[book] MEMS Fundamentals

MEMS Fundamentals

with ANSYS simulation of basic sensors and actuators

Michał Szermer, Andrzej Napieralski (Eds.)

ISBN eBook: 978-83-66287-64-8, 9788366287648

Wydawnictwo Politechniki Łódzkiej

Intro: The purpose of this book is to help universities and individuals extend their traditional microelectronics education into the MEMS area. It is organized in a set of tutorials primarily aimed at electronic engineering students and practicing engineers. Based on carefully selected examples of sensors and actuators, it introduces the reader to device operating principles, modeling approaches, simulation tools and design methodologies.

Book Contents

Preface
Chapter 1. INTRODUCTION
1.1. Program description
1.2. References
Chapter 2. SILICON MEMBRANE
2.1. Introduction
2.2. Modeling
2.2.1. Getting started
2.2.2. Setting system of units
2.2.3. Selecting finite element types
2.2.4. Setting material properties
2.2.5. Defining geometry
2.2.6. Meshing
2.2.7. Selecting analysis type
2.2.8. Applying boundary conditions
2.2.9. Running analysis
2.2.10. Viewing simulation results
2.3. Tasks for students
2.4. References
Chapter 3. THERMAL ACTUATOR
3.1. Introduction
3.2. Modeling
3.2.1. Getting started
3.2.2. Defining geometry
3.2.3. Setting material properties
3.2.4. Setting finite element types
3.2.5. Meshing
3.2.6. Selecting analysis type
3.2.7. Applying boundary conditions
3.2.8. Running analysis
3.2.9. Viewing simulation results
3.3. Automation of MEMS thermal actuator design
3.3.1. Simulation of thermal actuator with varying heater temperature
3.3.2. Viewing and saving simulation results using POST1 postprocessor
3.3.3. Plotting relationships
3.3.4. Tasks for students
3.4. References
Chapter 4. ELECTROTHERMAL ACTUATOR
4.1. Introduction
4.2. Modeling
4.2.1. Getting started
4.2.2. Defining geometry
4.2.3. Setting finite element types
4.2.4. Setting material properties
4.2.5. Meshing
4.2.6. Applying boundary conditions
4.2.6.1. Clamp
4.2.6.2. Temperature
4.2.6.3. Voltage
4.2.7. Selecting analysis type
4.2.8. Running analysis
4.2.9. Viewing simulation results
4.2.9.1. Displacement
4.2.9.2. Voltage
4.2.9.3. Temperature
4.3. Tasks for students
4.4. References
Chapter 5. ACCELEROMETER
5.1. Introduction
5.2. Modeling
5.2.1. Getting started
5.2.2. Defining geometry
5.2.3. Setting finite element types
5.2.4. Setting material properties
5.2.5. Meshing
5.2.6. Applying boundary conditions
5.2.7. Selecting analysis type
5.2.8. Running analysis
5.2.9. Viewing simulation results
5.3. Tasks for students
5.4. References
Chapter 6. SILICON MEMBRANE IN WORKBENCH
6.1. Membranes
6.2. Membrane modeling
6.3. Design and modeling of the membrane
6.3.1. Introduction to ANSYS
6.3.2. Getting started
6.3.3. Defining geometry
6.3.4. Setting up the simulation
6.3.5. Results processing
6.4. Exercises for Students
6.4.1. Laboratory tasks
6.4.2. Individual tasks
6.5. References
Chapter 7. MICROBOLOMETER IN WORKBENCH
7.1. Microbolometer principle
7.2. Microbolometer design with ANSYS Workbench
7.2.1. Getting started
7.2.2. Defining geometry
7.2.3. Adding materials’ data to the project
7.2.4. Electrical simulation
7.2.5. Thermal simulation
7.2.6. Exercises for students
7.2.7. Transient thermal simulation
7.2.8. Exercises for students
7.3. References

[GUEST EDITORIAL] Women in Circuits

GUEST EDITORIAL

Zeynep Toprak-Deniz

Women in Circuits 

IEEE SOLID-STATE CIRCUITS MAGAZINE FALL 2020

DOI 10.1109/MSSC.2020.3021864 (18 November 2020)

The “Rising to the Top in Industry” career panel touched upon topics including mentoring, setting career goals, filing patents, and management versus technical tracks.

At the 2020 International Solid-State Circuits Conference (ISSCC), the Women in Circuits (WiC) Committee hosted the first-ever Rising Stars workshop for graduate and undergraduate students as well as young professionals who have graduated within the last two years and are interested in learning how to excel in academic and industry careers in computer science and electrical engineering. Twenty individuals were selected to attend a special dinner featuring a keynote speech by Prof. Anantha P. Chandrakasan - already a risen star - and a mentoring session with committee members. The event also included two panels. The “Rising to the Top in Industry” career panel touched upon topics including mentoring, setting career goals, filing patents, and management versus technical tracks. The “Navigating the Assistant Professorship” panel addressed topics related to applying for a faculty position, tenure review, and managing day-to-day life in academia. The panels were open to all ISSCC 2020 attendees and the public and attracted more than 300 participants. This Fall 2020 issue of IEEE SolidState Circuits Magazine on WiC follows the tradition of previous issues since 2017, enabling more exposure to female leaders through exposition of their work in circuits on a variety of important topics. The following IEEE Solid-State Circuits Society members were asked to contribute tutorials for this issue:

• Jane Gu, associate professor at the University of California, Davis, and member of the Technical Program Committee (TPC) for the IEEE Radio Frequency Integrated Circuits Symposium, Custom Integrated Circuits Conference (CICC), and ISSCC, is an associate editor of IEEE Microwave and Wireless Components Letters and VLSI Journal of Integration and guest editor of IEEE Journal of Solid-State Circuits (JSSC).
• Ulkuhan Guler, assistant professor at Worcester Polytechnic Institute, is a senior member of JSSC and serves on the CICC TPC.
• Alicia Klinefelter, senior research scientist in the ASIC and VLSI research group at NVIDIA, has served on the ISSCC TPC since 2018.
• Yan Li, vice president for memory design at Western Digital, leading the design of advanced 3D NAND as well as other nonvolatile memories and new innovation initiatives, serves on the ISSCC Machine Learning TPC.
• Rabia Yazicigil, assistant professor in the Department of Electrical and Computer Engineering at Boston University and visiting scholar at the Massachusetts Institute of Technology, was vice-chair of the 2020 Rising Stars workshop.
• Maneesha Yellepeddi, manager of the Programmable Solutions Group at Intel, is an alumnus of the 2020 Rising Stars workshop.

ISSCC 2021 will continue this tradition by hosting another Sunday evening workshop bringing together experts in cloud-connected biosensors, advance algorithms, and artificial intelligence to discuss our preparedness for combating the spread of infectious diseases now and in the future. The “ICs in PandemICs” panel will feature recent work on remote patient monitoring and data analysis with related security and privacy concerns. I hope to see you all there!

Fwd: Online Skill Enhancement Program for SCIENCE Students to be held during December 02 - 08, 2020 from 05:00 pm - 06:30 pm daily.

On behalf of the DBT Star College Program and Department of Electronics

We invite all FIRST AND SECOND Year science students of your institution to join 

the Online Skill Enhancement Program 

to be held during 

December 02 - 08, 2020 from 05:00 pm - 06:30 pm daily

Kindly register via Zoom Link No Registration Fees:

https://us02web.zoom.us/webinar/register/WN_gug93-ABQr-IoAGdW_juoQ  

The objective of the program is to make the students first feel comfortable in their new environment, open them up, create bonding and to connect, learn new things about sensors, mechanics, control, programming the microcontroller to see how it works and controls various aspects be they of biology, zoology, chemistry, physics, mathematics or computers. So this workshop will be useful for all science students to help them explore their knowledge in their fields as well as other fields. Today there is a need to take the concepts of various fields together. This is to skill them in the basic concepts of programming the robotic and control aspects of various applications and sensitize them towards exploring their academic interest and activities.

This program will provide an opportunity for all the science stream students to get some experience in the new way and enhance their knowledge towards interdisciplinary learning. All students having a passion to learn and explore a new world of automation and control and start experimenting with robotic applications are most welcome to participate.

Kindly register via Zoom Link: https://us02web.zoom.us/webinar/register/WN_gug93-ABQr-IoAGdW_juoQ

Organizing Committee
Dr. Poonam Kasturi

Convener-DBT Star College Program (Electronics)

Teacher-in-Charge, Department of Electronics

Deen Dayal Upadhyaya College

University of Delhi

Dr. Manoj Saxena | डॉ मनोज  सक्सेना 

Program Coordinator - DBT Star College Program (DDUC)

Associate Professor | सह - आचार्य

Department of Electronics | इलेक्ट्रॉनिक्स विभाग

Deen Dayal Upadhyaya College | दीन दयाल उपाध्याय कॉलेज

University of Delhi | दिल्ली विश्वविद्यालय

Dwarka Sector-3, New Delhi-110078 | द्वारका क्षेत्र -३, नई दिल्ली -११००७८

India | भारत

[paper] Compact Models for Sizing Based on ANN

Husni Habal, Dobroslav Tsonev, Matthias Schweikardt 

Compact Models for Initial MOSFET Sizing Based on Higher-order Artificial Neural Networks

ACM/IEEE Workshop on Machine Learning for CAD (MLCAD ’20)

Nov. 16–20, 2020, Virtual Event, Iceland. ACM, pp. 111-116

DOI: 10.1145/3380446.3430632

¹Infineon Technologies AG Munich, Germany
²LogiqWorks Ltd. Sofia, Bulgaria
³Reutlingen University Reutlingen, Germany

Abstract: Simple MOSFET models intended for hand analysis are inaccurate in deep sub-micrometer process technologies and in the moderate inversion region of device operation. Accurate models, such as BSIM6 model, are too complex for use in hand analysis and are intended for circuit simulators. Artificial neural networks (ANNs) are efficient at capturing both linear and non-linear multivariate relationships. In this work, a straightforward modeling technique is presented using ANNs to replace the BSIM model equations. Existing open-source libraries are used to quickly build models with error rates generally below 3%. When combined with a novel approach, such as the gm/Id systematic design method, the presented models are sufficiently accurate for use in the initial sizing of analog circuit components without simulation.

Figure: ANN Model Architecture.

[paper] Noise Modeling of Gate Leakage Current in Nanoscale MOSFETs

Jonghwan Lee* 

Noise Modeling of Gate Leakage Current in Nanoscale MOSFETs

Journal of the Semiconductor & Display Technology, 

Vol. 19, No. 3. September 2020

*Department of System Semiconductor Engineering, Sangmyung University

Abstract: The physics-based compact gate leakage current noise models in nanoscale MOSFETs are developed in such a way that the models incorporate important physical effects and are suitable for circuit simulators, including QM (quantummechanical) effects. An emphasis on the trap-related parameters of noise models is laid to make the models adaptable to the variations in different process technologies and to make its parameters easily extractable from measured data. With the help of an accurate and generally applicable compact noise models, the compact noise models are successfully implemented into BSIM (Berkeley Short-channel IGFET Model) format. It is shown that the noise models have good agreement with measurements over the frequency, gate-source and drain-source bias ranges.

Fig: Implementation of the gate leakage current and noise models into the BSIM model

Appendix:

Input deck to simulate MOSFET Noise

*

m1 2 1 0 0 mod1 L=10u W=10u

*

vgs 1 0 dc 1.4 ac 1

vds 3 0 dc 0.3

rdd 2 3 1

*

.include model.TI_nmos

.op

.dc vgs 1 5 0.5

.print dc igd(vgs)

*

.ac dec 10 1 100Meq

.noise v(2) vgs dec 10 1 100Meg 1

.plot noise onoisa inoise

*

.end