User:John R. Brews/WP Import: Difference between revisions

The hybrid-pi model is a popular circuit model used for analyzing the small signal behavior of transistors. 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 capacitances and other parasitic elements.

Bipolar transistor

(PD) Image: John R. Brews
Simplified, low-frequency hybrid-pi BJT model.

(PD) Image: John R. Brews
Bipolar hybrid-pi model with parasitic capacitances.

The hybrid-pi model is a linearized two-port network approximation to the transistor using the small-signal base-emitter voltage ${\displaystyle v_{be}}$ and collector-emitter voltage ${\displaystyle v_{ce}}$ as independent variables, and the small-signal base current ${\displaystyle i_{b}}$ and collector current ${\displaystyle i_{c}}$ as dependent variables. (See Jaeger and Blalock.^[1])

A basic, low-frequency hybrid-pi model for the bipolar transistor is shown in the figure. The three transistor terminals are E = emitter, B = base, and C = collector. The base-emitter connection is through a resistor r_π, and the base current causes a small-signal voltage drop across it, v_π (the π notation is standard). The various parameters are as follows.

• ${\displaystyle g_{m}={\frac {i_{c}}{v_{be}}}{\Bigg |}_{v_{ce}=0}={\begin{matrix}{\frac {I_{\mathrm {C} }}{V_{\mathrm {T} }}}\end{matrix}}}$ is the transconductance in siemens, evaluated in a simple model (see Jaeger and Blalock^[2])

where:

• ${\displaystyle I_{\mathrm {C} }\,}$ is the quiescent collector current (also called the collector bias or DC collector current)
• ${\displaystyle V_{\mathrm {T} }={\begin{matrix}{\frac {kT}{q}}\end{matrix}}}$ is the thermal voltage, calculated from Boltzmann's constant, the charge on an electron, and the transistor temperature in kelvins. At 290 K V_T is very nearly 25 mV (Google calculator)(room temperature or 70°F ≈ 294 K).

• ${\displaystyle r_{\pi }={\frac {v_{be}}{i_{b}}}{\Bigg |}_{v_{ce}=0}={\frac {\beta _{0}}{g_{m}}}={\frac {V_{\mathrm {T} }}{I_{\mathrm {B} }}}\,}$ in ohms

where:

• ${\displaystyle \beta _{0}={\frac {I_{\mathrm {C} }}{I_{\mathrm {B} }}}\,}$ is the current gain at low frequencies (commonly called h_FE). Here ${\displaystyle I_{B}}$ is the Q-point base current. This is a parameter specific to each transistor, and can be found on a datasheet; ${\displaystyle \beta }$ is a function of the choice of collector current.

• ${\displaystyle r_{O}={\frac {v_{ce}}{i_{c}}}{\Bigg |}_{v_{be}=0}={\begin{matrix}{\frac {V_{A}+V_{CE}}{I_{C}}}\end{matrix}}\approx {\begin{matrix}{\frac {V_{A}}{I_{C}}}\end{matrix}}}$ is the output resistance due to the Early effect.

Related terms

The reciprocal of the output resistance is named the output conductance

• ${\displaystyle g_{ce}={\frac {1}{r_{O}}}}$.

The reciprocal of g_m is called the intrinsic resistance

• ${\displaystyle r_{E}={\frac {1}{g_{m}}}}$.

MOSFET parameters

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.

• ${\displaystyle g_{m}={\frac {i_{d}}{v_{gs}}}{\Bigg |}_{v_{ds}=0}}$

is the transconductance in siemens, evaluated in the Shichman-Hodges model in terms of the Q-point drain current ${\displaystyle I_{D}}$ by (see Jaeger and Blalock^[3]):

${\displaystyle \ g_{m}={\begin{matrix}{\frac {2I_{\mathrm {D} }}{V_{\mathrm {GS} }-V_{\mathrm {th} }}}\end{matrix}}}$,

where:

${\displaystyle I_{\mathrm {D} }}$ is the quiescent drain current (also called the drain bias or DC drain current)

${\displaystyle V_{th}}$ = threshold voltage and ${\displaystyle V_{GS}}$ = gate-to-source voltage.

The combination:

${\displaystyle \ V_{ov}=(V_{GS}-V_{th})}$

often is called the overdrive voltage.

• ${\displaystyle r_{O}={\frac {v_{ds}}{i_{d}}}{\Bigg |}_{v_{gs}=0}}$ is the output resistance due to channel length modulation, calculated using the Shichman-Hodges model as

${\displaystyle r_{O}={\begin{matrix}{\frac {1/\lambda +V_{DS}}{I_{D}}}\end{matrix}}\approx {\begin{matrix}{\frac {V_{E}L}{I_{D}}}\end{matrix}}}$,

using the approximation for the channel length modulation parameter λ^[4]

${\displaystyle \lambda ={\begin{matrix}{\frac {1}{V_{E}L}}\end{matrix}}}$.

Here V_E is a technology related parameter (about 4 V / μm for the 65 nm technology node^[4]) and L is the length of the source-to-drain separation.

The reciprocal of the output resistance is named the drain conductance

• ${\displaystyle g_{ds}={\frac {1}{r_{O}}}}$.

References and notes