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{{Short description|Model of electronic circuits involving transistors}}
'''Hybrid-Pi''' is a popular [[Electronic circuit|circuit]] model used for analyzing the [[small signal]] behavior of [[Bipolar junction transistor|bipolar junction]] and [[Field-effect transistor|field effect transistors]]. Sometimes it is also called '''Giacoletto model''' because it was introduced by [[Lawrence J. Giacoletto|L.J. Giacoletto]] in 1969.<ref>Giacoletto, L.J. "Diode and transistor equivalent circuits for transient operation" IEEE Journal of Solid-State Circuits, Vol 4, Issue 2, 1969 [http://ieeexplore.ieee.org/xpl/articleDetails.jsp?tp=&arnumber=1049963&contentType=Journals+%26+Magazines&sortType%3Dasc_p_Sequence%26filter%3DAND%28p_IS_Number%3A22508%29]</ref> The model can be quite accurate for low-frequency circuits and can easily be adapted for higher frequency circuits with the addition of appropriate inter-electrode [[capacitance]]s and other [[Parasitic element (electrical networks)|parasitic elements]].▼
▲'''Hybrid-
==BJT parameters==▼
The hybrid-pi model is a linearized [[two-port network]] approximation to the BJT using the small-signal base-emitter voltage, <math>\scriptstyle v_\text{be}</math>, and collector-emitter voltage, <math>\scriptstyle v_\text{ce}</math>, as independent variables, and the small-signal base current, <math>\scriptstyle i_\text{b}</math>, and collector current, <math>\scriptstyle i_\text{c}</math>, as dependent variables.<ref name=Jaeger1>▼
▲== BJT parameters ==
▲The hybrid-pi model is a linearized [[two-port network]] approximation to the BJT using the small-signal base-emitter voltage, <math>\
{{cite book
|author=R.C. Jaeger and T.N. Blalock
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[[File:H pi model.svg|thumb|Figure 1: Simplified, low-frequency hybrid-pi [[BJT]] model.]]
A basic, low-frequency hybrid-pi model for the [[bipolar transistor]] is shown in figure 1. The various parameters are as follows.
: <math>g_\text{m} = \left.\frac{i_\text{c}}{v_\text{be}}\right\vert_{v_\text{ce} = 0} = \frac{I_\text{C}}{V_\text{T}}</math>
is the [[transconductance]], evaluated in a simple model,<ref name=Jaeger>
{{cite book
Line 26:
|isbn=978-0-07-232099-2
|url=http://worldcat.org/isbn/0072320990
|year=2004
|publisher=McGraw-Hill
}}</ref> where:
* <math>\
* <math>\
* <math>r_\pi = \left.\frac{v_\text{be}}{i_\text{b}}\right\vert_{v_\text{ce} = 0} = \frac{V_\text{T}}{I_\text{B}} = \frac{\beta_0}{g_\text{m}}</math>▼
▲*<math>r_\pi = \left.\frac{v_\text{be}}{i_\text{b}}\right\vert_{v_\text{ce} = 0} = \frac{V_\text{T}}{I_\text{B}} = \frac{\beta_0}{g_\text{m}}</math>
where:
* <math>\
* <math>\
* <math>\
=== Related terms ===
The ''output [[electrical conductance|conductance]]'', ''g''{{sub|ce}}, is the reciprocal of the output resistance, ''r''{{sub|o}}:
: <math>g_\text{ce} = \frac{1}{r_\text{o}}</math>.
The ''[[transresistance]]'', ''r''{{sub|m}}, is the reciprocal of the transconductance:
: <math>r_\text{m} = \frac{1}{g_\text{m}}</math>.
=== Full model ===
[[File:Hybrid-pi detailed model.svg|thumb|Full hybrid-pi model]]
The full model introduces the virtual terminal,
{{-}}
== MOSFET parameters ==
[[File:MOSFET small signal.svg|thumb|Figure 2: Simplified, low-frequency hybrid-pi [[MOSFET]] model.]]
A basic, low-frequency hybrid-pi model for the [[MOSFET]] is shown in figure 2. The various parameters are as follows.
: <math>g_\text{m} = \left.\frac{i_\text{d}}{v_\text{gs}}\right\vert_{v_\text{ds} = 0}</math>
is the [[transconductance]], evaluated in the Shichman–Hodges model in terms of the [[Q-point]] drain current, <math>\scriptstyle I_\text{D}</math>:<ref name=Jaeger2>
{{cite book
Line 63 ⟶ 60:
|isbn=978-0-07-232099-2
|url=http://worldcat.org/isbn/0072320990
|year=2004
|publisher=McGraw-Hill
: <math>g_\text{m} = \frac{2I_\text{D}}{V_{\text{GS}} - V_\text{th}}</math>,▼
▲:<math>g_\text{m} = \frac{2I_\text{D}}{V_{\text{GS}} - V_\text{th}}</math>,
where:
* <math>\scriptstyle I_\text{D} </math> is the [[quiescent current|quiescent]] drain current (also called the drain bias or DC drain current)
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The combination:
: <math>V_\text{ov} = V_\text{GS} - V_\text{th}</math>
is often called ''overdrive voltage''.
: <math>r_\text{o} = \left.\frac{v_\text{ds}}{i_\text{d}}\right\vert_{v_\text{gs} = 0}</math>
is the output resistance due to [[channel length modulation]], calculated using the Shichman–Hodges model as
: <math>\begin{align}
r_\text{o} &= \frac{1}{I_\text{D}}\left(\frac{1}{\lambda} + V_\text{DS}\right) \\
&= \frac{1}{I_\text{D}}\left(V_E L + V_\text{DS}\right) \approx \frac{V_E L}{I_\text{D}}
\end{align}</math>
using the approximation for the ''channel length modulation'' parameter, ''λ'':<ref name=Sansen>▼
▲using the approximation for the ''channel length modulation'' parameter, λ:<ref name=Sansen>
{{cite book
|author=W. M. C. Sansen
Line 97 ⟶ 89:
|url=http://worldcat.org/isbn/0387257462
}}</ref>
: <math> \lambda = \frac{1}{
Here ''V''<sub>E</sub>
▲Here ''V<sub>E</sub>'' is a technology-related parameter (about 4 V/μm for the [[65 nanometer|65 nm]] technology node<ref name = Sansen/>) and ''L'' is the length of the source-to-drain separation.
The ''drain conductance'' is the reciprocal of the output resistance:
: <math>g_\text{ds} = \frac{1}{r_\text{o}} </math>.
*[[Small signal model]]▼
*[[Bipolar junction transistor#h-parameter model|h-parameter model]]▼
==
▲* [[Bipolar junction transistor#h-parameter model|h-parameter model]]
== References and notes ==
{{reflist}}
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