Aug 1, 2017

[paper] Circuit-level simulation methodology for Random Telegraph Noise by using Verilog-AMS


T. Komawaki, M. Yabuuchi, R. Kishida, J. Furuta, T. Matsumoto and K. Kobayashi
Circuit-level simulation methodology for Random Telegraph Noise by using Verilog-AMS
2017 IEEE ICICDT, Austin, TX, USA, 2017, pp. 1-4.
doi: 10.1109/ICICDT.2017.7993526

Abstract: As device sizes are downscaled to nanometer, Random Telegraph Noise (RTN) becomes dominant. It is indespensable to accurately estimate the effect of RTN. We propose the RTN simulation method for analog circuits. It is based on the charge trapping model. We replicate the RTN-induced threshold voltage fluctuation to attach a variable DC voltage source to the gate of MOSFET by using Verilog-AMS. We confirm that drain current of MOSFETs temporally fluctuates. The fluctuations of RTN are different for each MOSFET. Our proposed method can be applied to estimate the temporal impact of RTN including multiple transistors. We can successfully replicate RTN-induced frequency fluctuations in 3-stage ring oscillators as similar as the measurement results [read more...]

Circuit Design and Simulation Project using eSim

Invitation to participate in Circuit Design and Simulation Project using eSim

The FOSSEE (Free and Open Source Software for Education) project based at lIT Bombay has initiated a Circuit Design and Simulation Project using esim (an open source EDA tool for circuit design, simulation, analysis and PCB design).

Interested candidates can take any solved electronic circuit from any source and redesign it using eSim and submit it to us. Candidates will be rewarded with certificates and honorarium after a review process. These circuits will also be published on our website under an appropriate open source license. 

For more details, please visit: http://esim.fossee.in/circuit-simulation-project









Jul 26, 2017

Analysis of Short-Channel Effects in Junctionless DG MOSFETs #papers https://t.co/P2sqAueamw


from Twitter https://twitter.com/wladek60

July 26, 2017 at 11:39AM
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[paper] A Compact Model for the Statistics of the Low-Frequency Noise of MOSFETs With Laterally Uniform Doping

M. Banaszeski da Silva, H. P. Tuinhout, A. Zegers-van Duijnhoven, G. I. Wirth and A. J. Scholten
"A Compact Model for the Statistics of the Low-Frequency Noise of MOSFETs With Laterally Uniform Doping" 
in IEEE TED, vol. 64, no. 8, pp. 3331-3336, Aug. 2017.
doi: 10.1109/TED.2017.2713301

Abstract: In this paper, we develop a compact physics-based statistical model for random telegraph noise-related low-frequency noise in bulk MOSFETS with laterally uniform doping. The proposed model is suited for modern compact device models, such as PSP, BSIM, and EKV. With our proposed model, one can calculate the expected value and the variability of the noise as a function of bias and device parameters. We validate the model through numerous experimental results from different CMOS nodes, down to 40 nm [read more...]

Jul 25, 2017

[paper] Compact On-Wafer Test Structures for Device RF Characterization

B. Kazemi Esfeh, K. Ben Ali and J. P. Raskin IEEE Fellow
Compact On-Wafer Test Structures for Device RF Characterization
in IEEE TED, vol. 64, no. 8, pp. 3101-3107, Aug. 2017
doi: 10.1109/TED.2017.2717196

Abstract: The main objective of this paper is to validate the radio frequency (RF) characterization procedure based on compact test structures compatible with 50um pitch RF probes. It is shown that by using these new test structures, the layout geometry and hence the on-chip space consumption for complete sets of passive and active devices, e.g., coplanar waveguide transmission lines and RF MOSFETs, is divided by a factor of two. The validity domain of these new compact test structures is demonstrated by comparing their measurement results with classical test structures compatible with 100–150um pitch RF probes. 50um -pitch de-embedding structures have been implemented on 0.18um RF silicon-on-insulator (SOI) technology. Cutoff frequencies and parasitic elements of the RF SOI transistors are extracted and the RF performance of trap-rich SOI substrates is analyzed under small- and large-signal conditions [read more...]