D)

Abstract: Semiconductor device engineers are faced by a number of non-trivial tasks that can be solved efficiently using software. These tasks include, amongst others, data analysis, visualization and processing, as well as interfacing various circuit and Technology-Computer-Aided-Design (TCAD) simulators. In practice, custom ‘home-made’ scripts of varying quality are employed to solve these tasks. It is often found that fundamental software engineering concepts, such as Test-Driven-Development (Shull et al., 2010), or the use of state-of-the-art version control tools (e.g. Git) and practices (e.g. continuous integration, CI), are not utilized by these scripts. The issues inflicted by this practice include:

• The analysis/visualization/generation of data becomes difficult to reproduce.
• Device engineers work far from their maximum work-efficiency, as they are hindered, instead of empowered, by the software infrastructure.
• Knowledge built-up, possibly over decades, may be lost when developers leave a company or institution.

The Device Modeling Toolkit (DMT) presented here aims to solve these issues. DMT provides a Python library that offers:

• classes and methods relevant to commonly used device engineering tasks
• several abstract base classes for implementing new interfaces to various types of simulators
• concrete implementations of the abstract base classes for open-source simulators such as Ngspice (Vogt, 2022), Xyce (Keiter et al., 2014) or Hdev (Müller et al., 2022).

DMT-based simulations allow data generation, workflow implementation and visualization to be implemented in a single file, enabling more efficient cooperation and more reproducible research (Stodden et al., 2016). Basic principles in software engineering, such as unit testing,v ersion control, and documentation, are adhered to so that others can use and contribute to the software.

FIG: DMT interfacing a circuit simulator and corresponding data flow.

Related Publications: DMT is used internally by CEDIC staff in research and by SemiMod for commercial purposes. It has also been used by cooperating institutions and companies. The project has been used inthe following contexts:

• for circuit simulations (Weimer et al., 2022),
• for TCAD simulations and plotting (Markus Muller et al., 2021),
• for circuit and TCAD simulations (M. Muller et al., 2022),
• for model parameter extraction (Müller & Schröter, 2019) and
• for model parameter extraction and TCAD simulation (Phillips et al., 2022).

In addition, DMT has been cited in (Grabinski, 2019; Kuthe et al., 2020; Müller et al., 2019,

2021).

Related Projects: DMT directly uses the VerilogAE (Kuthe et al., 2020) for accessing all information in Verilog-AMS files. The TCAD simulator Hdev (Müller et al., 2022) uses the class DutHdev as its Python interface.

Acknowledgements: This project would not have been possible without our colleagues Dipl.-Ing. Christoph Weimer and Dr.-Ing. Yves Zimmermann. We particularly acknowledge Wladek Grabinski for his efforts to promote the use of open source software in the semiconductor community.

REF:

Shull, F., Melnik, G., Turhan, B., Layman, L., Diep, M., & Erdogmus, H. (2010). What do we know about test-driven development? IEEE Softw., 27(6), 16–19. https://doi.org/10.1109/MS.2010.152
Vogt, H. (2022). Ngspice, the open source Spice circuit simulator - Intro. http://ngspice. sourceforge.net/
Keiter, E. R., Mei, T., Russo, T. V., Schiek, R. L., Sholander, P. E., Thornquist, H. K., Verley, J. C., & Baur, D. G. (2014). Xyce Parallel Electronic Simulator Reference Guide , Version 6 . 2 (September). Sandia National Laboratories (SNL). https://doi.org/10.2172/1826862
Müller, M., Mothes, S., Claus, M., & Schröter, M. (2022). Hdev: A 1D and 2D Hydrodynamic/Drift-Diffusion solver for SiGe and III-V HBTs. J. Open Source Software
Stodden, V., McNutt, M., Bailey, D. H., Deelman, E., Gil, Y., Hanson, B., Heroux, M. A., Ioannidis, J. P. A., & Taufer, M. (2016). Enhancing reproducibility for computational methods. Science, 354(6317), 1240–1241. https://doi.org/10.1126/science.aah6168 
Grabinski, W. (2019). FOSS TCAD/EDA tools for compact modeling. Arbeitskreis Bipolar.
https://www.iee.et.tu-dresden.de/iee/eb/forsch/AK-Bipo/2019/7-MOS-AK-Association_wgr_BipAK19.pdf