Transcript V GS

ECE 271
Electronic Circuits I
Topic 4
Field-Effect Transistors
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-1
Chapter Goals
• Describe structure and operation of MOSFETs.
• Define FET characteristics in operation regions of cutoff, triode and
saturation.
• Develop mathematical models for i-v characteristics of MOSFETs.
• Introduce graphical representations for output and transfer
characteristic descriptions of electron devices.
• Define and contrast characteristics of enhancement-mode and
depletion-mode FETs.
• Define symbols to represent FETs in circuit schematics.
• Investigate circuits that bias transistors into different operating regions.
• Explore FET modeling in SPICE.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-2
Intro (1)
•
•
Solid state transistor is the main building block of microelectronics.
It performs two major functions used in electronic devices:
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-3
Intro (1)
•
•
Solid state transistor is the main building block of microelectronics.
It performs two major functions used in electronic devices:
- amplifications (in analog)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-4
Intro (1)
•
•
Solid state transistor is the main building block of microelectronics.
It performs two major functions used in electronic devices:
- amplifications (in analog)
- switching (in digital)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-5
Intro (1)
•
•
Solid state transistor is the main building block of microelectronics.
It performs two major functions used in electronic devices:
- amplifications (in analog)
- switching (in digital)
•
There are two basic types of solid state transistors: BJT (bipolar junction
transistor) and FET (field effect transistor).
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-6
Intro (1)
•
•
Solid state transistor is the main building block of microelectronics.
It performs two major functions used in electronic devices:
- amplifications (in analog)
- switching (in digital)
•
There are two basic types of solid state transistors: BJT (bipolar junction
transistor) and FET (field effect transistor).
•
FET: electric field is used to control the shape and the conductivity of the
channel of one type charge carrier (p or n) in semiconductor device.
They are also called unipolar to contrast their single-carrier-type operation with
the dual-carrier-type operation of bipolar (junction) transistors (BJT).
•
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-7
Intro (1)
•
•
Solid state transistor is the main building block of microelectronics.
It performs two major functions used in electronic devices:
- amplifications (in analog)
- switching (in digital)
•
There are two basic types of solid state transistors BJT (bipolar junction
transistor) and FET (field effect transistor).
•
FET: electric filed is used to control the shape and hence the conductivity of the
channel of one type charge carrier (p or n) in semiconductor device.
They are also called unipolar to contrast their single-carrier-type operation with
the dual-carrier-type operation of bipolar (junction) transistors (BJT).
•
•
FET can be of two major types MOSFET (metal oxide semiconductor field
effect transistor (mostly used)), and JFET (junction field effect transistor).
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-8
Intro (2)
•
•
Metal Oxide Semiconductor Field Effect device was first solid state device
conceived (Lilienfield, 1928), however it took very long to develop a
successful commercial application of such devices. The first successful device
was fabricated in 1950, however the reliable commercial fabrication did not
start until decade later.
Today, the CMOS technology based on MOSFET is the dominant technology
in electronics.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-9
Intro (2)
•
•
Metal Oxide Semiconductor Field Effect device was first solid state device
conceived (Lilienfield, 1928), however it took very long to develop a
successful commercial application of such devices. The first successful device
was fabricated in 1950, however the reliable commercial fabrication did not
start until decade later.
Today, the CMOS technology based on MOSFET is the dominant technology
in electronics.
•
BJT devices were first introduced in 1948 and quickly became commercially
available. The first IC with logic gates and operational amplifiers that
appeared in early 1960s, were based on BJT technology. They are still widely
used, particularly in applications requiring high speed and high precision.
•
BJT device is based on pn-junction structure, while MOSFET is utilizing the
MOS capacitor structure.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-10
Metal Oxide Semiconductor
Field-Effect Transistors
(MOSFET)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-11
MOS Capacitor Structure
• Metal Oxide Semiconductor capacitor is
the core structure of the a Metal Oxide
Semiconductor Field Effect Transistor.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-12
MOS Capacitor Structure
• Metal Oxide Semiconductor capacitor is
the core structure of the a Metal Oxide
Semiconductor Field Effect Transistor.
• Consists of two electrodes and insulator
in between.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-13
MOS Capacitor Structure
• Metal Oxide Semiconductor capacitor is
the core structure of the a Metal Oxide
Semiconductor Field Effect Transistor.
• Consists of two electrodes and insulator
in between.
• First electrode (Gate): low-resistivity
material such as metal or polycrystalline
silicon.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-14
MOS Capacitor Structure
• Metal Oxide Semiconductor capacitor is
the core structure of the a Metal Oxide
Semiconductor Field Effect Transistor.
• Consists of two electrodes and insulator
in between.
• First electrode (Gate): low-resistivity
material such as metal or polycrystalline
silicon.
• Dielectric - Silicon dioxide: stable highquality electrical insulator between gate
and substrate.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-15
MOS Capacitor Structure
• Metal Oxide Semiconductor capacitor is
the core structure of the a Metal Oxide
Semiconductor Field Effect Transistor.
• Consists of two electrodes and insulator
in between.
• First electrode (Gate): low-resistivity
material such as metal or polycrystalline
silicon.
• Dielectric - Silicon dioxide: stable highquality electrical insulator between gate
and substrate.
• Second electrode (Substrate, Body): nor p-type semiconductor.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-16
MOS Capacitor Structure
• Metal Oxide Semiconductor capacitor is
the core structure of the a Metal Oxide
Semiconductor Field Effect Transistor.
• Consists of two electrodes and insulator
in between.
• First electrode (Gate): low-resistivity
material such as metal or polycrystalline
silicon.
• Dielectric - Silicon dioxide: stable highquality electrical insulator between gate
and substrate.
• Second electrode (Substrate, Body): nor p-type semiconductor.
• The semiconductor body has limited
supply of holes and electrons, and
substantial resistivity.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-17
MOS Capacitor Structure
• Metal Oxide Semiconductor capacitor is
the core structure of the a Metal Oxide
Semiconductor Field Effect Transistor.
• Consists of two electrodes and insulator
in between.
• First electrode (Gate): low-resistivity
material such as metal or polycrystalline
silicon.
• Dielectric - Silicon dioxide: stable highquality electrical insulator between gate
and substrate.
• Second electrode (Substrate, Body): nor p-type semiconductor.
• The semiconductor body has limited
supply of holes and electrons, and
substantial resistivity.
NJIT ECE271 Dr. Serhiy Levkov
The concentration of carriers
being dependant on voltage, the
capacitance of this structure
therefore is a nonlinear function
of voltage applied.
Chap 4-18
Substrate Conditions for Different Biases
We consider the conditions of the semiconductor region (p-type) below the gate
electrode under three different voltage bias: accumulation, depletion, inversion.
Those conditions are determined by VTN (0.5 - 2.0 V) the threshold voltage, at
which the electron inversion layer is just starting to form.
• Accumulation : VG<<VTN
The majority carriers (holes) accumulate
in a very thin layer below the negative
gate (like in capacitor)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-19
Substrate Conditions for Different Biases
We consider the conditions of the semiconductor region (p-type) below the gate
electrode under three different voltage bias: accumulation, depletion, inversion.
Those conditions are determined by VTN (0.5 - 2.0 V) the threshold voltage, at
which the electron inversion layer is just starting to form.
• Accumulation : VG<<VTN , VG<0
The majority carriers (holes) accumulate
in a very thin layer below the negative
gate (like in capacitor)
• Depletion: 0<VG<VTN
The small positive charge of the gate wipe
out the holes from the layer below
(depletes free carriers) creative a negative
charge of ionized atoms
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-20
Substrate Conditions for Different Biases
We consider the conditions of the semiconductor region (p-type) below the gate
electrode under three different voltage bias: accumulation, depletion, inversion.
Those conditions are determined by VTN (0.5 - 2.0 V) the threshold voltage, at
which the electron inversion layer is just starting to form.
• Accumulation : VG<<VTN
The majority carriers (holes) accumulate
in a very thin layer below the negative
gate (like in capacitor)
• Depletion: 0<VG<VTN
The small positive charge of the gate wipe
out the holes from the layer below
(depletes free carriers) creative a negative
charge of ionized atoms
• Inversion: VG>VTN
NJIT ECE271 Dr. Serhiy Levkov
The larger positive charge of the gate
attracts electrons whose concentration in
the very thin layer exceeds that of holes –
inversion of p-type into n-type.
Chap 4-21
Low-frequency C-V Characteristics for
MOS Capacitor on P-type Substrate
• MOS capacitance is non-linear
function of voltage.
• Total capacitance in any region is
dictated by the separation between
capacitor plates.
• Total capacitance can be modeled as
series combination of fixed oxide
capacitance and voltage-dependent
depletion layer capacitance.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-22
NMOS Transistor: Structure
A N-MOSFET is formed by adding two heavily doped n-type (n+ , about one of 100 of
silicon atoms is replaced with donor), regions to the MOS capacitor. The resulting
diffusions provide a supply of electrons that can rapidly form the inversion layer and easily
move under the gate, and also make terminals to apply a voltage and create a current in the
channel region.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-23
NMOS Transistor: Structure
A N-MOSFET is formed by adding two heavily doped n-type (n+ , about one of 100 of
silicon atoms is replaced with donor), regions to the MOS capacitor. The resulting
diffusions provide a supply of electrons that can rapidly form the inversion layer and easily
move under the gate, and also make terminals to apply a voltage and create a current in the
channel region.
• 4 device terminals:
Gate(G)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-24
NMOS Transistor: Structure
A N-MOSFET is formed by adding two heavily doped n-type (n+ , about one of 100 of
silicon atoms is replaced with donor), regions to the MOS capacitor. The resulting
diffusions provide a supply of electrons that can rapidly form the inversion layer and easily
move under the gate, and also make terminals to apply a voltage and create a current in the
channel region.
• 4 device terminals:
Gate(G)
Drain(D)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-25
NMOS Transistor: Structure
A N-MOSFET is formed by adding two heavily doped n-type (n+ , about one of 100 of
silicon atoms is replaced with donor), regions to the MOS capacitor. The resulting
diffusions provide a supply of electrons that can rapidly form the inversion layer and easily
move under the gate, and also make terminals to apply a voltage and create a current in the
channel region.
• 4 device terminals:
Gate(G)
Drain(D),
Source(S)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-26
NMOS Transistor: Structure
A N-MOSFET is formed by adding two heavily doped n-type (n+ , about one of 100 of
silicon atoms is replaced with donor), regions to the MOS capacitor. The resulting
diffusions provide a supply of electrons that can rapidly form the inversion layer and easily
move under the gate, and also make terminals to apply a voltage and create a current in the
channel region.
• 4 device terminals:
Gate(G)
Drain(D),
Source(S)
Body(B)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-27
NMOS Transistor: Structure
A N-MOSFET is formed by adding two heavily doped n-type (n+ , about one of 100 of
silicon atoms is replaced with donor), regions to the MOS capacitor. The resulting
diffusions provide a supply of electrons that can rapidly form the inversion layer and easily
move under the gate, and also make terminals to apply a voltage and create a current in the
channel region.
• 4 device terminals:
Gate(G)
Drain(D),
Source(S)
Body(B).
• Source and drain regions form
pn junctions with substrate.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-28
NMOS Transistor: Structure
A N-MOSFET is formed by adding two heavily doped n-type (n+ , about one of 100 of
silicon atoms is replaced with donor), regions to the MOS capacitor. The resulting
diffusions provide a supply of electrons that can rapidly form the inversion layer and easily
move under the gate, and also make terminals to apply a voltage and create a current in the
channel region.
• 4 device terminals:
Gate(G)
Drain(D),
Source(S)
Body(B).
• Source and drain regions form
pn junctions with substrate.
• vSB,= vS – vB , vDS = vD - vS and
vGS = vG - vS are typically
nonnegative during normal
operation.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-29
NMOS Transistor: Structure
A N-MOSFET is formed by adding two heavily doped n-type (n+ , about one of 100 of
silicon atoms is replaced with donor), regions to the MOS capacitor. The resulting
diffusions provide a supply of electrons that can rapidly form the inversion layer and easily
move under the gate, and also make terminals to apply a voltage and create a current in the
channel region.
• 4 device terminals:
Gate(G)
Drain(D),
Source(S)
Body(B).
• Source and drain regions form
pn junctions with substrate.
• vSB,= vS – vB , vDS = vD - vS and
vGS = vG - vS are always positive
during normal operation.
• vB <= vD and vB <= vS , to keep
pn junctions reverse biased.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-30
NMOS Transistor and Variable Resistor
•
•
A transistor is a three (or four)
terminal device, in which one
terminal controls the voltage or
current between other two
terminals
In certain way it is similar to a
variable resistor, in which the
movement of the middle terminal
controls the voltage.
+
+
-
NJIT ECE271 Dr. Serhiy Levkov
-
Chap 4-31
NMOS Transistor: Qualitative Behavior @ vDS =0
•
NJIT ECE271 Dr. Serhiy Levkov
VGS<<VTN (VGS <0): Two back to back
reverse biased pn junctions btw S and
D. Only small leakage current flows.
Chap 4-32
NMOS Transistor: Qualitative Behavior @ vDS =0
NJIT ECE271 Dr. Serhiy Levkov
•
VGS<<VTN (VGS <0): Two back to back
reverse biased pn junctions btw S and
D. Only small leakage current flows.
•
VGS<VTN (VGS >0): Depletion region
formed under gate merges with source
and drain depletion regions. No
current flows between source and
drain.
Chap 4-33
NMOS Transistor: Qualitative Behavior @ vDS =0
NJIT ECE271 Dr. Serhiy Levkov
•
VGS<<VTN (VGS <0): Two back to back
reverse biased pn junctions btw S and
D. Only small leakage current flows.
•
VGS<VTN (VGS >0): Depletion region
formed under gate merges with source
and drain depletion regions. No
current flows between source and
drain.
•
VGS>VTN: Channel is formed between
source and drain by electrons in
inversion layer. If VDS>0, finite iD
flows from drain to source.
•
iB=0 and iG=0.
Chap 4-34
NMOS Transistor: Qualitative Behavior @ vDS =0
Since the induced inversion layer is formed by electrons, it’s called N-channel
MOSFET.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-35
NMOS Transistor: Triode Region
Applying a small vDS creates a flow of electrons in the induced inversion layer between
source and drain - current iD (iD = iS , since iB=0 and iG=0).
v  small
DS
v 
i  Kn v V  DS  v
D
GS TN
2  DS





v
V
for 0  v
DS GS TN
where
Kn= Kn’W/L – the gain factor
Kn’=mnCox’’ (A/V2)
Cox’’=ox/Tox
 ox= oxide permittivity (F/cm)
Tox = oxide thickness (cm)
This is the triode region (linear region, ohmic mode).
MOSFET operates like a resistor, controlled by the gate voltage relative to both the
source and drain voltages.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-36
N-MOS Transistor: Triode Region
(derivation of the source-drain current)
Since currents iB and iG both are zero, and there is no path for drain current to escape: iS = iD.
To find it, we consider the transport of the charge. The linear density of the electron charge
at any point in the channel is:
Q '  W Cox ''(vox  VTN ) C / cm for vox  VTN ,
where Cox ''   ox / Tox  oxide capacitance per area,  ox  oxide permittivity(F/cm), Tox  oxide thickness (cm)
The voltage vox is the function of position x in the channel: vox  vGS  v(x). For inversion layer to
exist, should be vox > VTN , so Q’ = 0 until vox > VTN . At the source, vox = vGS and it decrease
to vox = vGS - vDS at the drain.
dv ( x)
The electron drift current is : i( x)  Q ' vx   W Cox ' ' (vox  VTN )(mn Ex ) , where E x  
dx
Combining everything:

L
0
i( x)dx  
vDS
0
i ( x)   m nCox ' 'W vGS  v( x)  VTN 
mnCox "W vGS  v( x)  VTN dv( x) ,
we get
dv( x)
dx
and integrating:
v 
v 


 vGS  VTN  DS  vDS  K n  vGS  VTN  DS 
2 
2 


W
where K n  K n'
, and K n'  m nCox''
L
iD  m nCox "
NJIT ECE271 Dr. Serhiy Levkov
W
L
Chap 4-37
Triode (a bit of history)
A triode is an electronic amplification device having three active electrodes.
most commonly it’s a vacuum tube with three elements: the filament (cathode),
the grid (controlling element), and the plate or anode. The triode vacuum tube
was the first electronic amplification device. It’s iv-characteristics was quite
linear.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-38
N-MOSFET: Triode Region Characteristics
• The expression for iD is quadratic in vDS
NJIT ECE271 Dr. Serhiy Levkov
v 
i  Kn v V  DS  v
D
GS TN
2  DS




Chap 4-39
N-MOSFET: Triode Region Characteristics
• The expression for iD is quadratic in vDS
with max reached at vDS = vGS - vTN = vOV
v 
i  Kn v V  DS  v
D
GS TN
2  DS




vDS
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-40
N-MOSFET: Triode Region Characteristics
• The expression for iD is quadratic in vDS
with max reached at vDS = vGS - vTN = vOV
• For small vDS << vGS - vTN , the
characteristics iD vs. vDS appear to be linear
(triode region, linear)
v 
i  Kn v V  DS  v
D
GS TN
2  DS




vDS
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-41
N-MOSFET: Triode Region Characteristics
• The expression for iD is quadratic in vDS
with max reached at vDS = vGS - vTN = vOV
• For small vDS << vGS - vTN , the
characteristics iD vs. vDS appear to be
linear (triode region, linear)
Under this condition, MOSFET
behaves like a
gate-source voltage-controlled
resistor between source and
drain,
i  Kn  v V  v  1 v
D
TN  DS Ron DS
 GS
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-42
N-MOSFET: Triode Region Characteristics
• The expression for iD is quadratic in vDS
with max reached at vDS = vGS - vTN = vOV
• For small vDS << vGS - vTN , the
characteristics iD vs. vDS appear to be
linear (triode region, linear)
Under this condition, MOSFET
behaves like a
gate-source voltage-controlled
resistor between source and
drain,
i  Kn  v V  v  1 v
D
TN  DS Ron DS
 GS
where on-resistance:
Ron 

NJIT ECE271 Dr. Serhiy Levkov
1
W
K n ' VGS VTN VDS 

L
v
DS 0
1
 Ron (V )
GS


W
K n '  V V 
L  GS TN 
Chap 4-43
MOSFET as Voltage-Controlled Resistor
Example: Voltage-Controlled Attenuator
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-44
MOSFET as Voltage-Controlled Resistor
Example: Voltage-Controlled Attenuator
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-45
MOSFET as Voltage-Controlled Resistor
Example: Voltage-Controlled Attenuator
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-46
MOSFET as Voltage-Controlled Resistor
Example: Voltage-Controlled Attenuator
v
vo  G(VGS )vs , G(VGS )  o 
vs
Ron
1


Ron  R 1 K R V

V
n  GS TN 
If Kn=500mA/V2, VTN=1V, R=2k and VGS = 1, 1.5, 2 V:
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-47
MOSFET as Voltage-Controlled Resistor
Example: Voltage-Controlled Attenuator
v
vo  G(VGS )vs , G(VGS )  o 
vs
Ron
1


Ron  R 1 K R V

V
n  GS TN 
If Kn=500mA/V2, VTN=1V, R=2k and VGS = 1, 1.5, 2 V:
G(VGS  1) 
1 500
mA
V
NJIT ECE271 Dr. Serhiy Levkov
1
2000  11 V

2
1
Chap 4-48
MOSFET as Voltage-Controlled Resistor
Example: Voltage-Controlled Attenuator
v
vo  G(VGS )vs , G(VGS )  o 
vs
Ron
1


Ron  R 1 K R V

V
n  GS TN 
If Kn=500mA/V2, VTN=1V, R=2k and VGS = 1, 1.5, 2 V:
G(VGS  1) 
1 500
mA
V
G(VGS  2) 
1 500
2000  11 V

2
mA
V
NJIT ECE271 Dr. Serhiy Levkov
1
2
1
1
2000   21 V
 0.5
Chap 4-49
MOSFET as Voltage-Controlled Resistor
Example: Voltage-Controlled Attenuator
v
vo  G(VGS )vs , G(VGS )  o 
Ron
1


Ron  R 1 K R V

V
n  GS TN 
vs
If Kn=500mA/V2, VTN=1V, R=2k and VGS = 1, 1.5, 2 V:
G(VGS  1) 
1 500
mA
V
G(VGS  2) 
1 500
2000  11 V

2
mA
V
G(VGS  1.5) 
1 500
2
1
1
2000   21 V
mA
V
NJIT ECE271 Dr. Serhiy Levkov
1
2
 0.5
1
2000  1.51 V
 0.667
To maintain triode region operation,
v v V
or
vo  V V
DS GS TN
GS TN
Chap 4-50
NMOS Transistor: inversion layer change
If we increase vDS , and it’s no more vDS << VGS - VTN = VOV (triode region limit), it
starts influencing the depth of induced inversion layer, for which we need VGS > VTN.
VOV - overdrive voltage
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-51
NMOS Transistor: inversion layer change
If we increase vDS , and it’s no more vDS << VGS - VTN = VOV (triode region limit), it
starts influencing the depth of induced inversion layer, for which we need VGS > VTN.
VOV - overdrive voltage
vDS = VOV - pinch-off voltage, saturation region begins
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-52
NMOS Transistor: Saturation Region
• When vDS increases above triode region
limit, channel region akmost
disappears, MOSFET also said to be
pinched-off.
• Current saturates at (almost) constant
value, independent of vDS.
What is the current in
saturation region?
v
 v V
DSAT GS TN
is also called
saturation or pinch-off voltage.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-53
NMOS Transistor: Saturation Region
Substituting vDS = vGS - VTN
into previous equation for
drain current, we get
• When vDS increases above triode region
limit, channel region akmost
disappears, MOSFET also said to be
pinched-off.
• Current saturates at (almost) constant
value, independent of vDS.
v
 v V
DSAT GS TN
is also called
saturation or pinch-off voltage.
NJIT ECE271 Dr. Serhiy Levkov
K' W
2
i  n  v V 
D
TN 
2 L  GS
for vDS  vGS VTN
• Saturation region operation
mostly used for analog
amplification.
Example here
Chap 4-54
NMOS Transistor: iv-characteristic
vGS  v(xpo ) VTN
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-55
NMOS Transistor: Region Summary
•
If vDS << VGS - VTN MOSFET is in linear
portion of the triode region
Triode
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-56
NMOS Transistor: Region Summary
•
•
NJIT ECE271 Dr. Serhiy Levkov
If vDS << VGS - VTN MOSFET is in linear
portion of the triode region
If vDS < VGS - VTN MOSFET is in
quadratic portion of the triode region
Chap 4-57
NMOS Transistor: Region Summary
•
•
•
NJIT ECE271 Dr. Serhiy Levkov
If vDS << VGS - VTN MOSFET is in linear
portion of the triode region
If vDS < VGS - VTN MOSFET is in
quadratic portion of the triode region
If vDS < VGS - VTN MOSFET is in
saturation region and current saturates at
(almost) constant value, independent of vDS.
Discuss how to build the iv graph
Chap 4-58
Transconductance of a MOS Device
• Transconductance is the important characteristics that
relates the change in drain current to a change in gatedi
source voltage
D
gm 
dv
GS Qpt

NJIT ECE271 Dr. Serhiy Levkov
Chap 4-59
Transconductance of a MOS Device
• Transconductance is the important characteristics that
relates the change in drain current to a change in gatedi
source voltage
D
gm 
dv
GS Qpt
• Taking the derivative of the expression for the drain

current in saturation region,
2I
W
D
gm  Kn' (V
V )
GS
TN
L
V
V
GS TN

NJIT ECE271 Dr. Serhiy Levkov
Chap 4-60
Transconductance of a MOS Device
• Transconductance is the important characteristics that
relates the change in drain current to a change in gatedi
source voltage
D
gm 
dv
GS Qpt
• Taking the derivative of the expression for the drain

current in saturation region,
2I
W
D
gm  Kn' (V
V )
GS
TN
L
V
V
GS TN
• The larger
the device transconductance, the more gain we

can expect from the amplifier that uses the transistor.
• Transconductance is inverse to the Ron defined earlier and
slightly differently.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-61
Channel-Length Modulation
•
NJIT ECE271 Dr. Serhiy Levkov
On the previous iv-characteristics, the
saturation part was horizontal (the current
was constant, as vDS increases). However, it’s
not exactly so.
Chap 4-62
Channel-Length Modulation
•
•
NJIT ECE271 Dr. Serhiy Levkov
On the previous iv-characteristics, the
saturation part was horizontal (the current
was constant, as vDS increases). However, it’s
not exactly so.
As vDS increases above vDSAT , length of
depleted channel beyond pinch-off point, DL,
increases and actual L decreases.
Chap 4-63
Channel-Length Modulation
•
•
•
On the previous iv-characteristics, the
saturation part was horizontal (the current
was constant, as vDS increases). However, it’s
not exactly so.
As vDS increases above vDSAT , length of
depleted channel beyond pinch-off point, DL,
increases and actual L decreases.
Since L is in denominator of the current
expression, it compensate slightly the general
increase of resistivity, which normally makes
the curve flat.
K' W
2
i  n  v V 
D
TN 
2 L  GS
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-64
Channel-Length Modulation
•
•
•
•
K' W
2
i  n  v V 
D
TN 
2 L  GS
NJIT ECE271 Dr. Serhiy Levkov
On the previous iv-characteristics, the
saturation part was horizontal (the current
was constant, as vDS increases). However, it’s
not exactly so.
As vDS increases above vDSAT , length of
depleted channel beyond pinch-off point, DL,
increases and actual L decreases.
Since L is in denominator of the current
expression, it compensate slightly the general
increase of resistivity, which normally makes
the curve flat.
As a result, iD increases slightly with vDS
instead of being constant and we can rewrite
equation in the form:
K 'W
2

i  n  v V  1v

DS
D
TN
GS



2 L
Chap 4-65
Channel-Length Modulation
•
•
•
•
On the previous iv-characteristics, the
saturation part was horizontal (the current
was constant, as vDS increases). However, it’s
not exactly so.
As vDS increases above vDSAT , length of
depleted channel beyond pinch-off point, DL,
increases and actual L decreases.
Since L is in denominator of the current
expression, it compensate slightly the general
increase of resistivity, which normally makes
the curve flat.
As a result, iD increases slightly with vDS
instead of being constant and we can rewrite
equation in the form:
K 'W
2

i  n  v V  1v

DS
D
TN
GS



2 L
where  is the channel length modulation
parameter, depends on manufacturing and L.
NJIT ECE271 Dr. Serhiy Levkov
Va – Early voltage.
Chap 4-66
Enhancement and Depletion Mode MOSFETS
• The MOSFETS transistors can be of two types:
enhancement mode when VTN > 0
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-67
Enhancement and Depletion Mode MOSFETS
• The MOSFETS transistors can be of two types:
enhancement mode when VTN > 0
depletion mode when VTN < 0
(the NMOS transistors considered so far were of enhancement type.)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-68
Enhancement and Depletion Mode MOSFETS
• The MOSFETS transistors can be of two types:
enhancement mode when VTN > 0
depletion mode when VTN < 0
(the NMOS transistors considered so far were of enhancement type.)
• The depletion mode devices are fabricated by ion implantation process
used to form a built-in n-type channel in device to connect source and
drain by a resistive channel.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-69
Enhancement and Depletion Mode MOSFETS
• The MOSFETS transistors can be of two types:
enhancement mode when VTN > 0
depletion mode when VTN < 0
(the NMOS transistors considered so far were of enhancement type.)
• The depletion mode devices are fabricated by ion implantation process
used to form a built-in n-type channel in device to connect source and
drain by a resistive channel.
• In such case, a non-zero drain current exists for vGS=0, and a
negative vGS required to turn device off.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-70
Enhancement and Depletion Mode MOSFETS
• The MOSFETS transistors can be of two types:
enhancement mode when VTN > 0
depletion mode when VTN < 0
(the NMOS transistors considered so far were of enhancement type.)
• The depletion mode devices are fabricated by ion implantation process
used to form a built-in n-type channel in device to connect source and
drain by a resistive channel.
• In such case, a non-zero drain current exists for vGS=0, and a
negative vGS required to turn device off.
Depletion mode – because negative
voltage has to be applied to the gate to
deplete the n-type channel and
eliminate the current path between the
source and the drain.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-71
Output and Transfer Characteristics of MOSFETS
• A MOSFET has one output variable – the drain-source current , that
depends on two input variables – drain-source voltage and gate-source
voltage (VGS is usually is a control variable).
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-72
Output and Transfer Characteristics of MOSFETS
• A MOSFET has one output variable – the drain-source current , that depends
on two input variables – drain-source voltage and gate-source voltage (VGS is
usually is a control variable).
• Two types of iv-curves are used to describe a MOSFET device fully:
output (drain) curve (DS current vs. DS voltage for a fixed GS voltage)
(the earlier considered characteristics were drain curves)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-73
Output and Transfer Characteristics of MOSFETS
• A MOSFET has one output variable – the drain-source current , that depends
on two input variables – drain-source voltage and gate-source voltage (VGS is
usually is a control variable).
• Two types of iv-curves are used to describe a MOSFET device fully:
output (drain) curve (DS current vs. DS voltage for a fixed GS voltage)
(the earlier considered characteristics were drain curves)
transfer curve (DS current vs. GS voltage for a fixed DS voltage, f.i. sat.)
Curves show that the enhancement mode device turns on at
VGS = 2, while the depletion mode device turns on at VGS = -2.
NJIT ECE271 Dr. Serhiy Levkov
Example here
Chap 4-74
Body Effect or Substrate Sensitivity
So far it was assumed that the source-bulk voltage vSB , is zero, which means that a
MOSFET is a three terminal device. Quite often vSB , especially in ICs is not zero..
• Non-zero vSB changes threshold voltage.
• This is called substrate sensitivity and is
modeled by


V V g  v 2  2 
TN TO  SB
F
F 
where
VTO - zero substrate bias for VTN (V)
g body-effect parameter m,determines
V
the intensity of the body effect
2FF - surface potentialparameter (V),
typically 0.6V.

NJIT ECE271 Dr. Serhiy Levkov
Chap 4-75
NMOS Summary (output characteristics)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-76
PMOS Transistors Structure (Enhancement-Mode)
0
0
ID
NMOS
PMOS
•
p-type source and drain regions in
n-type substrate.
NJIT ECE271 Dr. Serhiy Levkov
•
n-type source and drain regions in
p-type substrate.
Chap 4-77
PMOS Transistors Structure (Enhancement-Mode)
0
0
ID
NMOS
PMOS
•
•
P-type source and drain regions in
n-type substrate.
vGS < 0 required to create p-type
inversion layer in channel region
NJIT ECE271 Dr. Serhiy Levkov
•
•
N-type source and drain regions in
p-type substrate.
vGS > 0 required to create n-type
inversion layer in channel region
Chap 4-78
PMOS Transistors Structure (Enhancement-Mode)
0
0
ID
NMOS
PMOS
•
•
•
P-type source and drain regions in
n-type substrate.
vGS < 0 required to create p-type
inversion layer in channel region
For current flow, vGS<vTP
NJIT ECE271 Dr. Serhiy Levkov
•
•
•
N-type source and drain regions in
p-type substrate.
vGS > 0 required to create n-type
inversion layer in channel region
For current flow, vGS > vTN
Chap 4-79
PMOS Transistors Structure (Enhancement-Mode)
0
0
ID
NMOS
PMOS
•
•
•
•
P-type source and drain regions in
n-type substrate.
vGS < 0 required to create p-type
inversion layer in channel region
For current flow, vGS<vTP
To maintain reverse bias on diodes
of source-substrate and drainsubstrate junctions:
vSB < 0 and vDB < 0
NJIT ECE271 Dr. Serhiy Levkov
•
•
•
•
N-type source and drain regions in
p-type substrate.
vGS > 0 required to create n-type
inversion layer in channel region
For current flow, vGS > vTN
To maintain reverse bias on the
diodes of source-substrate and
drain-substrate junctions:
vSB >0 and vDB >0
Chap 4-80
Enhancement-Mode PMOS Transistors:
Output Characteristics
•
NJIT ECE271 Dr. Serhiy Levkov
For the PMOS transistor, all parameters and
behavior are inverse of NMOS transistor.
Chap 4-81
Enhancement-Mode PMOS Transistors:
Output Characteristics
•
•
NJIT ECE271 Dr. Serhiy Levkov
For the PMOS transistor, all parameters and
behavior are inverse of NMOS transistor.
Thus the output characteristics of PMOS
are the complete inverse of those of NMOS
Chap 4-82
Enhancement-Mode PMOS Transistors:
Output Characteristics
•
•
•
NJIT ECE271 Dr. Serhiy Levkov
For the PMOS transistor, all parameters and
behavior are inverse of NMOS transistor.
Thus the output characteristics of PMOS
are the complete inverse of those of NMOS
Often, they are shown in the inverted scale
and then they look very similar to the
characteristics of NMOS
Chap 4-83
Enhancement-Mode PMOS Transistors:
Output Characteristics
•
•
•
•
For the PMOS transistor, all parameters and
behavior are inverse of NMOS transistor.
Thus the output characteristics of PMOS
are the complete inverse of those of NMOS
Often, they are shown in the inverted scale
and then they look very similar to the
characteristics of NMOS
For VGS VTP , transistor is off (note
that on the diagram it’s vSG = - vGS).

NJIT ECE271 Dr. Serhiy Levkov
Chap 4-84
Enhancement-Mode PMOS Transistors:
Output Characteristics
•
•
•
•
•
NJIT ECE271 Dr. Serhiy Levkov
For the PMOS transistor, all parameters and
behavior are inverse of NMOS transistor.
Thus the output characteristics of PMOS
are the complete inverse of those of NMOS
Often, they are shown in the inverted scale
and then they look very similar to the
characteristics of NMOS
For VGS VTP , transistor is off (note
that on the diagram it’s vSG = - vGS).

For more negative vGS, drain current
increases in magnitude.
Chap 4-85
Enhancement-Mode PMOS Transistors:
Output Characteristics
•
•
•
•
•
•
NJIT ECE271 Dr. Serhiy Levkov
For the PMOS transistor, all parameters and
behavior are inverse of NMOS transistor.
Thus the output characteristics of PMOS
are the complete inverse of those of NMOS
Often, they are shown in the inverted scale
and then they look very similar to the
characteristics of NMOS
For VGS VTP , transistor is off (note
that on the diagram it’s vSG = - vGS).

For more negative vGS, drain current
increases in magnitude.
PMOS is in triode region for small
(absolute) values of VDS and in
saturation for larger values (note that
on the diagram it’s more negative to
the right).
Chap 4-86
NMOS Summary (model)
For the enhancement-mode NMOS transistor, VTN > 0. For the depletion-mode NMOS, VTN < 0.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-87
PMOS Summary (model)
For the enhancement-mode PMOS transistor, VTP < 0. For the depletion-mode PMOS, VTP > 0.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-88
NMOS and PMOS Summary (regions of operation)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-89
NMOS and PMOS Summary (terminal voltages)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-90
Short Summary of MOSFET (1)
•
A MOSFET is a 3 terminal (Gate, Source, Drain) or 4 terminal (Gate, Source, Drain,
Body) electronic device -- it has input (usually vGS) and output (usually iD).
•
The basic function of all transistors - an input voltage is used to provide the change in
the output current (or voltage):
– the change in output can be much bigger then the change in the input - amplifier
– the change in output can be to turn it on or off – digital gate
•
There are two types of MOSFET : PMOS and NMOS
•
•
Both types exist in two modes: Enhancement and Depletion.
NMOS enhancement mode: the output current (the inversion channel) may exist only
when input (vGS ) is positive (>0).
NMOS depletion mode: the output current (the inversion channel) may exist when input
(vGS ) is zero, requires to apply vGS <0 to shut the current).
•
•
PMOS is pretty much the complete inverse of NMOS.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-91
Short Summary of MOSFET (2)
NMOS
PMOS
Body: p-substrate
Source, Drain: n+
Inversion (conduction) layer: n
Body: n-substrate
Source, Drain: p+
Inversion (conduction) layer: p
E-NMOS
D-NMOS
E-PMOS
D-PMOS
Channel
(drain current
exists
when vGS > 0)
Channel
(drain current
exists
when vGS = 0)
Channel
(drain current
exists
when vGS < 0)
Channel
(drain current
exists
when vGS = 0)
VTN > 0
VTN <= 0
VTP < 0
VTP >= 0
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-92
Short Summary of MOSFET (3)
•
•
•
MOSFET is a symmetrical device – D and S are interchangeable.
MOSFET is fully described by two characteristics:
- input-output or transfer characteristic: (iD - vGS or vDS - vGS )
- output characteristic: (iD – vDS )
All four types of MOSFET may operate in three regions:
- cutoff : output current is 0
- triode: output current almost linearly depends on output voltage vDS (like in resistor)
- saturation: output current almost does not depend on DS voltage vDS (like in diode)
Transfer characteristics
NJIT ECE271 Dr. Serhiy Levkov
Output characteristics
Chap 4-93
MOSFET Circuit Symbols
•
•
•
•
NJIT ECE271 Dr. Serhiy Levkov
(g) and (i) are the most
commonly used symbols in VLSI
logic design.
MOS devices are symmetric.
In NMOS, n+ region at higher
voltage is the drain.
In PMOS p+ region at lower
voltage is the drain
Chap 4-94
MOSFET Analysis
• Depending on the type of application, a MOSFET may be put into one of three
regions of operation by setting its operating Q-point
.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-95
MOSFET Analysis
• Depending on the type of application, a MOSFET may be put into one of three
regions of operation by setting its operating Q-point.
• For binary logic application the transistor acts like an “on-off” switch and the
Q-point is set in ether cut-off region (“off”) or in the triode region (“on”) for the
output characteristic or at the ends of transfer characteristic.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-96
MOSFET Analysis
• Depending on the type of application, a MOSFET may be put into one of three
regions of operation by setting its operating Q-point.
• For binary logic application the transistor acts like an “on-off” switch and the
Q-point is set in ether cut-off region (“off”) or in the triode region (“on”) for the
output characteristic or at the ends of transfer characteristic.
• For amplifier application, the Q-point is set in the saturation region for the
output characteristic or in the middle (high) point of the transfer characteristic
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-97
MOSFET Analysis: logic inverter example
• For the low values of input vGS (binary 0) the
MOSFET is off, iD =0 and vDS = vout = 5V 
binary 1.
=0
=5
=low
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-98
MOSFET Analysis: logic inverter example
•
• For vGS =5V (binary 1) the MOSFET is on, iD is
high, and the output voltage vDS = vout = 0.65V 
binary 0.
NJIT ECE271 Dr. Serhiy Levkov
=high
=0.6
=5
Chap 4-99
MOSFET Analysis: logic inverter example
• For the low values of input vGS (binary 0) the
MOSFET is off, iD =0 and vDS = vout = 5V 
binary 1.
• For vGS =5V (binary 1) the MOSFET is on, iD is
high, and the output voltage vDS = vout = 0.65V 
binary 0.
NJIT ECE271 Dr. Serhiy Levkov
=0
=high
=5
=0.6
=low
=5
Chap 4-100
MOSFET Analysis: amplifier example
• For the amplifier, the Q-point created by
vGS = 2.5V is located at the high slope region
of transfer characteristic and at the saturation
region of the 2.5V curve.
=2. 5
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-101
MOSFET Analysis: amplifier example
• For the amplifier, the Q-point created by
vGS = 2.5V is located at the high slope region
of transfer characteristic and at the saturation
region of the 2.5V curve.
• A small AC signal is added to vary the gate
voltage about vGS = 2.5V, which causes the
drain current to change significantly and
amplified replica of the input appears at the
drain.
NJIT ECE271 Dr. Serhiy Levkov
=2. 5
Chap 4-102
MOSFET Analysis: load line example
• From KVL for the right loop:
vDD - vDS - iD RD = 0  iD = (vDD - vDS )/RD
• Setting two different values for vDS (5V and
3V for example) two points can be obtained
and the load line drawn.
NJIT ECE271 Dr. Serhiy Levkov
Thevenin
equivalent
Nonlinear
element
Chap 4-103
MOSFET Analysis: load line example
• From KVL for the right loop:
vDD - vDS - iD RD = 0  iD = (vDD - vDS )/RD
• Setting two different values for vDS (5V and
3V for example) two points can be obtained
and the load line drawn.
• Intersection with the transistor iv-curve
gives the Q-point, which, of course, depends
on the input vGS.
Thevenin
equivalent
Nonlinear
element
Conclusion
• The same device in the similar circuits may
behave differently depending on the
‘biasing‘ – DC voltages applied to different
terminals of MOSFET. The ‘signal’ then, is
actually comprised of relatively small
changes in the DC current and/or voltage
bias.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-104
Bias Analysis Approach
• The previous examples shows the importance of biasing for the desired
operation of MOSFET.
• Because of nonlinearity of characteristics and substantial difference in
operation region equations (different equations used), iterative approach is
used:
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-105
Bias Analysis Approach
• The previous examples shows the importance of biasing for the desired
operation of MOSFET.
• Because of nonlinearity of characteristics and substantial difference in
operation region equations (different equations used), iterative approach is
used:
• Assume an operation region (generally the saturation region)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-106
Bias Analysis Approach
• The previous examples shows the importance of biasing for the desired
operation of MOSFET.
• Because of nonlinearity of characteristics and substantial difference in
operation region equations (different equations used), iterative approach is
used:
• Assume an operation region (generally the saturation region)
• Use circuit analysis to find VGS (left, input loop)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-107
Bias Analysis Approach
• The previous examples shows the importance of biasing for the desired
operation of MOSFET.
• Because of nonlinearity of characteristics and substantial difference in
operation region equations (different equations used), iterative approach is
used:
• Assume an operation region (generally the saturation region)
• Use circuit analysis to find VGS (left, input loop)
• Use VGS to calculate ID, and ID to find VDS (right, output loop)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-108
Bias Analysis Approach
• The previous examples shows the importance of biasing for the desired
operation of MOSFET.
• Because of nonlinearity of characteristics and substantial difference in
operation region equations (different equations used), iterative approach is
used:
•
•
•
•
•
Assume an operation region (generally the saturation region)
Use circuit analysis to find VGS (left, input loop)
Use VGS to calculate ID, and ID to find VDS (right, output loop)
Check validity of operation region assumptions
Change assumptions and analyze again if required.
NOTE : An enhancement-mode device with VDS = VGS is always in saturation.
Why? For pinch off: VDS >= VGS - VTN . If VDS = VGS , then VDS >= VDS - VTN , or VTN >= 0, which
is always true for E-MOS device.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-109
Bias Analysis 1- Constant GS Voltage Biasing (1)
Problem: Find Q-pt (ID, VDS , VGS)
without and with the channel-length
modulation (   0 and   0.02V 1 ).
Approach: Assume operation
region, find Q-point, check to see if
result is consistent with operation
region.
Do this example on the board
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-110
Bias Analysis 1- Constant GS Voltage Biasing (1)
Problem: Find Q-pt (ID, VDS , VGS)
without and with the channel-length
modulation (   0 and   0.02V 1 ).
Approach: Assume operation
region, find Q-point, check to see if
result is consistent with operation
region.
Assumption:
1. Transistor is saturated.
2. IG=IB=0.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-111
Bias Analysis: Ex.1- Constant GS Voltage Biasing (1)
Problem: Find Q-pt (ID, VDS , VGS)
without and with the channel-length
modulation (   0 and   0.02V 1 ).
Approach: Assume operation
region, find Q-point, check to see if
result is consistent with operation
region.
Analysis:
Simplify circuit with Thevenin
transformation to find VEQ and REQ for
gate-bias voltage.
Assumption:
1. Transistor is saturated.
2. IG=IB=0.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-112
Bias Analysis 1- Constant GS Voltage Biasing (1)
Problem: Find Q-pt (ID, VDS , VGS)
without and with the channel-length
modulation (   0 and   0.02V 1 ).
Approach: Assume operation
region, find Q-point, check to see if
result is consistent with operation
region.
Analysis:
Simplify circuit with Thevenin
transformation to find VEQ and REQ for
gate-bias voltage.
Find VGS from the input loop, and then
use this to find ID.
Assumption:
1. Transistor is saturated.
2. IG=IB=0.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-113
Bias Analysis 1- Constant GS Voltage Biasing (1)
Problem: Find Q-pt (ID, VDS , VGS)
without and with the channel-length
modulation (   0 and   0.02V 1 ).
Approach: Assume operation
region, find Q-point, check to see if
result is consistent with operation
region.
Assumption:
1. Transistor is saturated.
2. IG=IB=0.
NJIT ECE271 Dr. Serhiy Levkov
Analysis:
Simplify circuit with Thevenin
transformation to find VEQ and REQ for
gate-bias voltage.
Find VGS from the input loop, and then
use this to find ID.
With ID, we can then calculate VDS
using the output loop
Chap 4-114
Bias Analysis 1- Constant GS Voltage Biasing (1)
The left (input) loop. Since IG=0:
V
I R
V
 0 V
V
 3V
EQ G EQ GS
GS
EQ
Then, from the transistor equation:
2
Kn 

V
I 
V 
D 2  GS TN 


 2510 6 

 mA




3 12 V2  50 mA
2
V2
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-115
Bias Analysis 1- Constant GS Voltage Biasing (1)
The right (output) loop:
V
V
The left (input) loop. Since IG=0:
DD
DS
 I R V
0
D D DS
10V  (50uA)(100K )  5.00 V
Check:VDS>VGS-VTN. Hence saturation
region assumption is correct.
V
I R
V
 0 V
V
 3V Q-pt: (50.0 mA, 5.0 V) with VGS= 3.0V
EQ G EQ GS
GS
EQ
Then, from the transistor equation:
2
Kn 

V
I 
V 
D 2  GS TN 


 2510 6 

 mA




3 12 V2  50 mA
2
V2
NJIT ECE271 Dr. Serhiy Levkov
Discussion.
The obtained result is proportional to K and
to the square of VTN , thus Q-pt. is quite
sensitive to the parameter fluctuation of the
device, so this circuit is not very used.
Chap 4-116
Bias Analysis 1- Constant GS Voltage Biasing (2)
Now let’s repeat the same problem taking
into account channel length modulation.
K 
2 

I  n V V  1 V 
D 2  GS TN  
DS 
V V
I R
DS DD D D
(25106 )
210.02 V 
V 10V (100K)
31

  
DS

DS
2
 4.55 V
(25106 )
I 
312 10.02 (4.55) 54.5 mA

D
2
Check:VDS>VGS-VTN. Hence
saturation region assumption is
correct.
Q-pt: (54.5 mA, 4.55 V) with
VGS= 3.00 V
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-117
Bias Analysis 1- Constant GS Voltage Biasing (2)
Now let’s repeat the same problem taking
into account channel length modulation.
K 
2 

I  n V V  1 V 
D 2  GS TN  
DS 
V V
I R
DS DD D D
(25106 )
210.02 V 
V 10V (100K)
31

  
DS

DS
2
 4.55 V
(25106 )
I 
312 10.02 (4.55) 54.5 mA

D
2
Check:VDS>VGS-VTN. Hence
saturation region assumption is
correct.
Q-pt: (54.5 mA, 4.55 V) with
VGS= 3.00 V
NJIT ECE271 Dr. Serhiy Levkov
Discussion.
The bias levels have changed by
about 10%. Typically, component
values will vary more than this, so
there is little value in including 
effects in most circuits.
Chap 4-118
Bias Analysis 1- Constant GS Voltage Biasing (3)
Load Line Analysis.
Problem: Find Q-pt (ID, VDS , VGS)
Approach: Find an equation for the
load line. Use this to find Q-pt at
intersection of load line with device
characteristic.
Assumptions:
1. IG=IB=0.
Do we need assumption for the
transistor region of operation?
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-119
Bias Analysis 1- Constant GS Voltage Biasing (3)
Load Line Analysis.
Problem: Find Q-pt (ID, VDS , VGS)
Approach: Find an equation for the
load line. Use this to find Q-pt at
intersection of load line with device
characteristic.
Assumptions:
1. IG=IB=0.
2. No need for region assumption,
will find solution directly.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-120
Bias Analysis 1- Constant GS Voltage Biasing (3)
Load Line Analysis.
Problem: Find Q-pt (ID, VDS , VGS)
Approach: Find an equation for the
load line. Use this to find Q-pt at
intersection of load line with device
characteristic.
Analysis: First, simplify circuit with
Thevenin transformation to find VEQ
and REQ for gate-bias voltage
Assumptions:
1. IG=IB=0.
2. No need for region assumption,
will find solution directly.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-121
Bias Analysis 1- Constant GS Voltage Biasing (3)
Load Line Analysis.
Problem: Find Q-pt (ID, VDS , VGS)
Approach: Find an equation for the
load line. Use this to find Q-pt at
intersection of load line with device
characteristic.
Assumptions:
1. IG=IB=0.
2. No need for region assumption,
will find solution directly.
NJIT ECE271 Dr. Serhiy Levkov
Analysis: First, simplify circuit with
Thevenin transformation to find VEQ
and REQ for gate-bias voltage
The left (input) loop. Since IG=0:
V
I R
V
0 
EQ G EQ GS
V
V
 3V
GS
EQ
Chap 4-122
Bias Analysis 1- Constant GS Voltage Biasing (3)
Load Line Analysis.
From the KVL for the right loop, load line
becomes

V
 I R V
DD D D DS
10 I 100K V
D
DS
@VDS=0, ID=100uA, @ID=0, VDS=10V

Plotting on device characteristic yields
Q-pt at intersection with VGS = 3V
device curve.
NJIT ECE271 Dr. Serhiy Levkov
Check: The load line approach agrees with
previous calculation.
Q-pt: (50.0 mA, 5.00 V) with VGS= 3.00 V
Discussion: Q-pt is clearly in the saturation
region. Graphical load line is good visual
aid to see device operating region.
Chap 4-123
Bias Analysis 2 - Four-Resistor Biasing (1)
Analysis: First, simplify circuit, split
VDD into two equal-valued sources and
apply Thevenin transformation to find
VEQ and REQ for gate-bias voltage
Problem: Find Q-pt (ID, VDS)
Approach: Assume operation region,
find Q-point, check to see if result is
consistent with operation region
Assumption: Transistor is saturated,
IG=IB=0
Do this example on the board
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-124
Bias Analysis 2 - Four-Resistor Biasing (1)
Left loop. Since IG=0,
VEQ  VGS  I D RS  0
Kn
VGS  VTN 2 RS
2



25106 3.910 4 
VEQ  VGS 

4 V  
GS



2
2
V 1
GS 





V 2 0.05V  7.21 0
GS
GS
NJIT
 ECE271 Dr. Serhiy Levkov
Chap 4-125
Bias Analysis 2 - Four-Resistor Biasing (1)
Solution:
V  2.71V,  2.66V
GS
If VGS= -2.71 , VGS<VTN and
MOSFET will be cut-off. Thus
V 2.66V
GS
and ID= 34.4 mA

Left loop. Since IG=0,
VEQ  VGS  I D RS  0
Kn
VGS  VTN 2 RS
2



25106 3.910 4 
VEQ  VGS 

4 V  
GS



2
2
V 1
GS 





V 2 0.05V  7.21 0
GS
GS
NJIT
 ECE271 Dr. Serhiy Levkov
Chap 4-126
Bias Analysis 2 - Four-Resistor Biasing (1)
Solution:
V  2.71V,  2.66V
GS
If VGS= -2.71 , VGS<VTN and
MOSFET will be cut-off. Thus
V 2.66V
GS

VEQ  VGS  I D RS  0
VEQ
K
 VGS  n VGS  VTN 2 RS
2



25106 3.910 4 

4 V  
GS



2
V 2 0.05V  7.21 0
GS
GS
NJIT
 ECE271 Dr. Serhiy Levkov
Right loop.
V
Left loop. Since IG=0,
DD
V
2
V 1
GS 





and ID= 34.4 mA
DS
 I (R  R ) V
0 
D D S
DS
 6.08V
We have VDS >VGS-VTN .
Hence saturation region assumption is
correct.
Q-pt: (34.4 mA, 6.08 V) with
VGS= 2.66 V
Chap 4-127
Bias Analysis 2 - Four-Resistor Biasing (2)
Body Effect
V V g ( V 2  2 )
TN TO
SB
F
F
In previous example, the body terminal
was connected to the source, so VSB = 0.
Now let’s consider the case with V  0
SB
V 10.5( V 0.6  0.6)
TN
SB


6
2510 

I '
D

V  I R  22,000I
SB D S
D

NJIT ECE271 Dr. Serhiy Levkov

2
2
V V 
GS TN 





Iterative solution can be found by
following steps:
•
V V  I R  622,000I
GS EQ D S
D




•
•
•
Estimate value of ID and use it to
find VGS and VSB
Use VSB to calculate VTN
Find ID’ using last equation
If ID’ is not same as original ID
estimate, start again.
Chap 4-128
Bias Analysis 2 - Four-Resistor Biasing (2)
Body Effect
The iteration sequence leads to ID= 88.0 mA, VTN = 1.41 V,
V V
I (R R )1040,000I 6.48V
DS DD D D S
D

We obtained that VDS>VGS-VTN. Hence saturation region assumption is
correct.
Q-pt: (88.0 mA, 6.48 V)
Check: VDS > VGS - VTN, therefore still in active region.
Discussion: Body effect has decreased current by 12% and increased
threshold voltage by 40%.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-129
Bias Analysis 3 – Two Resistor (saturation)
Assumption:
1. IG=IB=0.
2.Transistor is saturated since VDS=VGS
Do this example on the board
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-130
Bias Analysis 3 – Two Resistor (saturation)
Assumption:
1. IG=IB=0.
2.Transistor is saturated since VDS=VGS
Analysis. No need for input loop: VDS=VGS
V V
I R
DS DD D D
Output loop:

NJIT ECE271 Dr. Serhiy Levkov
Chap 4-131
Bias Analysis 3 – Two Resistor (saturation)
K
2
V V
V
 n V V  RD
DD 2  GS TN 
GS
DS
V
GS



 2.610 4 104 






 V
 3.3 

 GS
2
1

2
V  0.769V,  2.00V
GS
Assumption:
1. IG=IB=0.
2.Transistor is saturated since VDS=VGS
Analysis. No need for input loop: VDS=VGS
V V
I R
DS DD D D
Output loop:

NJIT ECE271 Dr. Serhiy Levkov
If VGS= -0.769 , VGS<VTN and
MOSFET will be cut-off. Thus
V V
 2.00V and ID= 130 mA
GS
DS
We obtained VDS>VGS-VTN. Hence
saturation region assumption is
correct.
Q-pt: (130 mA, 2.00 V)
Chap 4-132
Discussion of Four and Two-Resistor Biasing
Four resistor
• Provide excellent bias for transistors in discrete circuits.
• Stabilize bias point with respect to device parameter and temperature
variations using negative feedback.
• Use single voltage source to supply both gate-bias voltage and drain
current.
• Generally used to bias transistors in saturation region in amplifier circuits.
Two-resistor
• Uses lesser components that four-resistor biasing and also isolates drain
and gate terminals.
• Feedback mechanism.
Suppose, for some reason ID begins to increase. From VEQ  VGS  I D RS  0 it follows
that VGS has to decrease, since Vg is constant. This will decrease the current ID due to
current equation, thus restoring the existing state.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-133
Bias Analysis 4 – One Resistor (triode)
Assumption:
1. IG=IB=0
2. Transistor is saturated.
Analysis.
Left loop:
VGS=VDD=4 V
I  250 mA (41)2 1.13mA
D 2 V2
NJIT ECE271 Dr. Serhiy Levkov

Do this example on the board
Chap 4-134
Bias Analysis 4 – One Resistor (triode)
Right loop: V  I R V
DD D D DS
V
V
DS
DS
 41600I
D
 2.19V
Assumption:
1. IG=IB=0
2. Transistor is saturated.
Analysis.
Left loop:
VGS=VDD=4 V
I  250 mA (41)2 1.13mA
D 2 V2
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-135
Bias Analysis 4 – One Resistor (triode)
Right loop: V  I R V
DD D D DS
V
V
DS
DS
 41600I
D
 2.19V
We obtained VDS<VGS -VTN. Hence,
saturation region assumption is incorrect.
Assume the triode region and use the
triode region equation:
Assumption:
1. IG=IB=0
2. Transistor is saturated.
VDS  4  1600  250
Analysis.
VDS  2.3, 8.7 = 2.3V
Left loop:
VGS=VDD=4 V
I  250 mA (41)2 1.13mA
D 2 V2
NJIT ECE271 Dr. Serhiy Levkov
mA
V2
(4  1 
VDS
)VDS
2
and ID=1.06 mA
We obtained VDS<VGS -VTN, transistor is in
triode region
Q-pt:(1.06 mA, 2.3 V)
Chap 4-136
Bias Analysis 5 - Two-Resistor, PMOST
Right loop: 15V  (220k)I VDS  0
D
2
15V  (220k) 50 m A V  2  V  0
GS
2 V2  GS 
V  0.369V, 3.45V
GS
Since VGS= -0.369 V is more than VTP= -2 V,
we take VGS = -3.45 V
Assumption:
1. IG=IB=0
2. Transistor is saturated: VDS=VGS
Analysis.
Left loop: no need, VDS=VGS
Then we can calculate ID = 52.5 mA.
Check: VDS  VGS VTP
Hence saturation assumption is correct.

Q-pt: (52.5 mA, -3.45 V)
Do this example on the board
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-137
Junction Field-Effect
Transistors (JFET)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-138
Junction Field-Effect
Transistors (JFET)
•
•
•
•
MOSFET devices are called FET because electric field is used to control the shape and
hence the conductivity of the channel of one type charge carrier (p or n) in semiconductor
device.
There is another type of FET, which is not using MOS capacitor structure, however utilizes
the electric filed effect: Junction Field-Effect Transistor.
Less prevalent than MOSFET, JFET have many uses, especially in analog RF applications.
Can be of two types: n-channel and p-channel JFET.
n-channel JFET consists of:
• n-type semiconductor block that houses
the channel region in n-channel JFET.
• pn junction - forms the gate.
• Source and drain terminals
Like a diode with enlarged n-type section and two n-terminals.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-139
JFET Structure
•
•
With no bias applied, a resistive channel
exists. The current enters channel at the
drain and exits at source.
•
The resistance of the drain-source
channel is controlled by changing the
physical width of the channel through
modulation of the depletion layers
around pn-junctions (like squeezing a
garden hose)
•
Application of reverse bias to the gatechannel diodes causes the depletion
layer to widen, reducing the channel
width and decreasing the current.
•
JFET is inherently a depletion-mode
device – a voltage must be applied to
turn the device off.
In triode region, JFET is a voltagecontrolled resistor,
R r L
CH
tW
r - resistivity of channel
L - channel length
W - channel width between pn junction
depletion regions
t - channel depth
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-140
JFET: applying Gate-Source voltage
• vGS = 0. The channel width is W. It can
conduct current well if vDS is applied.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-141
JFET: applying Gate-Source voltage
• vGS = 0. The channel width is W. It can
conduct current well if vDS is applied.
• VP < vGS <0. The depletion layers width
is increased. The channel width W’ < W,
and channel resistance increases. Gatesource junction is reverse-biased, iG
almost 0.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-142
JFET: applying Gate-Source voltage
• vGS = 0. The channel width is W. It can
conduct current well if vDS is applied.
• VP < vGS <0. The depletion layers width
is increased. The channel width W’ < W,
and channel resistance increases. Gatesource junction is reverse-biased, iG
almost 0.
• vGS = VP < 0. The depletion layer is max.
Channel width – zero, region is pinchedoff, channel resistance is infinite.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-143
JFET: applying Drain-Source voltage
• With constant vGS, depletion region
near drain increases with vDS
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-144
JFET: applying Drain-Source voltage
• With constant vGS, depletion region
near drain increases with vDS
• At vDSP = vGS - VP , channel is totally
pinched-off; iD is saturated. (the current
does not stop: electrons are accelerated down the
channel (V is large), are injected into the depletion
region and swept to the drain)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-145
JFET: applying Drain-Source voltage
• With constant vGS, depletion region
near drain increases with vDS
• At vDSP = vGS - VP , channel is totally
pinched-off; iD is saturated. (the current
does not stop: electrons are accelerated down the
channel (V is large), are injected into the depletion
region and swept to the drain)
• JFET also suffers from channel-length
modulation like MOSFET at larger
values of vDS.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-146
JFET: applying Drain-Source voltage
• With constant vGS, depletion region
near drain increases with vDS
• At vDSP = vGS - VP , channel is totally
pinched-off; iD is saturated. (the current
does not stop: electrons are accelerated down the
channel (V is large), are injected into the depletion
region and swept to the drain)
• JFET also suffers from channel-length
modulation like MOSFET at larger
values of vDS.
Simulation:
http://www-g.eng.cam.ac.uk/mmg/teaching/linearcircuits/jfet.html
http://learnabout-electronics.org/fet_03.php
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-147
N-Channel JFET i-v Characteristics
The JFET iv-characteristics are remarkably similar to the MOSFET characteristics
(virtually identical).
Transfer Characteristics
NJIT ECE271 Dr. Serhiy Levkov
Output Characteristics
Chap 4-148
N-Channel JFET i-v equations
Equations are similar to MOSFET except written slightly differently
iG 0 for vGS 0
• For all regions :
iD  0 for vGS VP VP 0
• In cutoff region:
• In Triode region: 

2
vDS 
2I DSS 
iD  2  vGS VP 
 vDS for vGS  VP and vGS VP  VDS  0

2 
VP 
• In pinch-off region:
iD  I
Explanation:


DSS 


v
1 GS
VP

DSS
NJIT ECE271 Dr. Serhiy Levkov
2
1vDS 
for vGS  VP and vDS  vGS VP  0

v
Kn
Kn
2
2
iD  (vGS VP )  (VP ) 1 GS

2
2
VP

where I
Typically:










2

= I DSS 


2
vGS 
1
 ,
VP 
Kn
(VP )2 , I
[10μA, 10A], VP [25V, 0]
DSS
2
IDSS [10m A, 10 A], VP [-25V, 0V]
Chap 4-149
P-Channel JFET
• Polarities of n- and p-type regions of the n-channel
JFET are reversed to get the p-channel JFET.
• Channel current direction and operating bias voltages
are also reversed.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-150
JFET Circuit Symbols
n-channel
p-channel
• JFET structures are symmetric like MOSFETs.
• Source and drain determined by circuit voltages.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-151
JFET n-Channel Model Summary
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-152
JFET p-Channel Model Summary
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-153
Biasing JFET (1)
N-channel JFET

I
DSS
Depletion-mode MOSFET
Kn
400m A/V 2
(VP )2 
(5)2  5000m A  5mA
2
2
• Assumptions: Gate-channel junction is reverse-biased, reverse leakage
current of gate, IG = 0
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-154
Biasing JFET (2) DIY
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-155
Biasing JFET (3)
Region Assumption: JFET is pinched-off (saturation)
Input loop: IG  0, I S  I D  VGS  I D RS

V
VGS  I DSS RS 1 GS

VP





2
   5103 A  1000 

VGS  1.91V, 13.1V


V 
1 GS 

5V 

2
Since VGS = -13.1 V is less than VP= -5 V , we take VGS = -1.91 V (n-channel type!)
and, ID = IS = 1.91 mA.
Output loop:
VDS VDD  ID(RD  RS )12(1.91mA)(3k) 6.27V
VDS >VGS -VP. Hence pinch-off region assumption is correct and gatesource junction is reverse-biased by 1.91V.
Q-pt: (1.91 mA, 6.27 V)
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-156
Internal Capacitances in Electronic Devices
• Limit high-frequency performance of the electronic device
they are associated with.
• Limit switching speed of circuits in logic applications
• Limit frequency at which useful amplification can be
obtained in amplifiers.
• MOSFET capacitances depend on operation region and are
non-linear functions of voltages at device terminals.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-157
NMOS Transistor Capacitances: Triode Region
C
C  GC C
W Cox"WL C
W
GS
GSO
GSO
2
2

C
C
 GC C
W Cox"WL C
W
GD
GSO
GSO
2
2

C C A C
P
SB J S JSW S

C C A C
P
DB J D JSW D

NJIT ECE271 Dr. Serhiy Levkov
Cox” =Gate-channel capacitance
per unit area(F/m2).
CGC =Total gate channel
capacitance.
CGS = Gate-source capacitance.
CGD =Gate-drain capacitance.
CGSO and CGDO = overlap
capacitances (F/m).
CSB = Source-bulk capacitance.
CDB = Drain-bulk capacitance.
AS and AD = Junction bottom area
capacitance of the source and drain
regions.
PS and PD = Perimeter of the source and
drain junction regions.
Chap 4-158
NMOS Transistor Capacitances: Saturation Region
• Drain no longer connected to channel
C  2 C C
W
GS 3 GC GSO

C C
W
GD GDO

NJIT ECE271 Dr. Serhiy Levkov
Chap 4-159
NMOS Transistor Capacitances: Cutoff Region
• Conducting channel
region completely
gone.
C C
W
GS GSO

C C
W
GD GDO
C C
W
GB GBO

CGB = Gate-bulk
capacitance
CGBO = gate-bulk
capacitance per unit
width.

NJIT ECE271 Dr. Serhiy Levkov
Chap 4-160
JFET Capacitances
• CGD and CGS are determined by depletionlayer capacitances of reverse-biased pn
junctions forming gate and are bias
dependent.
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-161
SPICE Model for NMOS Transistor
Typical default values used by SPICE:
Kn or Kp = 20 mA/V2
g=0
=0
VTO = 1 V
mn or mp = 600 cm2/V.s
2FF = 0.6 V
CGDO=CGSO=CGBO=CJSW= 0
Tox= 100 nm
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-162
SPICE Model for JFET
• Typical default values used by SPICE:
Vp = -2 V
= CGD = CGD = 0
Transconductance parameter BETA
BETA = IDSS/VP2 = 100 mA/V2
NJIT ECE271 Dr. Serhiy Levkov
Chap 4-163