viju.ppt1, mosfet characteristics, three
ShobanaS19
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Aug 31, 2025
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About This Presentation
Explains mosfet and its characteristics, applications, helpful for ECE and EEE students. It is under the Electron devices MOSFET is one of the three terminal devices with Gate voltage as a control voltage other terminals are source and drain
Slide Content
MOSFET V-I Characteristics
Vijaylakshmi.B
Lecturer, Dept of Instrumentation Tech
Basaveswar Engg. College
Bagalkot, Karnataka
IUCEE-VLSI Design, Infosys, Mysore
Vijaylakshmi.B
Lecturer, Dept of Instrumentation Tech
Basaveswar Engg. College
Bagalkot, Karnataka
IUCEE-VLSI Design, Infosys, Mysore
Types of Transistors
MOSFET (Types)
Four types:
n-channel enhancement mode
•Most common since it is cheapest to manufacture
p-channel enhancement mode
n-channel depletion mode
p-channel depletion mode
Depletion type
n-channel p-channel
Enhancement type
n-channel p-channel
Four types:
n-channel enhancement mode
•Most common since it is cheapest to manufacture
p-channel enhancement mode
n-channel depletion mode
p-channel depletion mode
Depletion type
n-channel p-channel
Enhancement type
n-channel p-channel
MOSFET
FET = Field-Effect Transistor
A four terminal device (gate, source, drain,
bulk)
Symbols of
MOSFET
FET = Field-Effect Transistor
A four terminal device (gate, source, drain,
bulk)
Symbols of
MOSFET
MOSFET characteristics
Basically low voltage device. High voltage
device are available up to 600V but with limited
current. Can be paralleled quite easily for higher
current capability.
Internal (dynamic) resistance between drain and
source during on state, R
DS(ON), , limits the
power handling capability of MOSFET. High
losses especially for high voltage device due to
R
DS(ON) .
Dominant in high frequency application
(>100kHz). Biggest application is in switched-
mode power supplies.
Basically low voltage device. High voltage
device are available up to 600V but with limited
current. Can be paralleled quite easily for higher
current capability.
Internal (dynamic) resistance between drain and
source during on state, R
DS(ON), , limits the
power handling capability of MOSFET. High
losses especially for high voltage device due to
R
DS(ON) .
Dominant in high frequency application
(>100kHz). Biggest application is in switched-
mode power supplies.
The transistor consists of three regions, labeled the
``source'', the ``gate'' and the ``drain''.
The area labeled as the gate region is actually a
``sandwich'' consisting of the underlying substrate
material, which is a single crystal of semiconductor
material (usually silicon); a thin insulating layer
(usually silicon dioxide); andan upper metal layer.
Electrical charge, or current, can flow from the
source to the drain depending on the charge applied
to the gate region.
The semiconductor material in the source and drain
region are ``doped'' with a different type of material
than in the region under the gate, so an NPN or PNP
type structure exists between the source and drain
region of a MOSFET.
``source'', the ``gate'' and the ``drain''.
The area labeled as the gate region is actually a
``sandwich'' consisting of the underlying substrate
material, which is a single crystal of semiconductor
material (usually silicon); a thin insulating layer
(usually silicon dioxide); andan upper metal layer.
Electrical charge, or current, can flow from the
source to the drain depending on the charge applied
to the gate region.
The semiconductor material in the source and drain
region are ``doped'' with a different type of material
than in the region under the gate, so an NPN or PNP
type structure exists between the source and drain
region of a MOSFET.
•Most important device in digital design
•Very good as a switch
•Relatively few parasitics
•Rather low power consumption
•High integration density
•Simple manufacturing
•Economical for large complex circuits
•Very good as a switch
•Relatively few parasitics
•Rather low power consumption
•High integration density
•Simple manufacturing
•Economical for large complex circuits
n-Channel MOSFET
NMOS Structure
MOS (Metal-Oxide-Semiconductor) Nowadays gate is made of poly-silicon
?????? Channel length L and width W
??????
In most digital design, L is set at the minimum feature size
??????
W is selectable by the designer
?????? Bulk is connected to the Gnd in NMOS to prevent forward-biased PN junction
On state
Off state
MOS (Metal-Oxide-Semiconductor) Nowadays gate is made of poly-silicon
?????? Channel length L and width W
??????
In most digital design, L is set at the minimum feature size
??????
W is selectable by the designer
?????? Bulk is connected to the Gnd in NMOS to prevent forward-biased PN junction
On state
Off state
n-MOSFET Characteristics
Plots V-I characteristics
of the device for various
Gate voltages (VGS)
At a constant value of VDS , we can
also see that IDS is a function of the
Gate voltage, VGS
The transistor begins to conduct
when the Gate voltage, VGS , reaches
the Threshold voltage: VT
Plots V-I characteristics
of the device for various
Gate voltages (VGS)
At a constant value of VDS , we can
also see that IDS is a function of the
Gate voltage, VGS
The transistor begins to conduct
when the Gate voltage, VGS , reaches
the Threshold voltage: VT
PMOS Structure
PMOS transistor has a negative threshold voltage (Vtp) -0.3v~-1.2v
A pMOS turns on when Vgs<Vtp
PMOS transistor has a negative threshold voltage (Vtp) -0.3v~-1.2v
A pMOS turns on when Vgs<Vtp
The terminal characteristics of the device are given by
drain-to-source current Ids against drain-to-source
voltage Vds for different values of gate-to-source
voltage Vgs. All voltages are referenced with respect
to the source voltage, which is assumed to be at
ground potential.
P-MOSFET Characteristics
drain-to-source current Ids against drain-to-source
voltage Vds for different values of gate-to-source
voltage Vgs. All voltages are referenced with respect
to the source voltage, which is assumed to be at
ground potential.
P-MOSFET Characteristics
Switch models of MOSFETs
g
s
d
g = 0
s
d
g = 1
s
d
g
s
d
s
d
s
d
nMOS
pMOS
OFF
ON
ON
OFF
g
s
d
g = 0
s
d
g = 1
s
d
g
s
d
s
d
s
d
nMOS
pMOS
OFF
ON
ON
OFF
Thank You
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