Multigate Transistors for High Frequency
â K. Sivasankaran, Partha Sharathi Mallick
đ Library
đ
2023
đ Springer
đ English
⌠LIBER âŚ
đ
Multigate Transistors for High Frequency Applications
â Scribed by K. Sivasankaran, Partha Sharathi Mallick
- Publisher
- Springer
- Year
- 2023
- Tongue
- English
- Leaves
- 98
- Series
- Springer Tracts in Electrical and Electronics Engineering
- Category
- Library
⏠Acquire This Volume
No coin nor oath required. For personal study only.
⌠Synopsis
This book discusses the evolution of multigate transistors, the design challenges of transistors for high-frequency applications, and the design and modeling of multigate transistors for high-frequency applications. The contents particularly focus on the cut-off frequency and maximum oscillation frequency of different multigate structures. RF stability modeling for multigate transistors is presented, which can help to understand the relation between the small-signal parameter and the physical parameter of the device for optimization. This is a useful reference to those in academia and industry.
⌠Table of Contents
Preface
Contents
About the Authors
1 Introduction
1.1 Impact of Scaling
1.2 Heterogeneous Integration of Digital and Non-Digital Functionalities
1.3 Evolution of Multigate Transistors
1.4 Roadmap of Semiconductor Devices for High-Frequency Applications
References
2 Radio Frequency Transistor Stability and Design Challenges
2.1 Introduction
2.2 RF TransistorsâFigures of Merit (FoM)
2.2.1 Stability
2.2.2 Cut-Off Frequency (ft)
2.2.3 Maximum Oscillation Frequency (fmax)
2.3 RF Transistor Stability
2.3.1 Transistor Stability
2.3.2 Stability Circles
2.3.3 Tests for Unconditional Stability
2.4 Design Challenges of Transistors for RF Applications
2.4.1 Issues Associated with RF FoM
2.4.2 RF Modeling and Characterization
2.4.3 Critical RF Building Blocks
2.5 Summary
References
3 Radio Frequency Stability Performance of DG MOSFET
3.1 Introduction
3.2 Numerical Modeling of DG MOSFET
3.3 Stability Factor Modeling
3.4 Bias Optimization of DG MOSFET: RF Stability Perspective
3.4.1 Optimization of Gate to Source Voltage
3.4.2 Optimization of Drain to Source Voltage
3.5 Geometry Optimization of DG MOSFET: RF Stability Perspective
3.5.1 Optimization of Gate Spacer Length
3.5.2 Optimization of Silicon Body Thickness
3.6 Optimized Double-Gate MOSFET for Improved RF Stability Performance
3.7 Summary
References
4 Radio Frequency Stability Performance of Double-Gate Tunnel FET
4.1 Introduction
4.2 Numerical Modeling of DG Tunnel FET
4.3 Small-Signal Modelling of DG Tunnel FET
4.4 RF Stability Performance of Double-Gate Tunnel FET
4.5 Impact of Process Variation on RF Stability Performance of DG Tunnel FET
4.5.1 Impact of Body Thickness Variation
4.5.2 Impact of Oxide Thickness Variation
4.5.3 Impact of Gate Contact Alignment
4.5.4 Impact of Doping Concentration
4.6 Summary
References
5 Radio Frequency Stability Performance of FinFET
5.1 Introduction
5.2 Numerical Modeling of FinFET
5.3 Stability Modeling
5.4 Bias Optimization of FinFET: RF Stability Perspective
5.4.1 Optimization of Gate to Source Voltage
5.4.2 Optimization of Drain to Source Voltage
5.5 Geometry Optimization of FinFET: RF Stability Perspective
5.5.1 Optimization of Gate Spacer Length
5.5.2 Optimization of Fin Height and Fin Thickness
5.6 Optimization of Gate Work FunctionâRF Stability Perspective
5.7 Optimized FinFET Structure for Improved RF Stability Performance
5.8 Summary
References
6 Radio Frequency Stability Performance of Silicon Nanowire Transistor
6.1 Introduction
6.2 Numerical Modeling of Silicon Nanowire Transistor
6.3 Stability Modeling
6.4 Bias Optimization of SNWTâRF Stability Perspective
6.4.1 Optimization of Gate to Source Voltage
6.4.2 Optimization of Drain to Source Voltage
6.5 Geometry Optimization of SNWTâRF Stability Perspective
6.5.1 Optimization of Gate Contact Alignment
6.5.2 Optimization of Silicon Radius
6.6 Optimized SNWT for Improved RF Stability Performance
6.7 Summary
References
7 Radio Frequency Stability Performance of SELBOX Inverted-T Junctionless FET
7.1 Introduction
7.2 Virtual Fabrication Process Flow
7.3 Numerical Modeling of SELBOX ITJLFET
7.4 Stability Modeling
7.5 Impact of the Geometrical Parameter Variation on the RF Stability Performance
7.5.1 Impact of Supply Voltages
7.5.2 Impact of Gate Length (LG)
7.5.3 Impact of SELBOX Length (LSELBOX)
7.5.4 Impact of Source Underlap Length (LUS)
7.5.5 Impact of Fin Height (Hfin)
7.5.6 Impact of Fin Width (Wfin)
7.5.7 Impact of Gate Work Function (Ďms)
7.6 Summary
References
đ SIMILAR VOLUMES
Multigate Transistors for High Frequency
â K. Sivasankaran; Partha Sharathi Mallick
đ Library
đ
2023
đ Springer Nature
đ English
This book discusses the evolution of multigate transistors, the design challenges of transistors for high-frequency applications, and the design and modeling of multigate transistors for high-frequency applications. The contents particularly focus on the cut-off frequency and maximum oscillation fre
High-Frequency Bipolar Transistors: Phys
â Professor Dr. Michael Reisch (auth.)
đ Library
đ
2003
đ Springer-Verlag Berlin Heidelberg
đ English
<p><P>The book gives a detailed presentation of high-frequency bipolar transistors in silicon or silicon-germanium technology with particular emphasis given to todays advanced compact models and their physical foundations. The first part introduces the fundamentals of bipolar transistors on a gradua
Semiconductor devices; discrete devices;
Radio Frequency Transistors. Principles
â Helge Granberg and Norman Dye (Auth.)
đ Library
đ
1993
đ English
Radio Frequency Transistors: Principles
â Norman Dye, Helge Granberg
đ Library
đ
2001
đ Newnes
đ English
Radio Frequency Transistors: Principles and Practical Applications is a complete tool kit for successful RF circuit design. As cellular and satellite communications fields continue to expand, the need for RF circuit design grows. Radio Frequency Transistors contains a wealth of practical design info