ONSEMI MTD9N10E1

MTD9N10E
Preferred Device
Power MOSFET
9 Amps, 100 Volts
N–Channel DPAK
This advanced Power MOSFET is designed to withstand high
energy in the avalanche and commutation modes. The new energy
efficient design also offers a drain–to–source diode with a fast
recovery time. Designed for low voltage, high speed switching
applications in power supplies, converters and PWM motor controls,
these devices are particularly well suited for bridge circuits where
diode speed and commutating safe operating areas are critical and
offer additional safety margin against unexpected voltage transients.
• Avalanche Energy Specified
• Source–to–Drain Diode Recovery Time Comparable to a
Discrete Fast Recovery Diode
• Diode is Characterized for Use in Bridge Circuits
• IDSS and VDS(on) Specified at Elevated Temperature
• Replaces MTD6N10
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9 AMPERES
100 VOLTS
RDS(on) = 250 mΩ
N–Channel
D
G
S
MAXIMUM RATINGS (TC = 25°C unless otherwise noted)
Symbol
Value
Unit
Drain–Source Voltage
VDSS
100
Vdc
Drain–Gate Voltage (RGS = 1.0 MΩ)
VDGR
100
Vdc
Rating
Gate–Source Voltage
– Continuous
– Non–Repetitive (tp ≤ 10 ms)
4
VGS
VGSM
± 20
± 30
Vdc
Vpk
Drain Current – Continuous
Drain Current – Continuous @ 100°C
Drain Current – Single Pulse (tp ≤ 10 µs)
ID
ID
IDM
9.0
5.0
27
Adc
Total Power Dissipation
Derate above 25°C
Total Power Dissipation @ TA = 25°C, when
mounted to minimum recommended pad
size
PD
40
0.32
1.75
Watts
W/°C
Watts
Operating and Storage Temperature
Range
Single Pulse Drain–to–Source Avalanche
Energy – Starting TJ = 25°C
(VDD = 25 Vdc, VGS = 10 Vdc,
IL = 9.0 Apk, L = 1.0 mH, RG = 25 Ω)
Thermal Resistance
– Junction to Case
– Junction to Ambient
– Junction to Ambient, when mounted
to minimum recommended pad size
Maximum Temperature for Soldering
Purposes, 1/8″ from case for 10
seconds
MARKING
DIAGRAM
Apk
1 2
3
Y
WW
T9
YWW
T9
N10E
CASE 369A
DPAK
STYLE 2
= Year
= Work Week
= MOSFET
PIN ASSIGNMENT
4
Drain
TJ, Tstg
–55 to
150
°C
EAS
40
mJ
1
Gate
°C/W
RθJC
RθJA
RθJA
3.13
100
71.4
TL
260
3
Source
ORDERING INFORMATION
Device
°C
2
Drain
Package
Shipping
MTD9N10E
DPAK
75 Units/Rail
MTD9N10E1
DPAK
75 Units/Rail
MTD9N10ET4
DPAK
2500 Tape & Reel
Preferred devices are recommended choices for future use
and best overall value.
 Semiconductor Components Industries, LLC, 2001
February, 2001 – Rev. 4
1
Publication Order Number:
MTD9N10E/D
MTD9N10E
ELECTRICAL CHARACTERISTICS (TJ = 25°C unless otherwise noted)
Symbol
Characteristic
Min
Typ
Max
Unit
100
–
–
103
–
–
Vdc
mV/°C
–
–
–
–
10
100
–
–
100
nAdc
2.0
–
–
6.0
4.0
–
Vdc
mV/°C
–
0.17
0.25
Ohm
–
–
–
–
2.43
2.40
gFS
4.0
–
–
mhos
Ciss
–
610
1200
pF
Coss
–
176
400
Crss
–
14
30
td(on)
–
8.8
20
tr
–
28
60
td(off)
–
16
30
tf
–
4.8
10
QT
–
14
21
Q1
–
5.2
–
Q2
–
3.2
–
Q3
–
6.6
–
–
–
0.98
0.9
1.8
–
trr
–
91
–
ta
–
71
–
OFF CHARACTERISTICS
V(BR)DSS
Drain–Source Breakdown Voltage
(VGS = 0 Vdc, ID = 250 µAdc)
Temperature Coefficient (Positive)
Zero Gate Voltage Drain Current
(VDS = 100 Vdc, VGS = 0 Vdc)
(VDS = 100 Vdc, VGS = 0 Vdc, TJ = 125°C)
IDSS
Gate–Body Leakage Current (VGS = ± 20 Vdc, VDS = 0)
IGSS
µAdc
ON CHARACTERISTICS (Note 1.)
Gate Threshold Voltage
(VDS = VGS, ID = 250 µAdc)
Temperature Coefficient (Negative)
VGS(th)
Static Drain–Source On–Resistance (VGS = 10 Vdc, ID = 4.5 Adc)
RDS(on)
Drain–Source On–Voltage (VGS = 10 Vdc)
(ID = 9.0 Adc)
(ID = 4.5 Adc, TJ = 125°C)
VDS(on)
Forward Transconductance (VDS = 8.0 Vdc, ID = 4.5 Adc)
Vdc
DYNAMIC CHARACTERISTICS
Input Capacitance
Output Capacitance
(VDS = 25 Vd
Vdc, VGS = 0 Vdc,
Vd
f = 1.0 MHz)
Reverse Transfer Capacitance
SWITCHING CHARACTERISTICS (Note 2.)
Turn–On Delay Time
Rise Time
Turn–Off Delay Time
(VDD = 50 Vdc, ID = 9.0 Adc,
Vdc
VGS = 10 Vdc,
RG = 9.1 Ω)
Fall Time
Gate Charge
g
(S Figure
(See
Fi
8)
(VDS = 80 Vdc, ID = 9.0 Adc,
VGS = 10 Vdc)
ns
nC
SOURCE–DRAIN DIODE CHARACTERISTICS
Forward On–Voltage (Note 1.)
(IS = 9.0 Adc, VGS = 0 Vdc)
(IS = 9.0 Adc, VGS = 0 Vdc,
TJ = 125°C)
Reverse Recovery
y Time
(S Figure
(See
Fi
14)
(IS = 9.0
9 0 Adc,
Adc VGS = 0 Vdc,
Vdc
dIS/dt = 100 A/µs)
VSD
Vdc
ns
tb
–
20
–
QRR
–
0.4
–
µC
Internal Drain Inductance
(Measured from the drain lead 0.25″ from package to center of die)
LD
–
4.5
–
nH
Internal Source Inductance
(Measured from the source lead 0.25″ from package to source bond pad)
LS
–
7.5
–
nH
Reverse Recovery Stored
Charge
INTERNAL PACKAGE INDUCTANCE
1. Pulse Test: Pulse Width ≤ 300 µs, Duty Cycle ≤ 2%.
2. Switching characteristics are independent of operating junction temperature.
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2
MTD9N10E
TYPICAL ELECTRICAL CHARACTERISTICS
18
14
8V
7V
12
10
8
6V
6
4
5V
2
0
1
3
2
4
5
6
7
9
8
100°C
10
8
6
4
VGS, GATE-TO-SOURCE VOLTAGE (VOLTS)
Figure 1. On–Region Characteristics
Figure 2. Transfer Characteristics
VGS = 10 V
TJ = 100°C
0.30
0.25
25°C
0.20
0.15
-55°C
0
25°C
12
VDS, DRAIN-TO-SOURCE VOLTAGE (VOLTS)
0.35
0.10
14
0
2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 7.5 8.0 8.5 9.0
10
0.45
0.40
2
4
6
8
12
10
ID, DRAIN CURRENT (AMPS)
14
16
18
0.25
TJ = 25°C
0.23
0.21
0.19
VGS =10V
0.17
15 V
0.15
1.9
8
10
6
12
ID, DRAIN CURRENT (AMPS)
14
16
18
100
VGS =0V
VGS = 10 V
ID =4.5 A
1.5
1.3
1.1
0.9
10
TJ = 125°C
100°C
1.0
25°C
0.7
0.5
-50
4
Figure 4. On–Resistance versus Drain Current
and Gate Voltage
I DSS , LEAKAGE (nA)
RDS(on) , DRAIN-TO-SOURCE RESISTANCE
(NORMALIZED)
2
0
Figure 3. On–Resistance versus Drain Current
and Temperature
1.7
TJ = -55°C
2
4V
RDS(on) , DRAIN-TO-SOURCE RESISTANCE (OHMS)
RDS(on) , DRAIN-TO-SOURCE RESISTANCE (OHMS)
0
VDS ≥ 10 V
16
I D , DRAIN CURRENT (AMPS)
I D , DRAIN CURRENT (AMPS)
16
18
TJ = 25°C
VGS =10V
-25
0
25
50
75
100
TJ, JUNCTION TEMPERATURE (°C)
125
0.1
30
150
Figure 5. On–Resistance Variation with
Temperature
40
60
80
90
50
70
VDS, DRAIN-TO-SOURCE VOLTAGE (VOLTS)
Figure 6. Drain–To–Source Leakage
Current versus Voltage
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100
MTD9N10E
POWER MOSFET SWITCHING
The capacitance (Ciss) is read from the capacitance curve at
a voltage corresponding to the off–state condition when
calculating td(on) and is read at a voltage corresponding to the
on–state when calculating td(off).
At high switching speeds, parasitic circuit elements
complicate the analysis. The inductance of the MOSFET
source lead, inside the package and in the circuit wiring
which is common to both the drain and gate current paths,
produces a voltage at the source which reduces the gate drive
current. The voltage is determined by Ldi/dt, but since di/dt
is a function of drain current, the mathematical solution is
complex. The MOSFET output capacitance also
complicates the mathematics. And finally, MOSFETs have
finite internal gate resistance which effectively adds to the
resistance of the driving source, but the internal resistance
is difficult to measure and, consequently, is not specified.
The resistive switching time variation versus gate
resistance (Figure 9) shows how typical switching
performance is affected by the parasitic circuit elements. If
the parasitics were not present, the slope of the curves would
maintain a value of unity regardless of the switching speed.
The circuit used to obtain the data is constructed to minimize
common inductance in the drain and gate circuit loops and
is believed readily achievable with board mounted
components. Most power electronic loads are inductive; the
data in the figure is taken with a resistive load, which
approximates an optimally snubbed inductive load. Power
MOSFETs may be safely operated into an inductive load;
however, snubbing reduces switching losses.
Switching behavior is most easily modeled and predicted
by recognizing that the power MOSFET is charge
controlled. The lengths of various switching intervals (∆t)
are determined by how fast the FET input capacitance can
be charged by current from the generator.
The published capacitance data is difficult to use for
calculating rise and fall because drain–gate capacitance
varies greatly with applied voltage. Accordingly, gate
charge data is used. In most cases, a satisfactory estimate
of average input current (IG(AV)) can be made from a
rudimentary analysis of the drive circuit so that
t = Q/IG(AV)
During the rise and fall time interval when switching a
resistive load, VGS remains virtually constant at a level
known as the plateau voltage, VSGP. Therefore, rise and fall
times may be approximated by the following:
tr = Q2 x RG/(VGG – VGSP)
tf = Q2 x RG/VGSP
where
VGG = the gate drive voltage, which varies from zero to VGG
RG = the gate drive resistance
and Q2 and VGSP are read from the gate charge curve.
During the turn–on and turn–off delay times, gate current
is not constant. The simplest calculation uses appropriate
values from the capacitance curves in a standard equation
for voltage change in an RC network. The equations are:
td(on) = RG Ciss In [VGG/(VGG – VGSP)]
td(off) = RG Ciss In (VGG/VGSP)
1200
C, CAPACITANCE (pF)
1000
VDS = 0
VGS = 0
Ciss
TJ = 25°C
800
600
Ciss
Crss
400
Coss
200
0
10
Crss
5
VGS
0
VDS
5
10
15
20
GATE-TO-SOURCE OR DRAIN-TO-SOURCE VOLTAGE (VOLTS)
Figure 7. Capacitance Variation
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4
25
12
VDD = 50 V
ID = 9 A
VGS = 10 V
TJ = 25°C
VGS
Q2
8
80
Q1
6
60
4
ID = 9 A
TJ = 25°C
40
2
20
Q3
0
2
VDS
0
14
12
4
6
8
10
QG, TOTAL GATE CHARGE (nC)
t, TIME (ns)
100
10
0
100
120
QT
VDS , DRAIN-TO-SOURCE VOLTAGE (VOLTS)
VGS, GATE-TO-SOURCE VOLTAGE (VOLTS)
MTD9N10E
tr
td(off)
10
td(on)
tf
1
1
10
RG, GATE RESISTANCE (OHMS)
Figure 8. Gate–To–Source and Drain–To–Source
Voltage versus Total Charge
100
Figure 9. Resistive Switching Time
Variation versus Gate Resistance
DRAIN–TO–SOURCE DIODE CHARACTERISTICS
9
VGS = 0 V
TJ = 25°C
I S , SOURCE CURRENT (AMPS)
8
7
6
5
4
3
2
1
0
0.5
0.55
0.6
0.65
0.7
0.75
0.8
0.85
0.9
0.95
1.0
VSD, SOURCE-TO-DRAIN VOLTAGE (VOLTS)
Figure 10. Diode Forward Voltage versus Current
SAFE OPERATING AREA
reliable operation, the stored energy from circuit inductance
dissipated in the transistor while in avalanche must be less
than the rated limit and adjusted for operating conditions
differing from those specified. Although industry practice is
to rate in terms of energy, avalanche energy capability is not
a constant. The energy rating decreases non–linearly with an
increase of peak current in avalanche and peak junction
temperature.
Although many E–FETs can withstand the stress of
drain–to–source avalanche at currents up to rated pulsed
current (IDM), the energy rating is specified at rated
continuous current (ID), in accordance with industry
custom. The energy rating must be derated for temperature
as shown in the accompanying graph (Figure 12). Maximum
energy at currents below rated continuous ID can safely be
assumed to equal the values indicated.
The Forward Biased Safe Operating Area curves define
the maximum simultaneous drain–to–source voltage and
drain current that a transistor can handle safely when it is
forward biased. Curves are based upon maximum peak
junction temperature and a case temperature (TC) of 25°C.
Peak repetitive pulsed power limits are determined by using
the thermal response data in conjunction with the procedures
discussed
in
AN569,
“Transient
Thermal
Resistance–General Data and Its Use.”
Switching between the off–state and the on–state may
traverse any load line provided neither rated peak current
(IDM) nor rated voltage (VDSS) is exceeded and the
transition time (tr,tf) do not exceed 10 µs. In addition the total
power averaged over a complete switching cycle must not
exceed (TJ(MAX) – TC)/(RθJC).
A Power MOSFET designated E–FET can be safely used
in switching circuits with unclamped inductive loads. For
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MTD9N10E
SAFE OPERATING AREA
40
VGS = 20 V
SINGLE
PULSE
TC = 25°C
10
10 µs
100 µs
1 ms
1.0
10 ms
dc
0.1
RDS(on) LIMIT
THERMAL LIMIT
PACKAGE LIMIT
0.01
0.1
10
1.0
VDS, DRAIN-TO-SOURCE VOLTAGE (VOLTS)
ID = 9 A
EAS, SINGLE PULSE DRAIN-TO-SOURCE
AVALANCHE ENERGY (mJ)
I D , DRAIN CURRENT (AMPS)
100
32
24
16
8
0
25
100
Figure 11. Maximum Rated Forward Biased
Safe Operating Area
50
75
100
125
TJ, STARTING JUNCTION TEMPERATURE (°C)
150
Figure 12. Maximum Avalanche Energy versus
Starting Junction Temperature
r(t), NORMALIZED EFFECTIVE
TRANSIENT THERMAL RESISTANCE
1.0
D = 0.5
0.2
0.1
0.1
P(pk)
0.05
0.02
t1
0.01
t2
DUTY CYCLE, D = t1/t2
SINGLE PULSE
0.01
1.0E-05
1.0E-04
1.0E-03
1.0E-02
t, TIME (s)
1.0E-01
Figure 13. Thermal Response
di/dt
IS
trr
ta
tb
TIME
0.25 IS
tp
IS
Figure 14. Diode Reverse Recovery Waveform
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RθJC(t) = r(t) RθJC
D CURVES APPLY FOR POWER
PULSE TRAIN SHOWN
READ TIME AT t1
TJ(pk) - TC = P(pk) RθJC(t)
1.0E+00
1.0E+01
MTD9N10E
INFORMATION FOR USING THE DPAK SURFACE MOUNT PACKAGE
RECOMMENDED FOOTPRINT FOR SURFACE MOUNTED APPLICATIONS
Surface mount board layout is a critical portion of the
total design. The footprint for the semiconductor packages
must be the correct size to ensure proper solder connection
interface between the board and the package. With the
correct pad geometry, the packages will self align when
subjected to a solder reflow process.
0.165
4.191
0.100
2.54
0.118
3.0
0.063
1.6
0.190
4.826
0.243
6.172
inches
mm
POWER DISSIPATION FOR A SURFACE MOUNT DEVICE
PD = 150°C – 25°C = 1.75 Watts
71.4°C/W
The power dissipation for a surface mount device is a
function of the drain pad size. These can vary from the
minimum pad size for soldering to a pad size given for
maximum power dissipation. Power dissipation for a
surface mount device is determined by TJ(max), the
maximum rated junction temperature of the die, RθJA, the
thermal resistance from the device junction to ambient, and
the operating temperature, TA. Using the values provided
on the data sheet, PD can be calculated as follows:
PD =
The 71.4°C/W for the DPAK package assumes the use of
the recommended footprint on a glass epoxy printed circuit
board to achieve a power dissipation of 1.75 Watts. There
are other alternatives to achieving higher power dissipation
from the surface mount packages. One is to increase the
area of the drain pad. By increasing the area of the drain
pad, the power dissipation can be increased. Although one
can almost double the power dissipation with this method,
one will be giving up area on the printed circuit board
which can defeat the purpose of using surface mount
technology. For example, a graph of RθJA versus drain pad
area is shown in Figure 15.
TJ(max) – TA
RθJA
The values for the equation are found in the maximum
ratings table on the data sheet. Substituting these values
into the equation for an ambient temperature TA of 25°C,
one can calculate the power dissipation of the device. For a
DPAK device, PD is calculated as follows.
R
JA , Thermal Resistance, Junction
to Ambient (C/W)
100
Board Material = 0.0625″
G-10/FR-4, 2 oz Copper
1.75 Watts
80
TA = 25°C
°
60
3.0 Watts
θ
40
20
0
5.0 Watts
2
4
6
A, Area (square inches)
8
10
Figure 15. Thermal Resistance versus Drain Pad
Area for the DPAK Package (Typical)
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MTD9N10E
Another alternative would be to use a ceramic substrate
or an aluminum core board such as Thermal Clad. Using
a board material such as Thermal Clad, an aluminum core
board, the power dissipation can be doubled using the same
footprint.
SOLDER STENCIL GUIDELINES
pattern of the opening in the stencil for the drain pad is not
critical as long as it allows approximately 50% of the pad to
be covered with paste.
Prior to placing surface mount components onto a printed
circuit board, solder paste must be applied to the pads.
Solder stencils are used to screen the optimum amount.
These stencils are typically 0.008 inches thick and may be
made of brass or stainless steel. For packages such as the
SC–59, SC–70/SOT–323, SOD–123, SOT–23, SOT–143,
SOT–223, SO–8, SO–14, SO–16, and SMB/SMC diode
packages, the stencil opening should be the same as the pad
size or a 1:1 registration. This is not the case with the DPAK
and D2PAK packages. If one uses a 1:1 opening to screen
solder onto the drain pad, misalignment and/or
“tombstoning” may occur due to an excess of solder. For
these two packages, the opening in the stencil for the paste
should be approximately 50% of the tab area. The opening
for the leads is still a 1:1 registration. Figure 16 shows a
typical stencil for the DPAK and D2PAK packages. The
ÇÇ
ÇÇ
ÇÇ
ÇÇ
ÇÇÇ
ÇÇÇ ÇÇ
ÇÇÇ
ÇÇÇ
ÇÇ
ÇÇÇ
ÇÇÇ
ÇÇÇ
ÇÇÇ
SOLDER PASTE
OPENINGS
STENCIL
Figure 16. Typical Stencil for DPAK and
D2PAK Packages
SOLDERING PRECAUTIONS
• When shifting from preheating to soldering, the
maximum temperature gradient shall be 5°C or less.
• After soldering has been completed, the device should
be allowed to cool naturally for at least three minutes.
Gradual cooling should be used as the use of forced
cooling will increase the temperature gradient and
result in latent failure due to mechanical stress.
• Mechanical stress or shock should not be applied
during cooling.
The melting temperature of solder is higher than the rated
temperature of the device. When the entire device is heated
to a high temperature, failure to complete soldering within
a short time could result in device failure. Therefore, the
following items should always be observed in order to
minimize the thermal stress to which the devices are
subjected.
• Always preheat the device.
• The delta temperature between the preheat and
soldering should be 100°C or less.*
• When preheating and soldering, the temperature of the
leads and the case must not exceed the maximum
temperature ratings as shown on the data sheet. When
using infrared heating with the reflow soldering
method, the difference shall be a maximum of 10°C.
• The soldering temperature and time shall not exceed
260°C for more than 10 seconds.
* Soldering a device without preheating can cause
excessive thermal shock and stress which can result in
damage to the device.
* Due to shadowing and the inability to set the wave height
to incorporate other surface mount components, the D2PAK
is not recommended for wave soldering.
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MTD9N10E
TYPICAL SOLDER HEATING PROFILE
The line on the graph shows the actual temperature that
might be experienced on the surface of a test board at or
near a central solder joint. The two profiles are based on a
high density and a low density board. The Vitronics
SMD310 convection/infrared reflow soldering system was
used to generate this profile. The type of solder used was
62/36/2 Tin Lead Silver with a melting point between
177–189°C. When this type of furnace is used for solder
reflow work, the circuit boards and solder joints tend to
heat first. The components on the board are then heated by
conduction. The circuit board, because it has a large surface
area, absorbs the thermal energy more efficiently, then
distributes this energy to the components. Because of this
effect, the main body of a component may be up to 30
degrees cooler than the adjacent solder joints.
For any given circuit board, there will be a group of
control settings that will give the desired heat pattern. The
operator must set temperatures for several heating zones,
and a figure for belt speed. Taken together, these control
settings make up a heating “profile” for that particular
circuit board. On machines controlled by a computer, the
computer remembers these profiles from one operating
session to the next. Figure 17 shows a typical heating
profile for use when soldering a surface mount device to a
printed circuit board. This profile will vary among
soldering systems but it is a good starting point. Factors that
can affect the profile include the type of soldering system in
use, density and types of components on the board, type of
solder used, and the type of board or substrate material
being used. This profile shows temperature versus time.
STEP 1
PREHEAT
ZONE 1
“RAMP”
200°C
STEP 2
STEP 3
VENT
HEATING
“SOAK” ZONES 2 & 5
“RAMP”
DESIRED CURVE FOR HIGH
MASS ASSEMBLIES
STEP 4
HEATING
ZONES 3 & 6
“SOAK”
160°C
STEP 5
STEP 6
STEP 7
HEATING
VENT
COOLING
ZONES 4 & 7
205° TO 219°C
“SPIKE”
PEAK AT
170°C
SOLDER
JOINT
150°C
150°C
100°C
140°C
100°C
SOLDER IS LIQUID FOR
40 TO 80 SECONDS
(DEPENDING ON
MASS OF ASSEMBLY)
DESIRED CURVE FOR LOW
MASS ASSEMBLIES
5°C
TIME (3 TO 7 MINUTES TOTAL)
TMAX
Figure 17. Typical Solder Heating Profile
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MTD9N10E
PACKAGE DIMENSIONS
DPAK
CASE 369A–13
ISSUE AA
C
B
V
NOTES:
1. DIMENSIONING AND TOLERANCING PER ANSI
Y14.5M, 1982.
2. CONTROLLING DIMENSION: INCH.
SEATING
PLANE
–T–
E
R
4
Z
A
S
1
2
3
U
K
F
J
L
H
D
G
2 PL
0.13 (0.005)
M
T
DIM
A
B
C
D
E
F
G
H
J
K
L
R
S
U
V
Z
INCHES
MIN
MAX
0.235
0.250
0.250
0.265
0.086
0.094
0.027
0.035
0.033
0.040
0.037
0.047
0.180 BSC
0.034
0.040
0.018
0.023
0.102
0.114
0.090 BSC
0.175
0.215
0.020
0.050
0.020
--0.030
0.050
0.138
---
STYLE 2:
PIN 1.
2.
3.
4.
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10
GATE
DRAIN
SOURCE
DRAIN
MILLIMETERS
MIN
MAX
5.97
6.35
6.35
6.73
2.19
2.38
0.69
0.88
0.84
1.01
0.94
1.19
4.58 BSC
0.87
1.01
0.46
0.58
2.60
2.89
2.29 BSC
4.45
5.46
0.51
1.27
0.51
--0.77
1.27
3.51
---
MTD9N10E
Notes
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11
MTD9N10E
Thermal Clad is a registered trademark of the Bergquist Company.
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MTD9N10E/D