Difference between revisions of "TF EIM Chapt6"

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Field Effect Transistors (FET, JFET, MOSFET)
  
==Load Line==
+
=Properties=
  
 +
FETs differ from the bipolar transistors in the las chapter in that the current from a FET is only due to the majority charge carriers in the semiconductor while bi-polar transistors current is produced from both carrier types; electron and hole.
  
The load line represents the bias conditions in which the <math>I_C -vs V_{CE}</math> dependence is linear;(i.e.: a constance Resistance).  Setting up a circuit which changes the transistor bias along the load line means that the transistor is behaving like a resistor.
+
*higher input impedance than bi-polar
 +
*less gain than bi-polar
 +
*better temperature stability
  
 +
=JFET =
  
Consider the collector-Emitter side of the transistor below.
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JFET <math>\equiv</math>  Junction Field Effect Transistor
  
[[File:TF_EIM_LoadLineCircuit1.gif | 500 px]]
 
  
 +
In a bi-polar transistor you have a depletion region with mixed charge carriers
  
Kirchoff's loops theorem is
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{| border="3"  cellpadding="20" cellspacing="0"
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|[[File:TF_EIM_BipolarJunction.png| 200 px]] ||  [[File:TF_EIM_BipolarJunctionDiodeRep.png| 200 px]] ||[[File:TF_EIM_BipolarJunctionCircuit.png| 200 px]]
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|-
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| pnp bi-polar transistor || Equivalence circuit || Circuit diagram
 +
|-
 +
|}
  
<math>V_{CC} - I_CR_C -V{CE} = 0</math>
 
  
<math>\Rightarrow</math>
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In the Junction Field Effect Transistor you have a single charge carrier with the minority charge carriers forming a choke point for the majority carrier current flow.  It is similar to "pinching" a garden hose when water is flowing through it.
  
<math>I_C = \frac{V_{CC}}{R_C} - \frac{1}{R_C} V_{CE}</math>
 
  
A graph of <math>I_C -vs- V_{CE}</math> is a line with a slope of<math> - \frac{1}{R_C}</math> and a y-intercept of  <math>\frac{V_{CC}}{R_C}</math>.
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{| border="3"  cellpadding="20" cellspacing="0"
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|[[File:TF_EIM_JFETnchan.gif| 200 px]] ||  [[File:TF_EIM_nchanDiodeRep.jpg| 200 px]] ||[[File:TF_EIM_JFETnchanCircuit.jpeg| 200 px]]
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|-
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| JFET || Equivalence circuit || Circuit diagram
 +
|-
 +
|}
  
If <math>I_C=0</math> then <math>V_{CE} = V_{CC}</math>.
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The semiconductor material of the gate is the opposite of the channel. Here the n-p (or p-n) junction is between the gate and the channel. 
  
The point Q_0 in the  above curve represents a "Quiescent" point where the best amplification occurs because it is in the middle of the operating point.
+
The JFET operates by reverse biasing the gate-channel junction (diode) so the gate current doesn't flow in the direction indicated by the circuit diagram symbol. This means that the current through the gate is small (nAmps).  As a result the input impedance looking into the gate is high (M<math>\Omega</math>) for the equivalent circuit.
  
Q_0 is the cutoff point where there is no output:ie; the base current is zero.
+
The current junction rule is
  
Q_S is the point where the amplifier is saturating.  he transistor can;t supply the needed drive current so the output is truncated.
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:<math>I_D = I_S + I_G \approx I_S</math>
  
==Temperature Dependence==
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for the Bi-Polar transistor
  
 +
:<math>I_C=I_E +I_B \approx I_E</math>
  
As the temperature increases the impurity atoms tend to diffuse through the semiconductor fro high concentration regions to low concentration regions. 
+
==Resistance==
  
This diffusion changes the<math> I_C -vs- V_{CE}</math>  curve near the saturation region because the diode biasing voltages change.
+
The FET acts like a resistor.
  
 +
Consider the following circuit
  
 +
Let
  
You don't want the temperature change of the transistor to change the bias conditions of the transistor.
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<math>V_{DD} =</math> the drain driving voltage
  
=Bipolar Transistor Amplifier=
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<math>R_D</math> = resistor between the drain and V_{DD}
  
 +
if
 +
<math>\rho</math> = resistivity of the n-type semiconductor
  
[[File:TF_EIM_Lab14a.png]]
+
then
  
 +
:r = <math>\rho \frac{\ell}{A}</math> = resistance of the JFET
  
Consider the above circuit.
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:<math>I_D = \frac{V_{DD}}{r+R_D}</math>
  
Observations
+
If you reverse bias the gate then the depletion region at the p-n junction expands into the n-type material thereby reducing the cross-sectional area (A) of the channel.
  
1.) Notice the input goes through a high pass filter with a break point of<math> \frac{1}{R_1 C_1}</math>.
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==FET pinchoff==
  
2.) The output also goes through a high pass filter  with a break point of<math> \frac{1}{R_l C_2}</math>.
+
If you continue to reverse bias the gate, keeping V_{DD} constant, then the drain current will decrease as you make the gate more negative.
  
3.) Kirchoff voltage rule
+
The pinchoff condition will occur when the reverse bias is large enough to stop the drain current I_D.
  
:<math>V_{CC} -I_C R_C - V_{CE} - I_E R_E = 0</math>
+
:<math>V_{GS(off)} = \mbox{pinchoff bias} = \frac{enT}{8 \epsilon}</math>
:<math>V_{CC} - V_{CE} -I_C (R_C  + R_E) = 0</math>  <math>I_C \approx I_E</math>
 
  
:<math>\Rightarrow I_C =\frac{ V_{CC} - V_{CE}}{R_C  + R_E }</math>
+
where
  
4.) Kirchoff law
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:<math>\epsilon</math> = dielectric constant
 +
:<math>T</math> = thickness of the channel
 +
:<math>n</math> = number of impurity atoms per volume
  
:<math>V_{CC} -(I_B + I_D) R_2 - V_{EB} - I_E R_E = 0</math>
 
  
5.) INput resistance
+
You can find the "pinchoff" voltage by making V_{GS} more negative (n-channel) until the drain current I_D becomes zero.
  
<math>\frac{1}{R_{in}} = \frac{1}{X_B} + \frac{1}{R_1} + \frac{1}{R_2}</math>
 
  
6.)
+
In the other extreme
  
:<math>V_B = \frac{R_1}{R_1+R_2} V_{CC}</math>
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:<math>I_{DSS} \equiv</math> Maximum drain current (current flows from Drain to Source with the gate Shorted; ie <math>V_{GS}</math> = 0)
 +
 
 +
==Temperature==
 +
 
 +
Because of the way a JFET operates, by pinching the current, the device heats up less at higher currents because you are no longer restricting the current flow.
 +
 
 +
At low values of<math> I_D</math> and increase in the device temperature will cause an increase in <math>I_D</math>.
 +
 
 +
But at high values of <math>I_D</math> the increase in temperature decreases <math>I_D</math>.
 +
 
 +
This feature of the JFET allows you to chain several together for amplification such that if one starts to overheat it will amplify less.
 +
 
 +
== Characteristic curve==
 +
 
 +
The JFET has a characteristic curve that is similar to the bi-polar transistor.  In the case of the bi-polar transistor you saw a dependence of the collector current (<math>I_C</math>) on the potential difference between the collector and the emitter (<math>V_{CE}</math>) for several values of the base current <math>I_B.</math>
 +
 
 +
The JFET has a similar characteristic curve which the drain current (<math>I_D</math>) depends on the voltage difference between the drain and source (<math>V_{DS}</math>) for several values of the gate-source potential difference (<math>V_{S}</math>).
 +
 
 +
The difference is that higher base current in the bi-polar transistor yields higher output currents whereas in the JFET you get higher output currents with the least negative gate bias (n-channel).
 +
 
 +
 
 +
[[File:TF_EIM_JFET_Vgs-vs-Id.png | 300 px]][[File:TF_EIM_JFET_Vds-vs-Id.png | 300 px]]
 +
 
 +
= Equivalent circuit=
 +
 
 +
The method of Equivalent circuits seeks to describe the performance of a circuit in terms of it input and output voltages and currents.  One you know the dependence of these parameters then the circuit becomes a black box.
 +
 
 +
 
 +
 
 +
Let
 +
 
 +
<math>V_{in}, V_{out}, I_{in}, I_{out}</math> be the four variables which describe the circuit.
 +
 
 +
choose
 +
 
 +
<math>V_{in}</math> and <math>V_{out}</math> as the independent variables which will be described by the dependent variables <math>I_{in}</math> and <math>I_{out}</math>
 +
 
 +
In other words you express the currents as functions of the voltages
 +
 
 +
:<math>I_{in} = f_{in}(V_{in},V_{out})</math>
 +
:<math>I_{in} = f_{out}(V_{in},V_{out})</math>
 +
 
 +
 
 +
using the chain rule you can express small changes in the current as
 +
 
 +
:<math>\Delta I_{in} = \left ( \frac{\partial I_{in}}{\partial V_{in}} \right ) \Delta V_{in} + \left (  \frac{\partial I_{in}}{\partial V_{out}} \right ) \Delta V_{out}</math>
 +
:<math>\Delta I_{out} = \left ( \frac{\partial I_{out}}{\partial V_{in}} \right ) \Delta V_{in} + \left (  \frac{\partial I_{out}}{\partial V_{out}} \right ) \Delta V_{out}</math>
 +
 
 +
;Note:The derivatives with respect to one voltage are taken for fixed values of the other voltage.
 +
 
 +
 
 +
You define the derivative in terms of "y-parameters" such that
 +
 
 +
:<math>y_{is} \equiv \left ( \frac{\partial I_{in}}{\partial V_{in}} \right )</math> = input conductance
 +
 
 +
: <math>y_{rs} \equiv  \left (  \frac{\partial I_{in}}{\partial V_{out}} \right )</math>
 +
 
 +
: <math>y_{fs} \equiv  \left ( \frac{\partial I_{out}}{\partial V_{in}} \right )</math>
 +
 
 +
: <math>g_m \equiv y_{os} \equiv  \left ( \frac{\partial I_{out}}{\partial V_{out}} \right )</math> = output conductance
 +
 
 +
 
 +
In the case of the common source JFET configuration
 +
 
 +
<math>I_{in} = I_G</math> , <math>I_{out} = I_D</math>
 +
 
 +
==admittance==
 +
 
 +
;Notice: The above y-parameters have units of inverse Ohms 
 +
 
 +
The SI unit for this is called the "siemens" and is represented by '''S'''
 +
 
 +
:<math>\mbox {siemens} = S = \frac{1}{\mbox {Ohms}} = \Omega^{-1}</math>
 +
 
 +
The inverse of resistance is conductance. 
 +
 
 +
In electric engineering the term "admittance" is used to describe how easily a circuit will allow current to flow (its conductance).
 +
 
 +
The unit "mho" is also used as an equivalent unit to '''S''' used by electrical engineers.
 +
 
 +
 
 +
:<math>\mbox {mho} = \frac{1}{\mbox {Ohms}} = \Omega^{-1}</math>
 +
 
 +
 
 +
== the JFET equivalent Circuit==
 +
 
 +
Below is a common source JFET configuration.  The Gate and Drain have the Source line as a common reference.  This is analogous to the common emitter configuration discussed in the last chapter and using in [[Lab_14_TF_EIM]].
 +
 
 +
[[File:TF_EIM_JFET_CommonSOurceCircuit.png| 200 px]]
 +
 
 +
 
 +
===DC===
 +
 
 +
[[File:TF_EIM_JFET_DCequivCircuit.png| 200 px]]
 +
 
 +
 
 +
The arrows with circles indicate ideal current sources.  The one on the left has the current <math>y_{rs}V_{out}</math> and the one on the right <math>y_{rs}V_{in}</math>
 +
 
 +
===AC===
 +
[[File:TF_EIM_JFET_ACequivCircuit.png| 200 px]]
 +
 
 +
C_{gs} is the capacitance between the gate and the source.
 +
 
 +
C_{gd}  is the capacitance between the gate and the drain.
 +
 
 +
=MOSFET=
 +
 
 +
MOSFET<math> \equiv</math> Metal-Oxide-Semiconductor Field Effect Transistor
  
 
[[Forest_Electronic_Instrumentation_and_Measurement]]
 
[[Forest_Electronic_Instrumentation_and_Measurement]]

Latest revision as of 15:00, 6 April 2011

Field Effect Transistors (FET, JFET, MOSFET)

Properties

FETs differ from the bipolar transistors in the las chapter in that the current from a FET is only due to the majority charge carriers in the semiconductor while bi-polar transistors current is produced from both carrier types; electron and hole.

  • higher input impedance than bi-polar
  • less gain than bi-polar
  • better temperature stability

JFET

JFET [math]\equiv[/math] Junction Field Effect Transistor


In a bi-polar transistor you have a depletion region with mixed charge carriers

TF EIM BipolarJunction.png TF EIM BipolarJunctionDiodeRep.png TF EIM BipolarJunctionCircuit.png
pnp bi-polar transistor Equivalence circuit Circuit diagram


In the Junction Field Effect Transistor you have a single charge carrier with the minority charge carriers forming a choke point for the majority carrier current flow. It is similar to "pinching" a garden hose when water is flowing through it.


TF EIM JFETnchan.gif TF EIM nchanDiodeRep.jpg TF EIM JFETnchanCircuit.jpeg
JFET Equivalence circuit Circuit diagram

The semiconductor material of the gate is the opposite of the channel. Here the n-p (or p-n) junction is between the gate and the channel.

The JFET operates by reverse biasing the gate-channel junction (diode) so the gate current doesn't flow in the direction indicated by the circuit diagram symbol. This means that the current through the gate is small (nAmps). As a result the input impedance looking into the gate is high (M[math]\Omega[/math]) for the equivalent circuit.

The current junction rule is

[math]I_D = I_S + I_G \approx I_S[/math]

for the Bi-Polar transistor

[math]I_C=I_E +I_B \approx I_E[/math]

Resistance

The FET acts like a resistor.

Consider the following circuit

Let

[math]V_{DD} =[/math] the drain driving voltage

[math]R_D[/math] = resistor between the drain and V_{DD}

if [math]\rho[/math] = resistivity of the n-type semiconductor

then

r = [math]\rho \frac{\ell}{A}[/math] = resistance of the JFET
[math]I_D = \frac{V_{DD}}{r+R_D}[/math]

If you reverse bias the gate then the depletion region at the p-n junction expands into the n-type material thereby reducing the cross-sectional area (A) of the channel.

FET pinchoff

If you continue to reverse bias the gate, keeping V_{DD} constant, then the drain current will decrease as you make the gate more negative.

The pinchoff condition will occur when the reverse bias is large enough to stop the drain current I_D.

[math]V_{GS(off)} = \mbox{pinchoff bias} = \frac{enT}{8 \epsilon}[/math]

where

[math]\epsilon[/math] = dielectric constant
[math]T[/math] = thickness of the channel
[math]n[/math] = number of impurity atoms per volume


You can find the "pinchoff" voltage by making V_{GS} more negative (n-channel) until the drain current I_D becomes zero.


In the other extreme

[math]I_{DSS} \equiv[/math] Maximum drain current (current flows from Drain to Source with the gate Shorted; ie [math]V_{GS}[/math] = 0)

Temperature

Because of the way a JFET operates, by pinching the current, the device heats up less at higher currents because you are no longer restricting the current flow.

At low values of[math] I_D[/math] and increase in the device temperature will cause an increase in [math]I_D[/math].

But at high values of [math]I_D[/math] the increase in temperature decreases [math]I_D[/math].

This feature of the JFET allows you to chain several together for amplification such that if one starts to overheat it will amplify less.

Characteristic curve

The JFET has a characteristic curve that is similar to the bi-polar transistor. In the case of the bi-polar transistor you saw a dependence of the collector current ([math]I_C[/math]) on the potential difference between the collector and the emitter ([math]V_{CE}[/math]) for several values of the base current [math]I_B.[/math]

The JFET has a similar characteristic curve which the drain current ([math]I_D[/math]) depends on the voltage difference between the drain and source ([math]V_{DS}[/math]) for several values of the gate-source potential difference ([math]V_{S}[/math]).

The difference is that higher base current in the bi-polar transistor yields higher output currents whereas in the JFET you get higher output currents with the least negative gate bias (n-channel).


TF EIM JFET Vgs-vs-Id.pngTF EIM JFET Vds-vs-Id.png

Equivalent circuit

The method of Equivalent circuits seeks to describe the performance of a circuit in terms of it input and output voltages and currents. One you know the dependence of these parameters then the circuit becomes a black box.


Let

[math]V_{in}, V_{out}, I_{in}, I_{out}[/math] be the four variables which describe the circuit.

choose

[math]V_{in}[/math] and [math]V_{out}[/math] as the independent variables which will be described by the dependent variables [math]I_{in}[/math] and [math]I_{out}[/math]

In other words you express the currents as functions of the voltages

[math]I_{in} = f_{in}(V_{in},V_{out})[/math]
[math]I_{in} = f_{out}(V_{in},V_{out})[/math]


using the chain rule you can express small changes in the current as

[math]\Delta I_{in} = \left ( \frac{\partial I_{in}}{\partial V_{in}} \right ) \Delta V_{in} + \left ( \frac{\partial I_{in}}{\partial V_{out}} \right ) \Delta V_{out}[/math]
[math]\Delta I_{out} = \left ( \frac{\partial I_{out}}{\partial V_{in}} \right ) \Delta V_{in} + \left ( \frac{\partial I_{out}}{\partial V_{out}} \right ) \Delta V_{out}[/math]
Note
The derivatives with respect to one voltage are taken for fixed values of the other voltage.


You define the derivative in terms of "y-parameters" such that

[math]y_{is} \equiv \left ( \frac{\partial I_{in}}{\partial V_{in}} \right )[/math] = input conductance
[math]y_{rs} \equiv \left ( \frac{\partial I_{in}}{\partial V_{out}} \right )[/math]
[math]y_{fs} \equiv \left ( \frac{\partial I_{out}}{\partial V_{in}} \right )[/math]
[math]g_m \equiv y_{os} \equiv \left ( \frac{\partial I_{out}}{\partial V_{out}} \right )[/math] = output conductance


In the case of the common source JFET configuration

[math]I_{in} = I_G[/math] , [math]I_{out} = I_D[/math]

admittance

Notice
The above y-parameters have units of inverse Ohms

The SI unit for this is called the "siemens" and is represented by S

[math]\mbox {siemens} = S = \frac{1}{\mbox {Ohms}} = \Omega^{-1}[/math]

The inverse of resistance is conductance.

In electric engineering the term "admittance" is used to describe how easily a circuit will allow current to flow (its conductance).

The unit "mho" is also used as an equivalent unit to S used by electrical engineers.


[math]\mbox {mho} = \frac{1}{\mbox {Ohms}} = \Omega^{-1}[/math]


the JFET equivalent Circuit

Below is a common source JFET configuration. The Gate and Drain have the Source line as a common reference. This is analogous to the common emitter configuration discussed in the last chapter and using in Lab_14_TF_EIM.

TF EIM JFET CommonSOurceCircuit.png


DC

TF EIM JFET DCequivCircuit.png


The arrows with circles indicate ideal current sources. The one on the left has the current [math]y_{rs}V_{out}[/math] and the one on the right [math]y_{rs}V_{in}[/math]

AC

TF EIM JFET ACequivCircuit.png

C_{gs} is the capacitance between the gate and the source.

C_{gd} is the capacitance between the gate and the drain.

MOSFET

MOSFET[math] \equiv[/math] Metal-Oxide-Semiconductor Field Effect Transistor

Forest_Electronic_Instrumentation_and_Measurement

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