AN-937 (v.Int)
Gate Drive Characteristics and Requirements for
HEXFET®s
Topics covered:
Gate drive vs base drive
Enhancement vs Depletion
N vs P-Channel
Max gate voltage
Zener diodes on gate?
The most important factor in gate drive: the impedance of the gate drive circuit
Switching 101 or Understanding the waveforms
What happens if gate drive impedance is high? dv/dt induced turn-on
Can a TTL gate drive a standard HEXFET®?
The universal buffer
Power dissipation of the gate drive circuit is seldom a problem
Can a C-MOS gate drive a standard HEXFET®?
Driving HEXFET®s from linear circuits
Drive circuits not referenced to ground
Gate drivers with optocouplers
Gate drive supply developed from the drain of the power device
Gate drivers with pulse transformers
Gate drivers with choppers
Drive requirements of Logic Level HEXFET®s
How fast is a Logic Level HEXFET®driven by a logic circuit?
Simple and inexpensive isolated gate drive supplies
A well-kept secret: Photovoltaic generators as gate drivers
Driving in the MHz? Use resonant gate drivers
Related topics
(Note: Most of the gate drive considerations and circuits are equally applicable to IGBTs. Only MOSFETs are mentioned for the
sake of simplicity. Special considerations for IGBTs are contained in INT-990)
1. GATE DRIVE VS BASE DRIVE
The conventional bipolar
transistor is a current-driven
device. As illustrated in
Figure 1(a). a current must
be applied between the base
and emitter terminals to pro-
duce a flow of current in the
collector. The amount of a
drive required to produce a
given output depends upon
the gain, but invariably a
current must be made to flow
into the base terminal to
produce a flow of current in
the collector.
The HEXFET®is fundamentally different: it is a voltage-controlled power MOSFET device. A voltage must be applied between
the gate and source terminals to produce a flow of current in the drain (see Figure 1b). The gate is isolated electrically from the
source by a layer of silicon dioxide. Theoretically, therefore, no current flows into the gate when a DC voltage is applied to it -
though in practice there will be an extremely small current, in the order of nanoamperes. With no voltage applied between the
gate and source electrodes, the impedance between the drain and source terminals is very high, and only the leakage current
flows in the drain.
I
C
I
B
CURRENT
SOURCE
CURRENT
IN BASE PRODUCES
CURRENT
IN COLLECTOR
I
D
VOLTAGE
SOURCE
VOLTAGE
AT GATE PRODUCES
CURRENT
IN DRAIN
+
+
+
(a) Bipolar Transistor (b) HEXFET
Figure 1.
Bipolar Transistor is Current Driven, HEXFET is Voltage Driven
AN-937 (v.Int)
When a voltage is applied between the gate and
source terminals, an electric field is set up within the
HEXFET®. This field “inverts” the channel (Figure
2) from P to N, so that a current can flow from drain
to source in an uninterrupted sequence of N-type
silicon (drain-channel-source). Field-effect
transistors can be of two types: enhancement mode
and depletion mode. Enhancement-mode devices
need a gate voltage of the same sign as the drain
voltage in order to pass current.
Depletion-mode devices are naturally on and are
turned off by a gate voltage of the same polarity as
the drain voltage. All HEXFET®s are enhancement-
mode devices.
All MOSFET voltages are referenced to the source
terminal. An N-Channel device, like an NPN
transistor, has a drain voltage that is positive with
respect to the source. Being enhancement-mode
devices, they will be turned on by a positive voltage
on the gate. The opposite is true for P-Channel
devices, that are similar to PNP transistors.
Although it is common knowledge that HEXFET®transistors are more easily driven than bipolars, a few basic considerations
have to be kept in mind in order to avoid a loss in performance or outright device failure.
2. GATE VOLTAGE LIMITATIONS
Figure 2 shows the basic HEXFET®structure. The silicon oxide layer between the gate and the source regions can be punctured
by exceeding its dielectric strength. The data sheet rating for the gate-to-source voltage is between 10 and 30 V for most
HEXFET®s.
Care should be exercised not to exceed the gate-to-source maximum voltage rating. Even if the applied gate voltage is kept below
the maximum rated gate voltage, the stray inductance of the gate connection, coupled with the gate capacitance, may generate
ringing voltages that could lead to the destruction of the oxide layer. Overvoltages can also be coupled through the drain-gate
self-capacitance due to transients in the drain circuit. A gate drive circuit with very low impedance insures that the gate voltage
is not exceeded in normal operation. This is explained in more detail in the next section.
Zeners are frequently used “to protect the gate from transients”. Unfortunately they also contribute to oscillations and have been
known to cause device failures. A transient can get to the gate from the drive side or from the drain side. In either case, it would
be an indication of a more fundamental problem: a high impedance drive circuit. A zener would compound this problem, rather
than solving it. Sometimes a zener is added to reduce the ringing generated by the leakage of a gate drive transformer, in
combination with the input capacitance of the MOSFET. If this is necessary, it is advisable to insert a small series resistor (5-10
Ohms) between the zener and the gate, to prevent oscillations.
3. THE IMPEDANCE OF THE GATE CIRCUIT
To turn on a power MOSFET a certain charge has to be supplied to the gate to raise it to the desired voltage, whether in the
linear region, or in the “saturation” (fully enhanced) region. The best way to achieve this is by means of a voltage source, capable
of supplying any amount of current in the shortest possible time. If the device is operated as a switch, a large transient current
capability of the drive circuit reduces the time spent in the linear region, thereby reducing the switching losses.
On the other hand, if the device is operated in the linear mode, a large current from the gate drive circuit minimizes the
relevance of the Miller effect, improving the bandwidth of the stage and reducing the harmonic distortion. This can be better
understood by analyzing the basic switching waveforms at turn-on and turn-off for a clamped inductive load, as shown in Figures
DRAIN DRAIN
DIODE CURRENT
TRANSISTOR
CURRENT
TRANSISTOR
CURRENT
N
SOURCE N
GATE OXIDE
P
N
INSULATING
OXIDE
SOURCE
METALLIZATION
SILICON GATE
CHANNEL
Figure 2.
Basic HEXFET Structure
AN-937 (v.Int)
3 and 5. Figure 3 shows the waveforms of the drain current, drain-to-source voltage and gate voltage during the turn-on interval.
For the sake of simplicity, the equivalent impedance of the drive circuit has been assumed as purely resistive.
At time, t0, the drive pulse starts to rise. At t0 it reaches the threshold voltage of the HEXFET®s and the drain current starts to
increase. At this point, two things happen which make the gate-source voltage waveform deviate from its original “path”. First,
inductance in series with the source which is common to the gate circuit (“common source inductance”) develops an induced
voltage as a result of the increasing source current. This voltage counteracts the applied gate drive voltage, and slows down the
rate of rise of voltage appearing directly across the gate and source terminals; this in turn slows down the rate of rise of the
source current. This is a negative feedback effect: increasing current in the source produces a counteractive voltage at the gate,
which tends to resist the change of current.
The second factor that influences the gate-source voltage is the so called “Miller” effect. During the period t1 to t2 some voltage
is dropped across “unclamped” stray circuit inductance in series with the drain, and the drain-source voltage starts to fall. The
LOAD
"OPEN CIRCUIT"
DRIVE
PULSE
DRIVE CIRCUIT
RESISTANCE
G
INDUCTANCE
STRAY
SOURCESOURCE
INDUCTANCE
DRAIN-SOURCE
VOLTAGE
DRAIN-SOURCE
V
TH
"OPEN CIRCUIT" DRIVE PULSE
GATE-SOURCE
VOLTAGE
I
t
0
t
1
t
3
t
2
t
4
Figure 3.
Waveforms at Turn-On
DRIVE
+
-I
D
+
-I
S
THIS INDUCED VOLTAGE
SUBSTRACTS FROM THE
DRIVE VOLTAGE
RESULTING IN
RESULTING IN
THIS VOLTAGE RISING
MORE SLOWLY
RESULTING IN
SLOW RISE OF IS
VOLTAGE DROP ACROSS
THIS L MEANS THAT THE
DRAIN VOLTAGE FALL
RESULTING IN
DISCHARGE OF
THIS CAPACITOR
RESULTING IN
MORE CURRENT
THROUGH THIS
RESISTANCE
Figure 4.
Diagrammatic Representation of Effects
When Switching-ON
DRAIN-SOURCE
VOLTAGE
G-S VOLTAGE
CURRENT
GATE VOLTAGE
GIVING I
V
TH
"OPEN CIRCUIT"
DRIVE PULSE
t
4
t
3
t
2
t
1
t
0
I
Figure 5.
Waveforms at Turn-OFF
AN-937 (v.Int)
decreasing drain-source voltage is reflected across the drain-gate capacitance, pulling a discharge current through it, and
increasing the effective capacitive load on the drive circuit.
This in turn increases the voltage drop across the source impedance of the drive circuit, and decreases the rate of rise of voltage
appearing between the gate and source terminals. Obviously, the lower the impedance of the gate drive circuit, the less this effect
will be. This also is a negative feedback effect; increasing current in the drain results in a fall of drain-to-source voltage, which in
turn slows down the rise of gate-source voltage, and tends to resist the increase of drain current. These effects are illustrated
diagramatically in Figure 4. This state of affairs continues throughout the period t1 to t2, as the current in the HEXFET®rises to
the level of the current, IM, already flowing in the freewheeling rectifier, and it continues into the next period, t2 to t3, when the
freewheeling rectifier goes into reverse recovery.
Finally, at time t3 the freewheeling rectifier starts to support voltage and drain current and voltage start to fall. The rate of fall of
drain voltage is now governed almost exclusively by the Miller effect, and an equilibrium condition is reached, under which the
drain voltage falls at just the rate necessary for the voltage between gate and source terminals to satisfy the level of drain current
estab-lished by the load. This is why the gate-to-source voltage falls as the recovery current of the freewheeling rectifier falls,
then stays constant at a level corresponding to the drain current, while the drain voltage falls. Obviously, the lower the impe-
dance of the gate-drive circuit, the higher the discharge current through the drain-gate self-capacitance, the faster will be the fall
time of the drain voltage and the switching
losses.
Finally, at time t4, the HEXFET®is switched fully
on, and the gate-to-source voltage rises rapidly
towards the applied “open circuit” value.
Similar considerations apply to the turn-off
interval. Figure 5 shows theoretical waveforms
for the HEXFET®in the circuit of Figure 4 during
the turn-off interval. At to the gate drive starts to
fall until, at tl , the gate voltage reaches a level
that just sustains the drain current and the device
enters the linear mode of operation. The drain-to-
source voltage now starts to rise. The Miller
effect governs the rate-of-rise of drain voltage
and holds the gate-to-source voltage at a level
corresponding to the constant drain current.
Once again, the lower the impedance of the drive
circuit, the greater the charging current into the
drain-gate capacitance, and the faster will be the
rise time of the drain voltage. At t3 the rise of
drain voltage is complete, and the gate voltage
and drain current start to fall at a rate determined
by the gate-source circuit impedance.
We have seen how and why a low gate drive
impedance is important to achieve high
switching performance. However, even when
switching performance is of no great concern, it
is important to minimize the impedance in the
gate drive circuit to clamp unwanted voltage
transients on the gate. With reference to Figure
6, when one HEXFET®is turned on or off, a step
of voltage is applied between drain and source of
the other device on the same leg. This step of
voltage is coupled to the gate through the gate-to-
drain capacitance, and it can be large enough to
turn the device on for a short instant (“dv/dt
induced turn-on”). A low gate drive impedance would keep the voltage coupled to the gate below the threshold.
A STEP OF VOLTAGE CAUSES
V
DS
Q
1
V
DS
Q
2
V
GS
Q
1
V
GS
Q
2
A TRANSIENT
ON THE GATE
Figure 6.
Transients of Voltage Induced on the Gate by Rapid
Changes on the Drain-to-Source Voltage
AN-937 (v.Int)
In summary: MOS-gated transistors should be driven from low impedance (voltage) sources, not only to reduce switching losses,
but to avoid dv/dt induced turn-on and reduce the susceptibility to noise.
4. DRIVING STANDARD HEXFET®S FROM TTL
Table 1 shows the guaranteed sourcing and sinking currents for different TTL families at their respective voltages. From this
table, taking as an example of the 74LS series, it is apparent that, even with a sourcing current as low as 0.4 mA, the guaranteed
logic one voltage is 2.4V (2.7 for 74LS and 74S). This is lower than the possible threshold of a HEXFET®. The use of a pull-up
resistor in the output, as shown in Figure 7, takes the drive voltage up to 5 V, as necessary to drive the gate of Logic Level
HEXFET®s, but is not sufficient to fully enhance standard HEXFET®s. Section 8 covers the drive characteristics of the logic
level devices in detail.
Logic
Conditions 54 / 74 54H / 74H (54L) /
74L
(54LS) /
74LS
74S
Logic Zero
Min. sink current
for VOL
16mA
< 0.4V 20mA
< (0.4V) / 20mA
< (0.3V) /
0.4V
(4) / 8
< (0.4V) /
0.5V
20mA
0.5V
Logic One
Max. source
current for VOH
-0.4mA
>2.4V -0.5mA
>2.4V -0.2mA
>2.4V
-0.4mA
> (2.5) /
2.7V
-1.0mA
>2.7V
Typical Gate
Propagation Delay 10ns 7ns 50ns
12ns
4ns
Table 1. Driving HEXFET®s from TTL (Totem Pole Outputs)
Open collector buffers, like the 7406, 7407, etc., possibly with
several drivers connected in parallel as shown in Figure 9, give
enough voltage to drive standard devices into “full
enhancement”, i.e. data sheet on-resistance. The impedance of
this drive circuit, however, gives relative long switching times.
Whenever better switching performance is required, interface
circuits should be added to provide fast current sourcing and
sinking to the gate capacitances. One simple interface circuit is
the complementary source-follower stage shown in Figure 9. To
drive a MOSFET with a gate charge of 60 nC in 60 ns an average
gate current of 1 A has to be supplied by the gate drive circuit, as
indicated in INT-944. The on-resistance of the gate drive
MOSFETs has to be low enough to support the desired switching
times.
With a gate charge of 60 nC and at a switching frequency is
100kHz, the power lost in the gate drive circuit is approximately:
P = VGS x QG x f = 12 x 60 x 10-9 x 100 x 103 = 72mW
The driver devices must be capable of supplying 1A without
significant voltage drop, but hardly any power is dissipated in
them.
5. DRIVING STANDARD HEXFET®S FROM C-MOS
While the same general considerations presented above for TTL would also apply to C-MOS, there are three substantial
differences that should be kept in mind:
1. C-MOS has a more balanced source/sink characteristic that, on a first approximation, can be thought of as a 500 ohm
resistance for operation over 8V and a 1k ohm for operation under 8V (Table 2).
Figure 7.
Direct Drive from TTL Output
LOAD
V
H
PULL-UP
RESISTOR
TTL
(TOTEM POLE)
AN-937 (v.Int)
2. C-MOS can operate from higher supply voltages than 5V so that HEXFET®saturation can be guaranteed.
3. Switching times are longer than those for TTL (Table 2).
When C-MOS outputs are directly coupled to the gate of
a HEXFET®, the dominant limitation to performance is
not the switching time, but the internal impedance
(assuming that C-MOS are operated from a 10V or
higher voltage supply). It will certainly not be able to
turn OFF the HEXFET®as fast as the TTL, while the
turn-ON waveform will be slightly better than what can
be achieved with a 7407 with a 680 ohm pull-up
resistor. Of course, gates can be paralleled in any
number to lower the impedance and this makes C-MOS
a very simple and convenient means of driving
HEXFET®s. Drivers can also be used, like the 4049 and
4050 which have a much higher current sinking
capability (Table 2), but they do not yield any significant
improvement in current sourcing.
For better switching speeds, buffer circuits, like the one
shown in Figure 9, should be considered, not only to
provide better current sourcing and sinking capability,
but also to improve over the switching times of the C-
MOS output itself and the dv/dt noise immunity.
6. DRIVING HEXFET®S FROM LINEAR CIRCUITS
The complementary source follower configuration of Figure 9 can also be used in linear applications to improve drive capability
from an opamp or other analog source.
Most operational amplifiers have a very limited slew rate, in the order of few V/microsec. This would limit the bandwidth to less
than 25kHz. A larger bandwidth can be obtained with better operational amplifiers followed by a current booster, like the ones
shown in Figures 10 or 11. For a system bandwidth of 1MHz, the opamp bandwidth must be significantly higher than 1MHz and
its slew rate at least 30V/µs.
V
H
680
IRF320
7407
680
12V
Figure 8.
High Voltage TTL driver and its waveforms
Figure 9.
Simple Interface to Drive HEXFETs from TTL
7407
1
K
V
H
LOAD
+12V
INPUT
87
2
4
56
1
3
IRF7307 OR IRF7507
AN-937 (v.Int)
Standard Buffered
Outputs 4049 / 4050 Drivers
Logic Supply Voltage
Logic Conditions 5V 10V
15V
5V
10V 15V
Logic Zero:
Approximate sink current
for VOL < 1.5V 1.5mA 3.5mA
4mA
20mA
40mA 40mA
Logic One:
Minimum source current for VOH
-0.5mA
> 4.6V -13mA
> 9.5V
-3.4mA
> 13.5V
-1.25mA
> 2.5V
-1.25mA
> 9.5V -3.75mA
> 13.5V
Typical switching times of logic drive signals:
RISE
FALL 100ns
100ns 50ns
50ns
40ns
40ns
100ns
40ns 50ns
20ns 40ns
15ns
Table 2. Driving HEXFET®s from C-MOS (Buffered)
When analog signals determine the switching frequency or
duty cycle of a HEXFET®, as in PWM applications, a
voltage comparator is normally used to command the
switching. Here, too, the limiting factors are the slew rate of
the comparator and its current drive capability. Response
times under 40ns can be obtained at the price of low output
voltage swing (TTL compatible). Once again, the use of
output buffers like the ones shown in Figures 9, may be
necessary to improve drive capability and dv/dt immunity. If
better switching speeds are desired. a fast op-amp should be
used.
In many applications, when the HEXFET®is turned on,
current transfers from a freewheeling diode into the
HEXFET®. If the switching speed is high and the stray
inductances in the diode path are small, this transfer can
occur in such a short time as to cause a reverse recovery
current in the diode high enough to short out the dc bus. For
this reason, it may be necessary to slow down the turn-on of
the HEXFET®while leaving the turn-off as fast as practical.
Low impedance pulse shaping circuits can be used for this
purpose, like the ones in Figures 12 and 13.
7. DRIVE CIRCUITS NOT
REFERENCED TO GROUND
To drive a HEXFET®into saturation, an appropriate voltage
must be applied between the gate and source. If the load is
connected between source and ground, and the drive voltage is
applied between gate and ground, the effective voltage between
gate and source decreases as the device turns on. An equilibrium
point is reached in which the amount of current flowing in the
load is such that the voltage between gate and source maintains
that amount of drain current and no more. Under these
conditions the voltage drop across the MOSFET is certainly
higher than the threshold voltage and the power dissipation can
be very high. For this reason, the gate drive circuit is normally
referenced to the source rather than to the ground. There are
Figure 10.
Dual Supply Op-Amp Drive Circuit
V
H
LOAD
+12V
INPUTS
87
2
4
56
1
3
IRF7309 OR IRF7509
-
+
-12V 0.1
µµ
F
CER
FET
INPUT
OP
AMP
Figure 11.
Single Supply Op-Amp Drive Circuit
(Voltage Follower)
CA3103
V
H
LOAD
+12V
87
2
4
56
1
3
IRF7307 OR IRF7507
-
+
0.1
µµ
F
CER
FET
INPUT
OP AMP.
2
3
AN-937 (v.Int)
basically three ways of developing a gate drive signal that is referenced to a floating point:
1. By means of optically coupled isolators.
2. By means of pulse transformers.
By means of DC to DC chopper circuits with transformer isolation.
7.1 MGDs with optocouplers
Most optocouplers require a separate
supply grounded to the source on the
receiving end of the optical link and
a booster stage at the output, as
shown in Figure 14a. One of the
major difficulties encountered in the
use of optocouplers is their
susceptibility to noise. This is of
particular relevance in applications
where high currents are being
switched rapidly. Because of the
dv/dt seen by the VEE pin, the
optocoupler needs to be rated for
high dv/dt, in the order of 10 V/ns.
Figure 15a shows an MGD with
under-voltage lockout and negative
gate bias. When powered with a 19
V floating source, the gate drive
voltage swings between +15V and -
3.9V. D1 and R2 offset the emitter voltage by 3.9V. The switching waveforms shown in Figure 15b are similar to those in Figure
14b except for the negative bias. Q3, D2 and R5 form the under voltage lockout circuit.
The LED D2 is used as low voltage, low current reference diode. Q3 turns on when the voltage at the anode of D2 exceeds the
sum of the forward voltage of LED and the base-emitter voltage of Q3. This enables the operation of the optocoupler. The
tripping point of the under voltage lock-out circuit is 17.5V. The start-up wave forms are shown in Figure 16.
Figure 12.
A pulse shaper. The 555 is used as an illustration of a Schmitt Trigger pulse shaper
INPUT PULSE
T = RC
WITH DIODE
CONNECTED
AS SHOWN
V
H
LOAD
+12V
87
2
4
56
1
3
IRF7307 OR IRF7507
C
555
8
42
3
61R
4.7K
INPUT
Figure 13.
Pulse shaper implemented with an integrator
V
H
LOAD
+12V
87
2
4
56
1
3
C
INPUT CA3103
-
+
C
R
V
INPUT
WITH DIODE
CONNECTED
AS SHOWN
SLOPE OF V
RC V/SEC
AN-937 (v.Int)
The auxiliary supply for the optocoupler and its associated circuitry can be developed from the drain voltage of the MOSFET
itself, as shown in Figure 17, 18 and 19. This supply can be used in conjunction with the UV-lockout shown in Figure 15 to
provide a simple high-quality optoisolated drive.
The circuit in Figure 17a can be modified to provide higher
output current. By changing C1 to 680pF and R3 to 5.6k, its
performance changes to what is shown in Figures 20, 21 and
22. Other methods of developing isolated supplies are discussed
in Section 9.
7.2 Pulse transformers
A pulse transformer is, in principle, a simple, reliable and
highly noise-immune method of providing isolated gate drive.
Unfortunately it has many limitations that must be overcome
with additional components. A transformer can only transfer to
the secondary the AC component of the input signal.
Consequently, their output voltage swings from negative to
positive by an amount that changes with the duty cycle, as
shown in Figure 23. As a stand-alone component they can be
used for duty cycles between 35 and 65%.
Figure 14a.
Simple high current optoisolated driver
87
2
4
56
1
3+
C2
10
BATT1
15V
GATE
EMITTER
3.9V
C1
0.1
IRF7307 OR IRF7507
VCC
OUT
EN
VEEC
A8
7
6
5
ISO1
R1 2
3
3.3k
Input: 5V/div
Output : 5V/div
Horiz: 500ns/div
Figure 14b:
Waveforms associated with the
circuit of Figure 14a when loaded with 100nF
Figure 15a:
Optoisolated driver with UV lockout and negative gate bias
87
2
4
56
1
3C2
10
BATT1
19V
GATE
EMITTER
3.9V
C1
0.1
IRF7309 OR IRF7509
VCC
OUT
EN
VEEC
A8
7
6
5
ISO1
R1 2
3
3.3k
R3
10k
Q3 R5
R4
1K
D2
LED
R5
4.7K
1K D1
3.9V C3
10
HCPL2200 2N2222
UNDERVOLTAGE
LOCK-OUT OUTPUT
BUFFER SINGLE TO SPLIT
POWER SUPPLY
IN+
IN-
AN-937 (v.Int)
Input: 5V/div
Output : 5V/div
Horiz: 500ns/div
Figure 15b:
Waveforms of the circuit in Figure 21a
when loaded with 100nF
FILE: 01A-POL.DAT
VBATT1 5V/div
Output: 5V/div
Horiz: 20ms/div File: 01-UV.dat
Figure 16.
Start-up waveforms for the
circuit of Figure 15a.
Gate Voltage: 10V/div
C2 ripple voltage: 0.5V/div
Q1 drain voltage: 200V/div
Horiz: 5
µµ
s/div File: GPS-1.plt
Figure 17b.
Waveforms of the circuit in Figure
23a.C1 = 100 pF, R3 = 5.6 k, f = 50 kHz
Figure 17a.
Drive supply developed from the drain voltage
+15V
D3
15V
15VRTN
C2
0.1
R3
D2
1N4148
C1
R2
100 D1
1N4148
Q1
IRF840
R1
10
Q2
IRF840
R4
R
G2
DRVRTN
DRIVE
VCC(300V)
20 30 40 50 60 70 80 90 100
0
1
2
3
Frequency (kHz)
Zener Current (mA)
Figure 18
. Zener current (max output current)
for the circuit in Figure 23a.
Figure 19
. Start-up voltage at 50 kHz
for the circuit in Figure 23a.
Horiz.: 500
µµ
s/div File: GPS-3.PLT
C2 voltage: 5V/div.
AN-937 (v.Int)
They have the additional advantage of providing a negative gate bias. One additional limitation of pulse transformers is the fact
that the gate drive impedance is seriously degraded by the leakage inductance of the transformer. Best results are normally
obtained with a few turns of twisted AWG30 wire-wrap wire on a small ferrite core.
Lower gate drive impedance and a wider duty-cycle range can be obtained with the circuit in Figure 24a. In this circuit, Q1 and
Q2 (a single Micro-8 package) are used to buffer the input and drive the primary of the transformer. The complementary MOS
output stage insures low output impedance and performs wave shaping. The output stage is fed by a dc restorer made by C2 and
D1 that references the signal to the positive rail. D1 and D2 are also used to generate the gate drive voltage.
The input and output wave form with 1nF load capacitance are shown i n Figure 24b. The turn-on and turn-off delays are 50ns.
The rise and fall times are determined by the 10 Ohm resistor and the capacitive load. This circuit will operate reliably between
20 and 500 kHz, with on/off times from 0.5 to 15 microsecs.
Due to the lack of an under voltage lock-out feature, the power-up and power down behavior of the circuit is important.
Intentionally C1 and C2 are much bigger in value then C3 so that the voltage across C3 rises to an adequate level during the first
incoming pulse. The power-up wave forms at 50kHz switching frequency and 50% duty cycle are shown in Figure 25. During
the first pulse, the output voltage is 10V only, and drops back below 10V at the fifth pulse.
Gate voltage: 10V/div.
Drain voltage: 200V/div.
C2 ripple voltage: 1V/div
Horiz: 2
µµ
s/div File: gps-4.plt
Figure 20.
Waveforms of the circuit in
Figure 23a. with C1=680pF, R3=1k,
f=100kHz.
10 20 30 40 50 60 70 80 100
Frequency (kHz)
Zener Current (mA)
Figure 21
. Zener current (max output current)
for the circuit in Figure 23a.
with C1 = 680pF, R3 = 1k
20
10
090
C2 voltage: 5V/div
Horiz: 100
µµ
s/div. File: GPS-6.plt
Figure 22.
Start-up voltage at 100 kHz for the
circuit in Figure 23a. with C1=680pF, R3=R3=1k
0V
GS
Figure 23.
Volt-seconds across
winding must balance
AN-937 (v.Int)
8
2
4
56
1
3
+12V
IN
12VRTN
Q2
IR7509
Q1
IR7509
C1
1
T1 C2
1
D1
IN4148
D2
IN4148
1
Q3
2
3R2
10
R1
10
Q4
1
3
2C4
0.1
IN
100K
E
G
1n
LOAD
R3
IRFL014 OR IRFD014
T1: CORE: 331X1853E2A A1=2600 (PHILIPS, OD=0.625", Ae=0.153CM^2)
PRIMARY: 17T, SEC.: 27T
Figure 24a.
Improving the performance of a gate drive transformer
Figure 24b.
Waveforms associated with the circuit
of Figure 24a
Input: 5V/div.
Output: 5V/div.
HORIZ: 50
µµ
S/div. FILE: X2-START.PLT
Figure 25.
Waveforms during start-up for the circuit in
Figure 24a.
87
2
4
56
1
3
+12V
12VRTN
INPUT
C1
0.1
C1
0.47
T1
1
C2
VCC
IN
FAULT
VSCOM
CS
8
7
6
5
U2
1
4
IR2127/8
HO
VB
2
3
R3
8.2K D5
11DF6
R2
1K
C
G
R4
220 C5
10n
E
D4
11DQ04 100K
T1: CORE: 331X185 3E2A, A1=2600 (OD=0.625", Ae=0.153 CM^2)
PRIMARY: 17T, AWG 28 SEC: 27T, AWG 28
Figure 26a.
Transformer-coupled MGD with UV lockout and short-circuit protection
AN-937 (v.Int)
The power down of the circuit is smooth and free from voltage spikes. When the pulse train is interrupted at the input, the C2
capacitor keeps the input of the CMOS inverter high and R1 discharges C3. By the time the input to the CMOS inverter drops
below the threshold voltage of Q4, C3 is completely discharged the output remains low.
The addition of a MOS-Gate Driver IC improves the performance of the circuit in Figure 24a, at the expenses of prop delay. The
circuit shown in Figure 26a has the following features:
- No secondary supply required
- Propagation delay ~500ns (CL= 10nF)
- Duty cycle range 5% to 85%
- Nominal operating frequency 50kHz (20kHz to 100kHz)
- Short circuit protection with Vce sensing. Threshold Vce = 7.5V
- Undervoltage lock-out at Vcc = 9.5V
- Over voltage lock out at Vcc = 20V
The short circuit protection is implemented with a Vce sensing circuit in combination with the current sense input (CS) of
IR2127/8. When the HO pin if U2 goes high R3 starts charging C5. Meanwhile the IGBT turns on, the collector voltage drops to
the saturation level, D5 goes into conduction and C5 discharges. When the collector voltage is high, D5 is reverse biased and the
voltage on C5 keeps raising. When C5 voltage exceeds 250mV the IR2127/8 shuts down the output. The fault to shut-down
delay is approximately 2 microsecs.
For operation with a large duty cycle, several options are available. The circuits described in AN-950 use a saturating transformer
to transfer the drive charge to the gate. The circuit shown in Figure 28a, on the other hand, achieves operation over a wide range
of duty cycles by using the MGD as a latch. It has the following features:
- Frequency range from DC to 900kHz.
- Turn-on delay: 250ns.
- Turn-off delay 200ns
- Duty cycle range from 1% to 99% at 100kHz.
- Under voltage and over voltage lockout.
- Optional short circuit protection, as shown in Figure 26a
In the circuit of Figure 28a the transformer is small (8 turns), since it transmits only short pulses to the secondary side. The
MGD on the secondary side of the transformer is latched by the feedback resistor R4. Figures 28b and 28c show the performance
of this circuit at the two extremes of 900 kHz and 2.5 Hz
Horiz.: 500ns/div.
Output: 5V/div.
Input: 2V/div.
Figure 26b.
Waveforms associated with the
circuit of Figure 26a.
Input: 5V/div.
Output: 5V/div.
IR2121 ERR pin: 5V/div.
Horiz: 1
µµ
s/div. FILE: X1-ERR.PLT
Figure 27.
Shutdown due to high V
CEsat
AN-937 (v.Int)
7.2 Chopping gate drives
Chopper circuits can maintain a gate drive signal for an indefinite period of time, have good noise immunity performance and,
with some additional circuitry, the isolated supply can be avoided.
The basic operating principle is shown in Figure 29. To turn on the MOSFET, a burst of high frequency is transmitted to the
secondary side. The MOSFET is turned off by interrupting the high frequency. The diode and the bipolar transistor form a
crowbar that rapidly discharges the gate.
In addition to providing the gate drive signal, the high frequency transformer is frequently used to power auxiliary circuitry, like
short-circuit protection, thus avoiding a dedicated supply.
8. DRIVE REQUIREMENTS AND SWITCHING CHARACTERISTICS OF
LOGIC LEVEL HEXFET®S
Many applications require a power MOSFET to be driven directly from 5 V logic circuitry. The on-resistance of standard power
MOSFETs is specified at 10 V gate drive, and are generally not suitable for direct interfacing to 5V logic unless an oversized
MOSFET is employed.
87
2
4
56
1
3
+12V
12VRTN
IN
C1
1C2
1nF
T1 4.7K
R2 VCC
IN
ERR
VSVSS
CS
8
7
6
5
U1
1
4
IR2121
HO
VB
2
3
R4 18K
R5 18K
+15V
G
C3
1E
TRANSFORMER: CORE: 266CT125-3E2A, (OD=0.325", Ae=0.072cm,^2, A1=2135)
PRIMARY: 8T, AWG 28 SEC: 8T, AWG 28
Figure 28a.
Transformer-coupled MGD for operation from DC to 900 kHz
R1
560
R3
18K 15VRTN
IRF7509 OR IRF7309
Input: 2V/div.
Output: 25.ns/div.
Horiz.: 25.ns/div. File: XP-900K.PLT
Figure 28b.
Waveforms associated with the
circuit of Figure 28a operated at 900 kHz
Input: 5V/div.
Output: 10V/div.
Reference 60Hz: 10V/div.
Horiz: 50ms/div. File: XP-2P5HZ.PLT
Figure 28c. Waveforms associated with the circuit
of Figure 28a operated at 2.5 Hz
AN-937 (v.Int)
Logic level HEXFET®s are specifically designed for operation from 5V logic and have guaranteed on-resistance at 5 or 4.5 V
gate voltage. Some have guaranteed on-resistance at 2.7 V.
Some important considerations for driving logic level HEXFET®s are discussed in this section and typical switching performance
of these is illustrated when driven by some common logic drive circuits.
8.1 Comparison to Standard HEXFET®s
Some devices are available as Logic-level HEXFET®s as well as standard HEXFET®s. The logic-level version uses a thinner gate
oxide and different doping concentrations. This has the following effects on the input characteristics:
Gate Threshold voltage is lower.
Transconductance is higher.
Input capacitance is higher.
Gate-source breakdown voltage is lower.
While input characteristics are different, reverse transfer capacitance, on-resistance, drain-source breakdown voltage, avalanche
energy rating, and output capacitance are all essentially the same. Table 3 summarizes the essential comparisons between
standard and logic level HEXFET®s.
Characteristics and Ratings Standard HEXFET®
(IRF Series) Comparable Logic Level HEXFET®
(IRL Series)
Gate Threshold Voltage VGS(on) 2 - 4V 1 - 2V
On-Resistance RDS(on)
Logic level HEXFET®has same value of RDS(on)
VGS = 5V as standard HEXFET®at VGS = 10V
RDS(on) of logic level HEXFET®also speed at VGS = 4V
Transconductance gfs
Typically 39% larger for logic level HEXFET®
Input Capacitance Crs
Typically 33% larger for logic level HEXFET®
Output Capacitance Crss
Essentially the same
Reverse Transfer Capacitance Crss
Essentially the same
Gate Charge
Gate-Source Qgs
Essentially the same
Gate-Drain Qgd
Essentially the same
Total Qg Essentially same as
VGS = 10V Essentially same at
VGS = 5V
Drain Source Breakdown
Voltage BVDSS
Same
Continuous Drain Current ID
Same
Single Pulse Avalanche Energy EAS
Same
Max. Gate-Source Voltage VGS + 20V +10V
Table 3: Essential Comparisons of Standard and Logic Level HEXFET®s
The gate charge for full enhancement of the logic level HEXFET®is, however, about the same as for a standard
HEXFET®because the higher input capacitance is counteracted by lower threshold voltage and higher transconductance. Since
the logic level HEXFET®needs only one half the gate voltage, the drive energy is only about one half of that needed for the
standard HEXFET®. Since the gate voltage is halved, the gate drive resistance needed to deliver the gate charge in a given time
is also halved, relative to a standard HEXFET®. In other words, for the same switching speed as a standard HEXFET®power
MOSFET, the drive circuit impedance for the logic level HEXFET®must be approximately halved.
The equivalence of switching times at one half the gate resistance for the logic level HEXFET®is illustrated by the typical
switching times for the IRL540 and the IRF540 HEXFET®s shown in Table 4, using data sheet test conditions.
AN-937 (v.Int)
Gate Resistance
Gate Voltage Drain Current Typical Values (ns)
RG
()
VGS
(V) ID
(A) tD on trtD on tr
9
10 28 15 72 40 50
4.5
52815724456
Table 4: Typical Resistive Switching Times for IRL540 and IRF540
TTL families do not actually deliver 5V in their VOH condition, even into an open circuit. The 5V level can, however, be reached
by the addition of a pull-up resistor from the output pin to the 5V bus, as illustrated in Figure 30. Without the pull-up resistor,
the RDS(on) value at VGS = 5V may not be attained, and the value specified at VGS = 4V should be used for worst case design.
8.2 Driving Logic Level HEXFET®s
The gate threshold voltage of MOSFETs decreases with temperature. At high temperature it can approach the VOL(max)
specification of the logic driver. Care should be exercised to insure that VTH(min) at the highest operating temperature is greater
than VOL(max) of the various logic families in order to guarantee complete turn off.
555
7483
2
85
15 V
CONTROL
INPUT
470 LOAD
Figure 29.
+5V
LOGIC
INPUTS
RET
LOAD
Figure 30.
Pull-up resistor used
to deliver 5V gate drive
+V
DD
R1
Figure 31a.
High common mode inductance
R
L
D
L
D
G
L
S
S
L
W
RET.SIG. RET.
DRIVE
+V
DD
R1
Figure 31b.
Minimum common mode
inductance
R
L
D
L
D
G
L
S
S
L
W
RET.SIG. RET.
AN-937 (v.Int)
Common source inductance plays a significant role in switching performance. In the circuit of Figure 31a the switching
performance is degraded due to the fact that VGS is reduced by (LS + LW) di/dt, where di/dt is the rate of change of the drain
current. By eliminating LW from the drive circuit, VGS can approach the applied drive voltage because only LS (the internal
source inductance) is common.
This can be done by separately connecting the power return and the drive signal return to the source pin of the switching
HEXFET®, as shown in Figure 31b. Thus, the load current ID does not flow through any of the external wiring of the drive
circuit; consequently, only the internal source inductance LS is common to both load and drive circuits.
In the case of logic level HEXFET®s, for which VGS is 5V and not 10V, the loss of drive voltage due to common mode
inductance has proportionately twice the effect as it would on a 10V drive signal, even though actual values of LS and LW are the
same.
8.3 Resistive Switching Tests
In the following tests of switching performance, the physical layout of the test circuit was carefully executed so to minimize the
common source inductance. The following precautions were also observed:
1. RL was built by paralleling 0.5W resistors to achieve the desired load resistance (see Table 5).
2. To minimize inductance in the load circuit, a 10 µF low-ESR low-ESL capacitor was connected directly from +VDD to the
source of the DUT.
3. To provide a low source impedance for the 5V gate pulse of the DUT, a 0.1 µF low-ESR low-ESL capacitor was connected
directly between pin 14 and pin 7 of the driver IC.
4. To provide minimum common source impedance, the source of the DUT was the common return point of all ac and dc
system grounds.
5. To reduce stray inductances and thus achieve maximum switching speeds, the physical size of the high current loop (RL,
DUT, 10 µF) was reduced to the smallest practical limits.
Only the 5 volt families have been tested as logic level HEXFET®drives: bipolar and CMOS (and their derivatives), as indicated
below.
TTL GATES
DM7400N: Standard TTL
74F00PC: High Speed TTL
DM74S00N: Schottky TTL
DM74LS00N: Low Power Schottky TTL
DM74AS00N: Advanced Schottky TTL
+V
DD
= 0.5 BV
DSS
Figure 32.
Switching test circuit. Logic level driver is one-quarter of a quad
NAND gate.
R
L
DUT
+5V
0.1pF0.1pF
3
15
1
2
7, 4, 5, 9
10, 12, 13
50
V
SS
+5V0 SIG. GEN.
SCOPE
AN-937 (v.Int)
CMOS GATES
74AC00PC: Advanced CMOS
74ACT00PC: TTL Compatible CMOS
MM74HC00N: Micro CMOS
MM74HCT00N: TTL Compatible Micro CMOS
BIPOLAR
DS0026: High Speed MOSFET Driver
The test conditions for the resistive switching performance is shown in Table 5. The resistive switching times obtained with the
above TTL and CMOS gates are tabulated in Table 6. In this table ton = Time in microseconds from 90% to 10% VDD and toff =
Time in microseconds from 10% to 90% VDD. Inductive switching gives faster voltage rise times than resistive switching due to
the resonant charging of the output capacitance of the device. Voltage fall times are essentially the same.
LOGIC LEVEL
HEXFET®SWITCHING
VOLTAGE
(V)
SWITCHING CURRENT
(A) RDSON
()RL
()
IRLZ14
IRLZ24
IRLZ34
IRLZ44
IRLZ514
IRLZ524
IRLZ524
IRLZ544
30
30
30
30
50
50
50
50
8
16
24
40
5
8
12
25
0.24
0.12
0.06
0.034
0.60
0.30
0.18
0.085
3.25
1.5
1.2
0.7
9.5
5.9
4.0
1.9
Table 5. Resistive Switching Conditions
Logic Family Logic Level HEXFET®,
Quad, Dual Input IRLZ14 IRLZ24 IRLZ34 IRLZ44 IRL514
IRL524
IRL534
IRL544
Nand Gate ton toff ton toff ton toff ton toff ton toff
toff ton toff ton
DM7400N
STANDARD TTL 0.173 0.018 0.663 0.026 0.700 0.076 1.491 0.146 0.151 0.022
0.041 0.263 0.060 0.616
7400FDOPC
HIGH SPEED TTL 0.124 0.008 0.490 0.013 0.429 0.068 0.863 0.146 0.104 0.004
0.034 0.176 0.059 0.372
DM7400
SCHOTTKY TTL 0.133 0.092 0.549 0.020 0.503 0.032 1.068 0.142 0.116 0.006
0.041 0.212 0.057 0.441
DM74LS
LOW POWER SCHOTTKY TTL 0.174 0.038 0.778 0.093 0.706 0.146 1.438 0.342 0.155 0.040
0.062 0.267 0.090 0.567
DM4SDON
ADVANCED SCHOTTKY TTL 0.126 0.008 0.567 0.013 0.446 0.023 0.896 0.149 0.111 0.005
0.127 0.176 0.058 0.336
74ACOOPC
ADVANCED CMOS 0.012 0.007 0.120 0.012 0.125 0.027 0.251 0.139 0.036 0.004
0.028 0.066 0.055 0.125
74ACTOOPC
TTL COMPATIBLE CMOS 0.012 0.006 0.121 0.011 0.125 0.016 0.233 0.127 0.033 0.044
0.027 0.060 0.055 0.120
MM74CHCOON
MICRO CMOS 0.066 0.039 0.179 0.091 0.227 0.147 0.508 0.328 0.058 0.044
0.068 0.111 0.096 0.232
MM74HCTCO4
TTL COMPATIBLE MICRO CMOS 0.066 0.030 0.179 0.060 0.227 0.123 0.504 0.269 0.068 0.035
0.051 0.111 0.086 0.232
DS0026
HIGH SPEED MOSFET DRIVER 0.052 0.005 0.016 0.005 0.014 0.007 0.032 0.016 0.021 0.004
0.004 0.036 0.005 0.029
Table 6. Results of the resistive load switching test
Typical Test Oscillograms
IRLZ24: 60V, 0.1 Ohm, N-Channel, TO-220 logic level HEXFET®was driven by each of the logic families listed in Table 4 and
the comparative resistive switching times photographed.
AN-937 (v.Int)
9. SIMPLE AND INEXPENSIVE METHODS TO GENERATE ISOLATED
GATE DRIVE SUPPLIES
.
In several applications, dc-to-dc converters are used to power the MOS Gate Driver. Although the gate drive requires little
power, the noisy environment, the isolation voltage and creepage distance requirements and the high dv/dt between the primary
and secondary size make the design of the DC-to-DC converter somewhat complicated. Its key parameters are listed below:
OUTPUT VOLTAGE, CURRENT. The output voltage of the DC-to-DC converter is the sum of the positive and negative drive
voltage to the gate. The load current required from the DC-to-DC converter is the sum of the current consumption of the drive
circuit and the average drive current to the gate.
dv/dt CAPABILITY. When the DC-
DC converter powers a high side
switch, the secondary side of the
converter is connected to the output of
the power circuit. The rapid change of
high voltage at the output of power
circuit stresses the isolation of the
transformer and injects noise to the
primary side of the transformer.
Switching noise at the primary side
disturbs the operation of the converter
and the control circuit for the power
stage, causing false triggering and
shoot-through. Therefore a
transformer with high voltage
isolation, appropriate creepage
distances and low winding-to-
winding capacitance is required i n this
application.
SMALL SIZE. To reduce the interwinding capacitances the transformer must be made small. This implies operation at high
frequency. Small size and compact layout help reducing the EMI and RFI generated by the converter. Figure 33a shows a
forward converter made with two CD4093 gates to generate the clock and drive the MOSFET. Energy as transferred to the
secondary when the MOSFET is on, in about 33% of the cycle. When the MOSFET is off, the secondary winding is used to
demagnetize the transformer and transfer the magnetizing energy to the load, thus eliminating the need for a demagnetizing
winding. The switching waveforms are shown in Figure 33b. The ringing in the drain voltage during the fly-back period is due to
the loose coupling between the primary and the secondary windings. The load current vs. output voltage characteristic of the
circuit is shown in Figure 34. When the output current falls below 5 mA, the circuit works as flyback converter because the
demagnetizing current flows through the output. A minimum load of 5mA is required to limit the output voltage at 15V.
+12V
Figure 33a.
100 kHz Forward converter
13
12 11 100
1
µµ
F
IRFD110
1N4148
12K
20K
5
64
CD4093
1n
12V
RTN
1
µµ
F
T1
4X
IN4148 V
0
R
L
f = 100kHz
T1 TRANSFORMER: DORE: PHILIPS 240XT250-3EA2 TOROID
(OD = 0.75", Ae=0.148CM^2, AI=3000)
PRIMARY: 14 TURNS, AWG 30 TEFLON INSULATED WIRE
SECONDARY: 24 TURNS, AWG 30 TEFLON INSULATED WIRE
Gate voltage: 5V/div.
Drain voltage: 10V/div.
Horiz: 2
µµ
s/div.
Figure 33b.
Waveforms associated with the
circuit in Figure 33a
35
30
25
20
15
10 0 20 40 60 80 100 120
Load current (mA)
Output Voltage (V)
Figure 34.
Load current vs. output voltage at 100 kHz,
Rout = 27.7 Ohms
AN-937 (v.Int)
If the converter is loaded with a
constant and predictable load, a zener
can provide the necessary regulation.
Otherwise a three-terminal regulator
or a small zener-driven MOSFET may
be necessary.
The circuit in Figure 35a is similar to
the previous one, except that the
higher switching frequency is higher
(500 kHz) and the transformer is
smaller. The remaining three gates in
the package are connected in parallel
to drive the MOSFET and reduce the
switching losses. The switching
waveforms are shown in Figure 35b.
The output resistance (Rout) of this
circuit is higher than the circuit shown
in Figure 33a, mainly because the
stray inductance of the smaller transformer is higher and the effects of the stray inductance are higher. Figure 37a shows a push-
pull operated at 500 kHz. The single gate oscillator produces a 50% duty cycle output, while the remaining gates in the package
are used to drive the push-pull output stage. The primary of the transformer sees half the voltage compared to the previous
circuit, therefore the number of turns at the primary were reduced to half.
10. PHOTOVOLTAIC GENERATORS AS GATE DRIVERS
A photovoltaic generator is a solid state power supply powered by light, normally an LED. The combination of the LED and the
photovoltaic generator in one package is called a Photovoltaic Isolator or PVI and is available in a 8-pin DIP package. As a
voltage source, the PVI can function as a “dc transformer” by providing an isolated low current to a load. While an optoisolator
requires a bias supply to transmit a signal across a galvanic barrier, the PVI actually transmits the energy across the barrier.
More information on the PVI can be found in Application Note GBAN-PVI-1 which appears in the Microelectronic Relay
Designer’ s Manual. This data book also contains the data sheet for the photovoltaic isolator, the PVI1050. A circuit is also
provided in the AN to significantly speed up turn off of the switch. As a gate driver the PVI has significant limitations: its short
circuit current is in the order of 30 microA with a very high internal impedance. Its simplicity, however, makes it appealing in
solid-state relay replacements, where switching times are not important and switching transients are not present.
A typical application is the ac switch described below. The IGBT and the power MOSFET are not suited to switching AC
waveforms directly. The IGBT can only conduct current in one direction while the power MOSFET has an anti-parallel diode
that will conduct during every negative half-cycle. Bidirectional blocking capability can be achieved by connecting two power
MOSFETs source to source, or two IGBTs with anti-parallel diodes emitter to emitter, as shown in Figure 39.
+12V
Figure 35a.
500 kHz Forward converter
13
12 11 100
1
µµ
F
IRFD110
1N4148
1K
6K
5
64
CD4093
220p
12V
RTN
1
µµ
F
T1
4X
IN4148 V
0
R
L
f = 500kHz
T1: CORE: PHILIPS 266CT125-3E2A (od=0.375", Ae=0.072CM^2, AL=2135
PRIMARY: 4T, AWG 30, SECONDARY: 7T, AWG30
9
810
1
23
14
7
30
25
20
15
10
0102030 5040
Load current (mA)
Output voltage (V)
Figure 36.
Load current vs. output voltage,
Rout = 27.7 Ohms
Drain Voltage: 10V/div.
Gate voltage: 5V/div.
Horiz.: 250ns/div.
Figure 35b.
Waveforms associated with the
circuit in Figure 35a
AN-937 (v.Int)
In the case of the MOSFET, there is the possibility that, for low current levels, the current flows through both MOSFET
channels, instead that one MOSFETs and diode, thereby achieving lower overall voltage drop. The MOSFET channel is a
bidirectional switch, that is, it can conduct current in the reverse direction.
If the voltage across the MOSFET
channel is less than the VF of the
intrinsic diode (which typically has a
higher VF than discrete diodes), then
the majority of the current will flow
through the MOSFET channel
instead of the intrinsic diode. The
gate drive for both the MOSFETs and
IGBTs must be referenced to the
common sources or emitters of the
devices. Since this node will be
swinging with the AC waveform, an
isolated drive is necessary. The PVI
can be used, as shown in Figure 40.
11. RESONANT GATE DRIVE TECHNIQUES
As indicated in Section 14, gate drive losses in hard switching are
equal to Qgs x Vgs x f. An IRF630 operated at 10 Mhz with a
gate voltage of 12 V would have gate drive losses of 3.6 W,
independent from the value of the gate drive resistor. Clearly, to
achieve hard switching at this frequency, the resistance of the gate
drive circuit is limited to whatever is associated with the internal
impedance of the driver and with the gate structure of the device
itself. Furthermore, the stray inductance of the gate drive circuit
must be limited to tens of nH. The design and layout of such a
circuit is not an easy task.
An alternative method to drive the gate in such an application is
to design a resonant circuit that makes use of the gate capacitance
and stray inductance as its reactive components, adding whatever
inductance is necessary to achieve resonance at the desired
frequency. This method can reduce the peak of the gate drive
current and losses in half, while simplifying the design of the gate
drive circuit itself. Since the gate charge is not dissipated at every
switching transition, but stored in a reactive component, the gate
drive losses are proportional to the resistance of the gate drive
circuit, rather than being independent from it. More information
on this gate drive method can be found in an article by El-
Hamamsy: Design of High-Efficiency RF Class-D Power
Amplifier and in references at the end of this article (IEEE
Transactions on Power Electronics, May 1994, page 297).
Related Topics
MOS-Gate Driver Ics
Transformer drive with wide duty cycle capability
Gate Charge
Three-phase MOS-Gate Driver
Photovoltaic Isolators (PVI)
+12V
Figure 37a.
500 kHz Forward converter
13
12 11 100
1
µµ
F
10K
5
64
CD4093
220p
12V
RTN
1
µµ
F
T1
1N4148 V
0
R
L
f = 500kHz
T1: CORE: PHILIPS 266CT125-3E2A (od=0.375", Ae=0.072CM^2, AL=2135
PRIMARY: 4T, AWG 30, SECONDARY: 7T, AWG30
9
810
1
23
14
7
7, 8
2
4
5, 6
1
37T
1N4148
100nF
100nF
2T
IRF7307
Buffer input: 5V/div.
Buffer Output: 5V/div.
Horiz.: 500ns/div
Figure 37b.
Waveforms associated with the circuit in Figure 37a
20
19
18
17
16
15
14
13 0 1020 30405060
Figure 38.
Load current vs. output voltage,
Rout=27.7 Ohms