Power MOSFET Basics

Application Note AN-1084
Power MOSFET Basics
by Vrej Barkhordarian, International Rectifier
Table of Contents
Page
Breakdown Voltage ..............................................................................5
On-resistance.......................................................................................6
Transconductance................................................................................6
Threshold Voltage ................................................................................7
Diode Forward Voltage ........................................................................7
Power Dissipation ................................................................................7
Dynamic Characteristics.......................................................................8
Gate Charge.........................................................................................10
dV/dt Capability ....................................................................................11
This application note discusses the breakdown voltage, on-resistance, transconductance,
threshold voltage, diode forward voltage, power dissipation, dynamic characteristics, gate
charge and dV/dt capability of the power MOSFET.
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AN-1084
1
Power MOSFET Basics
Vrej Barkhordarian, International Rectifier, El Segundo, Ca.
Discrete power MOSFETs
employ semiconductor
processing techniques that are
similar to those of today's VLSI
circuits, although the device
geometry, voltage and current
levels are significantly different
from the design used in VLSI
devices. The metal oxide
semiconductor field effect
transistor (MOSFET) is based
on the original field-effect
transistor introduced in the
70s. Figure 1 shows the
device schematic, transfer
characteristics and device
symbol for a MOSFET. The
invention of the power
MOSFET was partly driven by
the limitations of bipolar power
junction transistors (BJTs)
which, until recently, was the
device of choice in power
electronics applications.
Source
Contact
Field
Oxide
Gate
Gate
Oxide Metallization
Drain
Contact
n* Drain
n* Source
tox
p-Substrate
l
Channel
(a)
ID
0
Although it is not possible to
define absolutely the operating
boundaries of a power device,
we will loosely refer to the
power device as any device
that can switch at least 1A.
The bipolar power transistor is
a current controlled device. A
large base drive current as
high as one-fifth of the
collector current is required to
keep the device in the ON
state.
0
VT
VGS
(b)
ID
D
SB
(Channel or Substrate)
G
S
(c)
Figure 1. Power MOSFET (a) Schematic, (b) Transfer Characteristics, (c)
Also, higher reverse base drive
Device Symbol.
currents are required to obtain
fast turn-off. Despite the very advanced state of manufacturability and lower costs of BJTs, these
limitations have made the base drive circuit design more complicated and hence more expensive than the
power MOSFET.
Holdoff Voltage (V)
Another BJT limitation is that both electrons and holes
2000
contribute to conduction. Presence of holes with their higher
carrier lifetime causes the switching speed to be several orders of
1500
magnitude slower than for a power MOSFET of similar size and
Bipolar
Transistors
voltage rating. Also, BJTs suffer from thermal runaway. Their
1000
forward voltage drop decreases with increasing temperature
causing diversion of current to a single device when several
MOS
500
devices are paralleled. Power MOSFETs, on the other hand, are
majority carrier devices with no minority carrier injection. They
0
are superior to the BJTs in high frequency applications where
1
10
100
1000
switching power losses are important. Plus, they can withstand
Maximum Current (A)
simultaneous application of high current and voltage without
Figure 2. Current-Voltage
undergoing destructive failure due to second breakdown. Power
Limitations of MOSFETs and BJTs.
MOSFETs can also be paralleled easily because the forward
voltage drop increases with increasing temperature, ensuring an even distribution of current among all
components.
However, at high breakdown voltages (>200V) the on-state voltage drop of the power MOSFET becomes
higher than that of a similar size bipolar device with similar voltage rating. This makes it more attractive
to use the bipolar power transistor at the expense of worse high frequency performance. Figure 2 shows
the present current-voltage limitations of power MOSFETs and BJTs. Over time, new materials,
structures and processing techniques are expected to raise these limits.
Source
Gate
Oxide
Polysilicon
Gate
Source
Metallization
p+ Body Region
+
n
Channels
p
Drift Region
n+
p+
D
n- Epi Layer
G
n+ Substrate
(100)
Drain
Metallization
Drain
Figure 3. Schematic Diagram for an n-Channel Power MOSFET and the Device.
S
Figure 3 shows schematic diagram and Figure 4 shows the physical origin of the parasitic components in
an n-channel power MOSFET. The parasitic JFET appearing between the two body implants restricts
current flow when the depletion widths of the two adjacent body diodes extend into the drift region with
increasing drain voltage. The parasitic BJT can make the device susceptible to unwanted device turn-on
and premature breakdown. The base resistance RB must be minimized through careful design of the
doping and distance under the source region. There are several parasitic capacitances associated with
the power MOSFET as shown in Figure 3.
CGS is the capacitance due to the overlap of the source and the channel regions by the polysilicon gate
and is independent of applied voltage. CGD consists of two parts, the first is the capacitance associated
with the overlap of the polysilicon gate and the silicon underneath in the JFET region. The second part is
the capacitance associated with the depletion region immediately under the gate. CGD is a nonlinear
function of voltage. Finally, CDS, the capacitance associated with the body-drift diode, varies inversely
with the square root of the drain-source bias. There are currently two designs of power MOSFETs, usually
referred to as the planar and the trench designs. The planar design has already been introduced in the
schematic of Figure 3. Two variations of the trench power MOSFET are shown Figure 5. The trench
technology has the advantage of higher cell density but is more difficult to manufacture than the planar
device.
Metal
Cgsm
LTO
CGS2
CGS1
n-
CGD
n-
RCh
JFET
-
p
RB
CDS
BJT
REPI
n- Epi Layer
n- Substrate
Figure 4. Power MOSFET Parasitic Components.
BREAKDOWN VOLTAGE
S
G
S
Breakdown voltage,
BVDSS, is the voltage at
which the reverse-biased
body-drift diode breaks
down and significant
current starts to flow
between the source and
drain by the avalanche
multiplication process,
while the gate and
source are shorted
together. Current-voltage
characteristics of a
Electron Flow
power MOSFET are
shown in Figure 6.
BVDSS is normally
measured at 250µA drain
current. For drain
voltages below BVDSS
and with no bias on the
D
gate, no channel is
(a)
formed under the gate at
the surface and the drain
Source
Source
voltage is entirely
Gate
supported by the
reverse-biased body-drift
p-n junction. Two related
Oxide
Gate
phenomena can occur in
Oxide
poorly designed and
processed devices:
punch-through and
reach-through. PunchChannel
through is observed
n- Epi Layer
when the depletion
region on the source side
of the body-drift p-n
junction reaches the
n+ Substrate
source region at drain
(100)
voltages below the rated
avalanche voltage of the
device. This provides a
current path between
Drain
source and drain and
(b)
causes a soft breakdown
Figure 5. Trench MOSFET (a) Current Crowding in V-Groove Trench MOSFET,
characteristics as shown
(b) Truncated V-Groove MOSFET
in Figure 7. The leakage
current flowing between
source and drain is denoted by IDSS. There are tradeoffs to be made between RDS(on) that requires shorter
channel lengths and punch-through avoidance that requires longer channel lengths.
The reach-through phenomenon occurs when the depletion region on the drift side of the body-drift p-n
junction reaches the epilayer-substrate interface before avalanching takes place in the epi. Once the
depletion edge enters the high carrier concentration substrate, a further increase in drain voltage will
cause the electric field to quickly reach the critical value of 2x105 V/cm where avalanching begins.
ON-RESISTANCE
The on-state resistance of a power MOSFET is made up of several components as shown in Figure 8:
R DS(on) = R source + R ch + R A + R J + R D + R sub + R wcml
(1)
where:
25
Rsource = Source diffusion resistance
Rch = Channel resistance
RA = Accumulation resistance
RJ = "JFET" component-resistance of the
region between the two body regions
RD = Drift region resistance
Rsub = Substrate resistance
7
Gate
Voltage
20
Normalized Drain Current
Rwcml = Sum of Bond Wire resistance, the
Contact resistance between the source
and drain Metallization and the silicon,
metallization and Leadframe
contributions. These are normally
negligible in high voltage devices but can
become significant in low voltage devices.
15
(Saturation
Region)
Wafers with substrate resistivities of up to
20mΩ-cm are used for high voltage
devices and less than 5mΩ-cm for low
voltage devices.
Linear Region
6
5
10
IDS VS VDS LOCUS
4
Figure 9 shows the relative importance of
each of the components to RDS(on) over the
5
3
voltage spectrum. As can be seen, at high
voltages the RDS(on) is dominated by epi
resistance and JFET component. This
2
component is higher in high voltage
1
devices due to the higher resistivity or
lower background carrier concentration in
0
0
5
10
15
the epi. At lower voltages, the RDS(on) is
Drain Voltage (Volts)
dominated by the channel resistance and
Figure 6. Current-Voltage Characteristics of Power MOSFET
the contributions from the metal to
semiconductor contact, metallization,
bond wires and leadframe. The substrate contribution becomes more significant for lower breakdown
voltage devices.
TRANSCONDUCTANCE
Transconductance, gfs, is a measure of the sensitivity of drain current to changes in gate-source bias.
This parameter is normally quoted for a Vgs that gives a drain current equal to about one half of the
maximum current rating value and for a VDS that ensures operation in the constant current region.
Transconductance is influenced by gate width, which increases in proportion to the active area as cell
density increases. Cell density has increased over the years from around half a million per square inch in
1980 to around eight million for planar MOSFETs and around 12 million for the trench technology. The
limiting factor for even higher cell densities is the photolithography process control and resolution that
allows contacts to be made to the source metallization in the center of the cells.
Channel length also affects transconductance. Reduced
channel length is beneficial to both gfs and on-resistance,
with punch-through as a tradeoff. The lower limit of this
length is set by the ability to control the double-diffusion
process and is around 1-2mm today. Finally the lower the
gate oxide thickness the higher gfs.
ID
Soft
THRESHOLD VOLTAGE
Sharp
Threshold voltage, Vth, is defined as the minimum gate
electrode bias required to strongly invert the surface
under the poly and form a conducting channel between
BVDSS
VDS
the source and the drain regions. Vth is usually measured
at a drain-source current of 250µA. Common values are
Figure 7. Power MOSFET Breakdown
2-4V for high voltage devices with thicker gate oxides, and
Characteristics
1-2V for lower voltage, logic-compatible devices with
thinner gate oxides. With power MOSFETs finding increasing use in portable electronics and wireless
communications where battery power is at a premium, the trend is toward lower values of RDS(on) and
Vth.
GATE
DIODE FORWARD VOLTAGE
N+
The diode forward voltage, VF, is the
guaranteed maximum forward drop of
the body-drain diode at a specified
value of source current. Figure 10
shows a typical I-V characteristics for
this diode at two temperatures. Pchannel devices have a higher VF due
to the higher contact resistance
between metal and p-silicon
compared with n-type silicon.
Maximum values of 1.6V for high
voltage devices (>100V) and 1.0V for
low voltage devices (<100V) are
common.
SOURCE
RSOURCE
RA
RCH
RD
POWER DISSIPATION
N+ SUBSTRATE
The maximum allowable power
dissipation that will raise the die
temperature to the maximum
allowable when the case temperature
is held at 250C is important. It is give
by Pd where:
Pd = T j m ax- 25
R thJC
P-BASE
RJ
RSUB
DRAIN
Figure 8. Origin of Internal Resistance in a Power MOSFET.
(2)
Tjmax = Maximum allowable temperature of the p-n junction in the device (normally 1500C or 1750C) RthJC
= Junction-to-case thermal impedance of the device.
DYNAMIC CHARACTERISTICS
When the MOSFET is used as a switch, its basic function is to control the drain current by the gate
voltage. Figure 11(a) shows the transfer characteristics and Figure 11(b) is an equivalent circuit model
often used for the analysis of MOSFET switching performance.
Voltage Rating:
50V
100V
500V
Packaging
Rwcml
Metallization
Source
RCH
Channel
JFET
Region
REPI
Expitaxial
Layer
Substrate
Figure 9. Relative Contributions to RDS(on) With Different Voltage Ratings.
The switching performance of a device is determined by the time required to establish voltage changes
across capacitances. RG is the distributed resistance of the gate and is approximately inversely
proportional to active area. LS and LD are source and drain lead inductances and are around a few tens of
nH. Typical values of input (Ciss), output (Coss) and reverse transfer (Crss) capacitances given in the data
sheets are used by circuit designers as a starting point in determining circuit component values. The data
sheet capacitances are defined in terms of the equivalent circuit capacitances as:
Ciss = CGS + CGD, CDS shorted
100
Crss = CGD
Gate-to-drain capacitance, CGD, is a
nonlinear function of voltage and is the most
important parameter because it provides a
feedback loop between the output and the
input of the circuit. CGD is also called the
Miller capacitance because it causes the total
dynamic input capacitance to become greater
than the sum of the static capacitances.
ISD, Reverse Drain Current (A)
Coss = CDS + CGD
Figure 12 shows a typical switching time test
circuit. Also shown are the components of
the rise and fall times with reference to the
VGS and VDS waveforms.
10
TJ = 1500C
TJ = 250C
1
VGS = 0V
0.1
0.0
0.5
1.0
1.5
2.0
2.5
Turn-on delay, td(on), is the time taken to
VSD, Source-to-Drain Voltage (V)
charge the input capacitance of the device
Figure 10. Typical Source-Drain (Body) Diode Forward
before drain current conduction can start.
Voltage Characteristics.
Similarly, turn-off delay, td(off), is the time
taken to discharge the capacitance after the after is switched off.
D
ID
LD
CGD
D'
G
Slope = gfs
RG
C
ID
CDS
Body-drain
Diode
S'
CGS
VGS
LS
S
(a)
(b)
Figure 11. Power MOSFET (a) Transfer characteristics, (b) Equivalent Circuit Showing Components That
Have Greatest Effect on Switching
GATE CHARGE
RD
Although input capacitance
VDS
values are useful, they do not
provide accurate results when
D.U.T.
comparing the switching
VGS
performances of two devices
from different manufacturers.
RG
Effects of device size and
VDD
transconductance make such
+
comparisons more difficult. A
more useful parameter from the
circuit design point of view is
-10V
the gate charge rather than
Pulse Width < 1µ
µs
capacitance. Most
Duty Factor < 0.1%
manufacturers include both
parameters on their data sheets.
(a)
Figure 13 shows a typical gate
charge waveform and the test
td(on)
tr
td(off)
tf
circuit. When the gate is
connected to the supply voltage,
VGS
VGS starts to increase until it
100%
reaches Vth, at which point the
drain current starts to flow and
the CGS starts to charge. During
the period t1 to t2, CGS
continues to charge, the gate
voltage continues to rise and
drain current rises
90%
proportionally. At time t2, CGS
is completely charged and the
VDS
drain current reaches the
(b)
predetermined current ID and
stays constant while the drain
Figure 12. Switching Time Test (a) Circuit, (b) VGS and VDS
voltage starts to fall. With
Waveforms
reference to the equivalent
circuit model of the MOSFET shown in Figure 13, it can be seen that with CGS fully charged at t2, VGS
becomes constant and the drive current starts to charge the Miller capacitance, CDG. This continues
until time t3.
Charge time for the Miller capacitance is
larger than that for the gate to source
capacitance CGS due to the rapidly changing
drain voltage between t2 and t3 (current = C
dv/dt). Once both of the capacitances CGS
and CGD are fully charged, gate voltage (VGS)
starts increasing again until it reaches the
supply voltage at time t4. The gate charge
(QGS + QGD) corresponding to time t3 is the
bare minimum charge required to switch
the device on. Good circuit design practice
dictates the use of a higher gate voltage
than the bare minimum required for
switching and therefore the gate charge
used in the calculations is QG
corresponding to t4.
The advantage of using gate charge is that
the designer can easily calculate the
amount of current required from the drive
circuit to switch the device on in a desired
length of time because Q = CV and I = C
dv/dt, the Q = Time x current. For
example, a device with a gate charge of
20nC can be turned on in 20µsec if 1ma is
supplied to the gate or it can turn on in
20nsec if the gate current is increased to
1A. These simple calculations would not
have been possible with input capacitance
values.
dv/dt CAPABILITY
VDD
D
ID
D
CDG
G
S
S
ID
CGS
TEST CIRCUIT
(a)
OGS
OGD
VG
GATE
VOLTAGE
VG(TH)
t0 t1
t2
t3
DRAIN
VOLTAGE
t4
t
DRAIN CURRENT
VDD
ID
Peak diode recovery is defined as the
maximum rate of rise of drain-source
WAVEFORM
voltage allowed, i.e., dv/dt capability. If this
(b)
rate is exceeded then the voltage across the
gate-source terminals may become higher
Figure 13. Gate Charge Test (a) Circuit, (b) Resulting Gate
than the threshold voltage of the device,
and Drain Waveforms.
forcing the device into current conduction
mode, and under certain conditions a
catastrophic failure may occur. There are two possible mechanisms by which a dv/dt induced turn-on
may take place. Figure 14 shows the equivalent circuit model of a power MOSFET, including the
parasitic BJT. The first mechanism of dv/dt induced turn-on becomes active through the feedback action
of the gate-drain capacitance, CGD. When a voltage ramp appears across the drain and source terminal
of the device a current I1 flows through the gate resistance, RG, by means of the gate-drain capacitance,
CGD. RG is the total gate resistance in the circuit and the voltage drop across it is given by:
dv
VGS = I1 R G = R G C GD
dt
(3)
When the gate voltage VGS exceeds the threshold voltage of the device Vth, the device is forced into
conduction. The dv/dt capability for this mechanism is thus set by:
V
dv
= th
dt
R G C GD
(4)
It is clear that low Vth
DRAIN
devices are more prone to
dv/dt turn-on. The
negative temperature
coefficient of Vth is of
D
special importance in
I1
applications where high
CDB
CGD
temperature environments
NPN
are present. Also gate
BIPOLAR
APPLIED
circuit impedance has to be
G
TRANSISTOR
I2
RAMP
chooses carefully to avoid
VOLTAGE
this effect.
RG
RB
The second mechanism for
CGS
the dv/dt turn-on in
S
MOSFETs is through the
parasitic BJT as shown in
Figure 15. The capacitance
associated with the
SOURCE
depletion region of the body
Figure 14. Equivalent Circuit of Power MOSFET Showing Two Possible
diode extending into the
Mechanisms for dv/dt Induced Turn-on.
drift region is denoted as
CDB and appears between
the base of the BJT and the drain of the MOSFET. This capacitance gives rise to a current I 2 to flow
through the base resistance RB when a voltage ramp appears across the drain-source terminals. With
analogy to the first mechanism, the dv/dt capability of this mechanism is:
dv VBE
=
dt
R BC DB
(5)
If the voltage that develops across RB is greater
than about 0.7V, then the base-emitter junction
is forward-biased and the parasitic BJT is
turned on. Under the conditions of high (dv/dt)
and large values of RB, the breakdown voltage of
the MOSFET will be limited to that of the openbase breakdown voltage of the BJT. If the
applied drain voltage is greater than the openbase breakdown voltage, then the MOSFET will
enter avalanche and may be destroyed if the
current is not limited externally.
Increasing (dv/dt) capability therefore requires
reducing the base resistance RB by increasing
the body region doping and reducing the
distance current I2 has to flow laterally before it
is collected by the source metallization. As in
the first mode, the BJT related dv/dt capability
becomes worse at higher temperatures because
RB increases and VBE decreases with increasing
temperature.
SOURCE
N+
GATE
A
LN+
RS
CDS
DRAIN
Figure 15. Physical Origin of the Parasitic BJT
Components That May Cause dv/dt Induced Turn-on
References:
"HEXFET Power MOSFET Designer's Manual - Application Notes and Reliability Data," International
Rectifier
"Modern Power Devices," B. Jayant Baliga
"Physics of Semiconductor Devices," S. M. Sze
"Power FETs and Their Applications," Edwin S. Oxner
"Power MOSFETs - Theory and Applications," Duncan A. Grant and John Gower