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  • 1
    Online Resource
    Online Resource
    Device modeling for analog and RF CMOS circuit design / (2003)
    Hoboken, NJ :Wiley,
    Details
    UID:
    almafu_9959327319002883
    Format: 1 online resource (xiii, 292 pages) : , illustrations
    Edition: Electronic reproduction. [Place of publication not identified] : HathiTrust Digital Library, 2010.
    ISBN: 0471498696 , 9780471498698 , 0470863803 , 9780470863800 , 0470864346 , 9780470864340
    Content: Bridges the gap between device modelling and analog circuit design. Includes dedicated software enabling actual circuit design. Covers the three significant models: BSIM3, Model 9 &, and EKV. Presents practical guidance on device development and circuit implementation. The authors offer a combination of extensive academic and industrial experience.
    Note: Device Modeling for Analog and RF CMOS Circuit Design; Contents; Preface; 1 MOSFET Device Physics and Operation; 1.1 Introduction; 1.2 The MOS Capacitor; 1.2.1 Interface Charge; 1.2.2 Threshold Voltage; 1.2.3 MOS Capacitance; 1.2.4 MOS Charge Control Model; 1.3 Basic MOSFET Operation; 1.4 Basic MOSFET Modeling; 1.4.1 Simple Charge Control Model; 1.4.2 The Meyer Model; 1.4.3 Velocity Saturation Model; 1.4.4 Capacitance Models; 1.4.5 Comparison of Basic MOSFET Models; 1.4.6 Basic Small-signal Model; 1.5 Advanced MOSFET Modeling; 1.5.1 Modeling Approach; 1.5.2 Nonideal Effects. , 1.5.3 Unified MOSFET C-V ModelReferences; 2 MOSFET Fabrication; 2.1 Introduction; 2.2 Typical Planar Digital CMOS Process Flow; 2.3 RF CMOS Technology; References; 3 RF Modeling; 3.1 Introduction; 3.2 Equivalent Circuit Representation of MOS Transistors; 3.3 High-frequency Behavior of MOS Transistors and AC Small-signal Modeling; 3.3.1 Requirements for MOSFET Modeling for RF Applications; 3.3.2 Modeling of the Intrinsic Components; 3.3.3 HF Behavior and Modeling of the Extrinsic Components; 3.3.4 Non-quasi-static Behavior; 3.4 Model Parameter Extraction. , 3.4.1 RF Measurement and De-embedding Techniques3.4.2 Parameter Extraction; 3.5 NQS Model for RF Applications; References; 4 Noise Modeling; 4.1 Noise Sources in a MOSFET; 4.2 Flicker Noise Modeling; 4.2.1 The Physical Mechanisms of Flicker Noise; 4.2.2 Flicker Noise Models; 4.2.3 Future Work in Flicker Noise Modeling; 4.3 Thermal Noise Modeling; 4.3.1 Existing Thermal Noise Models; 4.3.2 HF Noise Parameters; 4.3.3 Analytical Calculation of the Noise Parameters; 4.3.4 Simulation and Discussions; 4.3.5 Induced Gate Noise Issue; References; 5 Proper Modeling for Accurate Distortion Analysis. , 5.1 Introduction5.2 Basic Terminology; 5.3 Nonlinearities in CMOS Devices and Their Modeling; 5.4 Calculation of Distortion in Analog CMOS Circuits; References; 6 The BSIM4 MOSFET Model; 6.1 An Introduction to BSIM4; 6.2 Gate Dielectric Model; 6.3 Enhanced Models for Effective DC and AC Channel Length and Width; 6.4 Threshold Voltage Model; 6.4.1 Enhanced Model for Nonuniform Lateral Doping due to Pocket (Halo) Implant; 6.4.2 Improved Models for Short-channel Effects; 6.4.3 Model for Narrow Width Effects; 6.4.4 Complete Threshold Voltage Model in BSIM4; 6.5 Channel Charge Model. , 6.6 Mobility Model6.7 Source/Drain Resistance Model; 6.8 I-V Model; 6.8.1 I-V Model When rdsMod = 0 (R(DS)(V) 0); 6.8.2 I-V Model When rdsMod = 1 (R(DS)(V) = 0); 6.9 Gate Tunneling Current Model; 6.9.1 Gate-to-substrate Tunneling Current I(GB); 6.9.2 Gate-to-channel and Gate-to-S/D Currents; 6.10 Substrate Current Models; 6.10.1 Model for Substrate Current due to Impact Ionization of Channel Current; 6.10.2 Models for Gate-induced Drain Leakage (GIDL) and Gate-induced Source Leakage (GISL) Currents; 6.11 Capacitance Models; 6.11.1 Intrinsic Capacitance Models. , Master and use copy. Digital master created according to Benchmark for Faithful Digital Reproductions of Monographs and Serials, Version 1. Digital Library Federation, December 2002.
    Additional Edition: Print version: Ytterdal, Trond. Device modeling for analog and RF CMOS circuit design. Hoboken, NJ : Wiley, ©2003 ISBN 0471498696
    Language: English
    Keywords: Electronic books. ; Electronic books.
    DOI: 10.1002/0470863803
    URL: https://onlinelibrary.wiley.com/doi/book/10.1002/0470863803
    URL: https://onlinelibrary.wiley.com/doi/book/10.1002/0470863803
    Library Location Call Number Volume/Issue/Year Availability
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    Online Resource
    Open Access Request
    HU Berlin
    FU Berlin
  • 2
    Online Resource
    Online Resource
    Mosfet Modeling & BSIM3 User’s Guide (2002)
    Boston, MA : Springer US
    Details
    UID:
    b3kat_BV045148443
    Format: 1 Online-Ressource (XVI, 462 p)
    ISBN: 9780306470509
    Content: Circuit simulation is essential in integrated circuit design, and the accuracy of circuit simulation depends on the accuracy of the transistor model. BSIM3v3 (BSIM for Berkeley Short-channel IGFET Model) has been selected as the first MOSFET model for standardization by the Compact Model Council, a consortium of leading companies in semiconductor and design tools. In the next few years, many fabless and integrated semiconductor companies are expected to switch from dozens of other MOSFET models to BSIM3. This will require many device engineers and most circuit designers to learn the basics of BSIM3. MOSFET Modeling & BSIM3 User's Guide explains the detailed physical effects that are important in modeling MOSFETs, and presents the derivations of compact model expressions so that users can understand the physical meaning of the model equations and parameters. It is the first book devoted to BSIM3. It treats the BSIM3 model in detail as used in digital, analog and RF circuit design. It covers the complete set of models, i.e., I-V model, capacitance model, noise model, parasitics model, substrate current model, temperature effect model and non quasi-static model. MOSFET Modeling & BSIM3 User's Guide not only addresses the device modeling issues but also provides a user's guide to the device or circuit design engineers who use the BSIM3 model in digital/analog circuit design, RF modeling, statistical modeling, and technology prediction. This book is written for circuit designers and device engineers, as well as device scientists worldwide. It is also suitable as a reference for graduate courses and courses in circuit design or device modelling. Furthermore, it can be used as a textbook for industry courses devoted to BSIM3. MOSFET Modeling & BSIM3 User's Guide is comprehensive and practical. It is balanced between the background information and advanced discussion of BSIM3. It is helpful to experts and students alike
    Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 9780792385752
    Language: English
    Keywords: MOS-FET ; Schaltungsentwurf ; Feldeffekttransistor ; MOS
    DOI: 10.1007/b117400
    URL: Volltext  (URL des Erstveröffentlichers)
    Library Location Call Number Volume/Issue/Year Availability
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    Online Resource
    Online Access
    Open Access Request
    BTU Cottbus
  • 3
    Online Resource
    Online Resource
    Device modeling for analog and RF CMOS circuit design / (2003)
    Hoboken, NJ :Wiley,
    Details
    UID:
    edocfu_9959327319002883
    Format: 1 online resource (xiii, 292 pages) : , illustrations
    Edition: Electronic reproduction. [Place of publication not identified] : HathiTrust Digital Library, 2010.
    ISBN: 0471498696 , 9780471498698 , 0470863803 , 9780470863800 , 0470864346 , 9780470864340
    Content: Bridges the gap between device modelling and analog circuit design. Includes dedicated software enabling actual circuit design. Covers the three significant models: BSIM3, Model 9 &, and EKV. Presents practical guidance on device development and circuit implementation. The authors offer a combination of extensive academic and industrial experience.
    Note: Device Modeling for Analog and RF CMOS Circuit Design; Contents; Preface; 1 MOSFET Device Physics and Operation; 1.1 Introduction; 1.2 The MOS Capacitor; 1.2.1 Interface Charge; 1.2.2 Threshold Voltage; 1.2.3 MOS Capacitance; 1.2.4 MOS Charge Control Model; 1.3 Basic MOSFET Operation; 1.4 Basic MOSFET Modeling; 1.4.1 Simple Charge Control Model; 1.4.2 The Meyer Model; 1.4.3 Velocity Saturation Model; 1.4.4 Capacitance Models; 1.4.5 Comparison of Basic MOSFET Models; 1.4.6 Basic Small-signal Model; 1.5 Advanced MOSFET Modeling; 1.5.1 Modeling Approach; 1.5.2 Nonideal Effects. , 1.5.3 Unified MOSFET C-V ModelReferences; 2 MOSFET Fabrication; 2.1 Introduction; 2.2 Typical Planar Digital CMOS Process Flow; 2.3 RF CMOS Technology; References; 3 RF Modeling; 3.1 Introduction; 3.2 Equivalent Circuit Representation of MOS Transistors; 3.3 High-frequency Behavior of MOS Transistors and AC Small-signal Modeling; 3.3.1 Requirements for MOSFET Modeling for RF Applications; 3.3.2 Modeling of the Intrinsic Components; 3.3.3 HF Behavior and Modeling of the Extrinsic Components; 3.3.4 Non-quasi-static Behavior; 3.4 Model Parameter Extraction. , 3.4.1 RF Measurement and De-embedding Techniques3.4.2 Parameter Extraction; 3.5 NQS Model for RF Applications; References; 4 Noise Modeling; 4.1 Noise Sources in a MOSFET; 4.2 Flicker Noise Modeling; 4.2.1 The Physical Mechanisms of Flicker Noise; 4.2.2 Flicker Noise Models; 4.2.3 Future Work in Flicker Noise Modeling; 4.3 Thermal Noise Modeling; 4.3.1 Existing Thermal Noise Models; 4.3.2 HF Noise Parameters; 4.3.3 Analytical Calculation of the Noise Parameters; 4.3.4 Simulation and Discussions; 4.3.5 Induced Gate Noise Issue; References; 5 Proper Modeling for Accurate Distortion Analysis. , 5.1 Introduction5.2 Basic Terminology; 5.3 Nonlinearities in CMOS Devices and Their Modeling; 5.4 Calculation of Distortion in Analog CMOS Circuits; References; 6 The BSIM4 MOSFET Model; 6.1 An Introduction to BSIM4; 6.2 Gate Dielectric Model; 6.3 Enhanced Models for Effective DC and AC Channel Length and Width; 6.4 Threshold Voltage Model; 6.4.1 Enhanced Model for Nonuniform Lateral Doping due to Pocket (Halo) Implant; 6.4.2 Improved Models for Short-channel Effects; 6.4.3 Model for Narrow Width Effects; 6.4.4 Complete Threshold Voltage Model in BSIM4; 6.5 Channel Charge Model. , 6.6 Mobility Model6.7 Source/Drain Resistance Model; 6.8 I-V Model; 6.8.1 I-V Model When rdsMod = 0 (R(DS)(V) 0); 6.8.2 I-V Model When rdsMod = 1 (R(DS)(V) = 0); 6.9 Gate Tunneling Current Model; 6.9.1 Gate-to-substrate Tunneling Current I(GB); 6.9.2 Gate-to-channel and Gate-to-S/D Currents; 6.10 Substrate Current Models; 6.10.1 Model for Substrate Current due to Impact Ionization of Channel Current; 6.10.2 Models for Gate-induced Drain Leakage (GIDL) and Gate-induced Source Leakage (GISL) Currents; 6.11 Capacitance Models; 6.11.1 Intrinsic Capacitance Models. , Master and use copy. Digital master created according to Benchmark for Faithful Digital Reproductions of Monographs and Serials, Version 1. Digital Library Federation, December 2002.
    Additional Edition: Print version: Ytterdal, Trond. Device modeling for analog and RF CMOS circuit design. Hoboken, NJ : Wiley, ©2003 ISBN 0471498696
    Language: English
    Keywords: Electronic books.
    DOI: 10.1002/0470863803
    URL: https://onlinelibrary.wiley.com/doi/book/10.1002/0470863803
    Library Location Call Number Volume/Issue/Year Availability
    BibTip Others were also interested in ...
    Online Resource
    Open Access Request
    FU Berlin
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