Transistor model: Difference between revisions

Browse history interactively

← Previous edit

Content deleted Content added

VisualWikitext

Revision as of 23:41, 3 March 2020 edit InternetArchiveBot (talk \| contribs) Bots, Pending changes reviewers 5,698,988 edits Bluelinking 1 books for verifiability.) #IABot (v2.1alpha3 ← Previous edit		Latest revision as of 19:54, 19 June 2025 edit undo OAbot (talk \| contribs) Bots 646,409 edits m Open access bot: url-access updated in citation with #oabot.
(21 intermediate revisions by 18 users not shown)
Line 1: {{Short description\|Simulation of physical processes taking place in an electronic device}} {{More footnotes needed\|date=January 2015}} [[Transistor]]s are simple devices with complicated behavior{{citation needed\|date=November 2022}}. In order to ensure the reliable operation of circuits employing transistors, it is necessary to [[Scientific modelling\|scientifically model]] the physical phenomena observed in their operation using '''transistor models'''. There exists a variety of different [[Model (abstract)\|models]] that range in complexity and in purpose. Transistor models divide into two major groups: models for device design and models for circuit design. ==Models for device design== Line 7 ⟶ 8: With this information about what the device looks like, the device simulator models the physical processes taking place in the device to determine its electrical behavior in a variety of circumstances: DC current–voltage behavior, transient behavior (both large-signal and small-signal), dependence on device layout (long and narrow versus short and wide, or interdigitated versus rectangular, or isolated versus proximate to other devices). These simulations tell the device designer whether the device process will produce devices with the electrical behavior needed by the circuit designer, and is used to inform the process designer about any necessary process improvements. Once the process gets close to manufacture, the predicted device characteristics are compared with measurement on test devices to check that the process and device models are working adequately. Although long ago the device behavior modeled in this way was very simple{{spaced en dash}} mainly drift plus diffusion in simple geometries{{spaced en dash}} today many more processes must be modeled at a microscopic level; for example, leakage currents<ref name=":0">{{Cite patent\|number=WO2000077533A3\|title=Semiconductor device simulation method and simulator\|gdate=2001-04-26\|invent1=Lui\|inventor1-first=Basil\|url=https://patents.google.com/patent/WO2000077533A3/en?inventor=Basil+Lui}}</ref> in junctions and oxides, complex transport of carriers including [[velocity saturation]] and ballistic transport, quantum mechanical effects, use of multiple materials (for example, [[SiGe#SiGe Transistors\|Si-SiGe]] devices, and stacks of different [[high-~~κ_dielectric~~κ dielectric\|dielectrics]]) and even the statistical effects due to the probabilistic nature of ion placement and carrier transport inside the device. Several times a year the technology changes and simulations have to be repeated. The models may require change to reflect new physical effects, or to provide greater accuracy. The maintenance and improvement of these models is a business in itself. These models are very computer intensive, involving detailed spatial and temporal solutions of coupled partial differential equations on three-dimensional grids inside the device.<ref name=Jacoboni> Line 16 ⟶ 17: \|___location=Wien \|isbn=3-211-82110-4 \|url=https://books.google.com/books?id=3cWnyhKmACEC~~&pg=PP1~~&dq=isbn~~=3-211-82110-4~~&~~sig~~pg=~~TCFY-o_l5gLj8OblcwGgQeB4Xts~~PP1}} </ref><ref name=Selberherr> {{cite book \|author=[[Siegfried Selberherr]] \|author-link=Siegfried Selberherr \|title=Analysis and Simulation of Semiconductor Devices \|year= 1984 Line 25 ⟶ 27: \|___location=Wien \|isbn=3-211-81800-6 \|url=https://books.google.com/books?id=EE4HlRZTYi4C~~&pg=PA97~~&dq=isbn~~=3-211-81800-6~~&~~sig~~pg=~~19_iT2-C0gy8WdBIPcLc7gRAXw8#PPP1,M1~~PA97}} </ref><ref name=Grasser> {{cite book \|~~author~~editor=Tibor Grasser ~~(Editor)~~ \|title=Advanced Device Modeling and Simulation (Int. J. High Speed Electron. and Systems) \|year= 2003 \|publisher=World Scientific \|isbn=981-238-607-6 \|url=https://books.google.com/books?id=HBkA3_pZMp4C&dqq=%22MOSFET++simulation%22~~&as_brr=0~~}} </ref><ref name=Kramer> {{cite book \|author1=Kramer, Kevin M. \|author2=Hitchon, W. Nicholas G. \|~~lastauthoramp~~name-list-style=~~yes~~amp \|title=Semiconductor devices: a simulation approach \|year= 1997 \|publisher=Prentice Hall PTR Line 45 ⟶ 47: </ref><ref name=Vasileska> {{cite book \|author1=Dragica Vasileska\|author1-link=Dragica Vasileska \|author2=Stephen Goodnick \|title=Computational Electronics \|year= 2006 \|page=.83 \|publisher=Morgan & Claypool \|isbn=1-59829-056-8 \|url=https://books.google.com/books?id=DBPnzqy5Fd8C&~~printsec=frontcover&dq~~q=%22gate+tunneling%22~~&as_brr=0#PPA83,M1~~}} </ref> Such models are slow to run and provide detail not needed for circuit design. Therefore, faster transistor models oriented toward circuit parameters are used for circuit design. Line 62 ⟶ 64: \|year= 2007 \|publisher=World Scientific \|isbn=978-981-256-810-76 \|url=https://books.google.com/books?id=yrrDcRm9bfUC~~&pg=PA293~~&dq=%22gate+tunneling%22&~~as_brr~~pg=~~0&sig=SJv5PSqaLbMdw10sEQPFd3ykN8E#PPA1,M1~~PA293}} </ref> Line 74 ⟶ 76: \|page=Chapter 1 \|publisher=World Scientific \|isbn=978-981-256-862-X5 \|url=https://books.google.com/books?id=SkT2xOuvpuYC&dqq=%22table+lookup+model%22~~&as_brr=0~~ \|~~nopp~~no-pp=true}} </ref><ref name=Tsividis> {{cite book Line 92 ⟶ 94: ====Physical models==== : These are [[Semiconductor device modeling\|models based upon device physics]], based upon approximate modeling of physical phenomena within a transistor.<ref name=":0" /><ref>{{Cite journal \|last1=Lui \|first1=Basil \|last2=Migliorato \|first2=P \|date=1997-04-01 \|title=A new generation-recombination model for device simulation including the Poole-Frenkel effect and phonon-assisted tunnelling \|url=https://www.sciencedirect.com/science/article/pii/S0038110196001487 \|journal=Solid-State Electronics \|language=en \|volume=41 \|issue=4 \|pages=575–583 \|doi=10.1016/S0038-1101(96)00148-7 \|bibcode=1997SSEle..41..575L \|issn=0038-1101\|url-access=subscription }}</ref> Parameters<ref>{{Cite journal \|last1=Lui \|first1=Basil \|last2=Tam \|first2=S. W. B. \|last3=Migliorato \|first3=P. \|date=1998 \|title=A Polysilicon Tft Parameter Extractor \|url=https://www.cambridge.org/core/journals/mrs-online-proceedings-library-archive/article/abs/polysilicon-tft-parameter-extractor/AFB82CB806F1140E9249C5FA90285B66 \|journal=MRS Online Proceedings Library \|language=en \|volume=507 \|pages=365 \|doi=10.1557/PROC-507-365 \|issn=0272-9172\|url-access=subscription }}</ref><ref>{{Cite journal \|last1=Kimura \|first1=Mutsumi \|last2=Nozawa \|first2=Ryoichi \|last3=Inoue \|first3=Satoshi \|last4=Shimoda \|first4=Tatsuya \|last5=Lui \|first5=Basil \|last6=Tam \|first6=Simon Wing-Bun \|last7=Migliorato \|first7=Piero \|date=2001-09-01 \|title=Extraction of Trap States at the Oxide-Silicon Interface and Grain Boundary for Polycrystalline Silicon Thin-Film Transistors \|url=https://iopscience.iop.org/article/10.1143/JJAP.40.5227/meta \|journal=Japanese Journal of Applied Physics \|language=en \|volume=40 \|issue=9R \|pages=5227 \|doi=10.1143/JJAP.40.5227 \|bibcode=2001JaJAP..40.5227K \|s2cid=250837849 \|issn=1347-4065\|url-access=subscription }}</ref> within these models are based upon physical properties such as oxide thicknesses, substrate doping concentrations, carrier mobility, etc.<ref>{{Cite journal \|last1=Lui \|first1=Basil \|last2=Tam \|first2=S. W.-B. \|last3=Migliorato \|first3=P. \|last4=Shimoda \|first4=T. \|date=2001-06-01 \|title=Method for the determination of bulk and interface density of states in thin-film transistors \|url=https://aip.scitation.org/doi/abs/10.1063/1.1361244 \|journal=Journal of Applied Physics \|volume=89 \|issue=11 \|pages=6453–6458 \|doi=10.1063/1.1361244 \|bibcode=2001JAP....89.6453L \|issn=0021-8979\|url-access=subscription }}</ref> In the past these models were used extensively, but the complexity of modern devices makes them inadequate for quantitative design. Nonetheless, they find a place in hand analysis (that is, at the conceptual stage of circuit design), for example, for simplified estimates of signal-swing limitations. ====Empirical models==== Line 117 ⟶ 119: * [[Gummel–Poon model]] * [[Bipolar junction transistor#Ebers–Moll model\|Ebers–Moll model]] * [http://www-device.eecs.berkeley.edu/bsim/?page=BSIM3 BSIM3] (see [[BSIM]]) * [http://www-device.eecs.berkeley.edu/bsim/?page=BSIM4 BSIM4] * [http://www-device.eecs.berkeley.edu/bsim/?page=BSIMSOI BSIMSOI] * [[EKV MOSFET Model]] (see also [http://ekv.epfl.ch/ its web site] at [[École Polytechnique Fédérale de Lausanne\|EPFL]]) * [http://www.cea.fr/cea-tech/leti/pspsupport/ PSP] * [http://www.iee.et.tu-dresden.de/iee/eb/hic_new/hic_start.html HICUM] * [http://mextram.ewi.tudelft.nl/ MEXTRAM] * [[Hybrid-pi model]] * [[Bipolar junction transistor#h-parameter model\|H-parameter model]] ==See also== * [[{{section link\|Bipolar junction transistor#\|Theory and modeling]]}} * [[Safe operating area]] * [[Electronic design automation]] Line 135 ⟶ 130: ==References== {{Reflist}} ~~<references/>~~ ==External links== *''Agilent EEsof EDA, IC-CAP Parameter Extraction and Device Modeling Software [https://www.keysight.com/en/pc-1297149/ic-cap-device-modeling-software-measurement-control-and-parameter-extraction?cc=US&lc=eng http://eesof.tm.agilent.com/products/iccap_main.html] '' [[Category:Electronic engineering]] [[Category:Transistor modeling]]''