FDB050AN06A0 [ONSEMI]
N 沟道 Power Trench® MOSFET 60V,80A,5mΩ;型号: | FDB050AN06A0 |
厂家: | ONSEMI |
描述: | N 沟道 Power Trench® MOSFET 60V,80A,5mΩ |
文件: | 总14页 (文件大小:1050K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
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FDP050AN06A0 / FDB050AN06A0
®
N-Channel PowerTrench MOSFET
60 V, 80 A, 5 mΩ
Features
RDS(on) = 4.3 mΩ ( Typ.) @ VGS = 10 V, ID = 80 A
QG(tot) = 61 nC ( Typ.) @ VGS = 10 V
Low Miller Charge
•
•
•
•
Applications
•
•
•
Synchronous Rectification for ATX / Server / Telecom PSU
Battery Protection Circuit
Low Qrr Body Diode
Motor drives and Uninterruptible Power Supplies
• UIS Capability (Single Pulse and Repetitive Pulse)
Formerly developmental type 82575
D
D
G
G
G
D2-PAK
D
S
S
TO-220
S
MOSFET Maximum Ratings T = 25°C unless otherwise noted
C
FDP050AN06A0
FDB050AN06A0
Unit
Symbol
Parameter
VDSS
VGS
Drain to Source Voltage
Gate to Source Voltage
Drain Current
60
20
V
V
Continuous (TC < 135oC, VGS = 10V)
Continuous (TA = 25oC, VGS = 10V, RθJA = 43oC/W)
Pulsed
80
A
ID
18
Figure 4
470
A
A
EAS
Single Pulse Avalanche Energy (Note 1)
Power dissipation
Derate above 25oC
mJ
W
W/oC
oC
245
PD
1.63
TJ, TSTG
Operating and Storage Temperature
-55 to 175
Thermal Characteristics
RθJC
RθJA
RθJA
Thermal Resistance Junction to Case, Max. TO-220, D2-PAK
Thermal Resistance Junction to Ambient, Max. TO-220, D2-PAK (Note 2)
Thermal Resistance Junction to Ambient D2-PAK, Max. 1in2 copper pad area
0.61
oC/W
oC/W
oC/W
62
43
Publication Order Number:
©2003 Semiconductor Components Industries, LLC.
November-2017,Rev.3
FDP050AN06A0/D
Package Marking and Ordering Information
Device Marking
FDB050AN06A0
FDP050AN06A0
Device
Package
D2-PAK
TO-220
Reel Size
330 mm
Tube
Tape Width
24 mm
N/A
Quantity
800 units
50 units
FDB050AN06A0
FDP050AN06A0
Electrical Characteristics TC = 25°C unless otherwise noted
Symbol
Parameter
Test Conditions
Min
Typ
Max
Unit
Off Characteristics
BVDSS
Drain to Source Breakdown Voltage
Zero Gate Voltage Drain Current
Gate to Source Leakage Current
ID = 250µA, VGS = 0V
60
-
-
-
-
-
-
V
V
DS = 50V
1
IDSS
µA
nA
VGS = 0V
TC = 150oC
-
250
100
IGSS
VGS = 20V
-
On Characteristics
VGS(TH)
Gate to Source Threshold Voltage
VGS = VDS, ID = 250µA
D = 80A, VGS = 10V
ID = 40A, VGS = 6V
2
-
-
4
V
I
0.0043 0.005
0.007 0.011
-
rDS(ON)
Drain to Source On Resistance
Ω
I
D = 80A, VGS = 10V,
-
0.0085 0.010
TJ = 175oC
Dynamic Characteristics
CISS
Input Capacitance
-
-
-
3900
750
270
61
-
-
pF
pF
pF
nC
nC
nC
nC
nC
VDS = 25V, VGS = 0V,
f = 1MHz
COSS
CRSS
Qg(TOT)
Qg(TH)
Qgs
Output Capacitance
Reverse Transfer Capacitance
Total Gate Charge at 10V
Threshold Gate Charge
-
VGS = 0V to 10V
80
11
-
VGS = 0V to 2V
-
-
-
-
8
VDD = 30V
ID = 80A
Gate to Source Gate Charge
Gate Charge Threshold to Plateau
Gate to Drain “Miller” Charge
24
Ig = 1.0mA
Qgs2
16
-
Qgd
15
-
Switching Characteristics (VGS = 10V)
tON
td(ON)
tr
Turn-On Time
Turn-On Delay Time
Rise Time
-
-
-
-
-
-
-
16
160
28
29
-
264
ns
ns
ns
ns
ns
ns
-
-
VDD = 30V, ID = 80A
VGS = 10V, RGS = 4.3Ω
td(OFF)
tf
Turn-Off Delay Time
Fall Time
-
-
tOFF
Turn-Off Time
86
Drain-Source Diode Characteristics
I
I
SD = 80A
SD = 40A
-
-
-
-
-
-
-
-
1.25
1.0
34
V
V
VSD
Source to Drain Diode Voltage
trr
Reverse Recovery Time
ISD = 75A, dISD/dt = 100A/µs
ISD = 75A, dISD/dt = 100A/µs
ns
nC
QRR
Reverse Recovered Charge
25
Notes:
1: Starting T = 25°C, L = 229µH, I = 64A.
J
AS
2: Pulse width = 100s.
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2
Typical Characteristics T = 25°C unless otherwise noted
C
1.2
160
CURRENT LIMITED
BY PACKAGE
1.0
120
0.8
0.6
0.4
0.2
0
80
40
0
150
0
25
50
75
100
175
25
50
75
100
125
150
175
125
o
o
T
, CASE TEMPERATURE ( C)
C
T
, CASE TEMPERATURE ( C)
C
Figure 1. Normalized Power Dissipation vs
Ambient Temperature
Figure 2. Maximum Continuous Drain Current vs
Case Temperature
2
DUTY CYCLE - DESCENDING ORDER
0.5
0.2
1
0.1
0.05
0.02
0.01
P
DM
0.1
t
1
t
2
NOTES:
DUTY FACTOR: D = t /t
1
2
SINGLE PULSE
PEAK T = P x Z
x R
+ T
J
DM
θJC
θJC C
0.01
10
-5
-4
-3
-2
-1
0
1
10
10
10
t, RECTANGULAR PULSE DURATION (s)
10
10
10
Figure 3. Normalized Maximum Transient Thermal Impedance
2000
1000
o
T
= 25 C
C
FOR TEMPERATURES
o
ABOVE 25 C DERATE PEAK
CURRENT AS FOLLOWS:
175 - T
150
C
I = I
25
V
= 10V
GS
TRANSCONDUCTANCE
MAY LIMIT CURRENT
IN THIS REGION
100
50
-5
-4
-3
-2
-1
0
1
10
10
10
10
t, PULSE WIDTH (s)
10
10
10
Figure 4. Peak Current Capability
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3
Typical Characteristics T = 25°C unless otherwise noted
C
1000
100
10
500
If R = 0
= (L)(I )/(1.3*RATED BV
t
- V
DD
)
AV
AS
DSS
10µs
If R ≠ 0
t
AV
= (L/R)ln[(I *R)/(1.3*RATED BV
- V ) +1]
DD
AS
DSS
100µs
100
1ms
o
STARTING T = 25 C
J
OPERATION IN THIS
AREA MAY BE
10ms
LIMITED BY r
DS(ON)
10
DC
1
o
SINGLE PULSE
STARTING T = 150 C
J
T
= MAX RATED
J
o
T
= 25 C
C
1
0.01
0.1
0.1
1
10
100
1
10
, DRAIN TO SOURCE VOLTAGE (V)
100
V
t , TIME IN AVALANCHE (ms)
AV
DS
NOTE: Refer to ON Semiconductor Application Notes AN7514 and
AN7515
Figure 5. Forward Bias Safe Operating Area
Figure 6. Unclamped Inductive Switching
Capability
160
160
PULSE DURATION = 80µs
V
= 7V
GS
DUTY CYCLE = 0.5% MAX
V
= 15V
DD
V
= 10V
V
= 6V
GS
GS
120
80
40
0
120
80
40
0
o
T
= 175 C
J
V
= 5V
o
GS
T
= 25 C
J
o
T
= 25 C
C
o
PULSE DURATION = 80µs
DUTY CYCLE = 0.5% MAX
T
= -55 C
J
0
0.5
1.0
1.5
4.0
4.5
5.0
5.5
6.0
V
, GATE TO SOURCE VOLTAGE (V)
V
, DRAIN TO SOURCE VOLTAGE (V)
GS
DS
Figure 7. Transfer Characteristics
Figure 8. Saturation Characteristics
8
2.0
PULSE DURATION = 80µs
DUTY CYCLE = 0.5% MAX
PULSE DURATION = 80µs
DUTY CYCLE = 0.5% MAX
V
= 6V
GS
7
6
5
4
1.5
1.0
0.5
V
= 10V
GS
V
= 10V, I =80A
D
GS
0
20
40
, DRAIN CURRENT (A)
60
80
-80
-40
0
40
80
120
160
200
o
I
T , JUNCTION TEMPERATURE ( C)
D
J
Figure 9. Drain to Source On Resistance vs Drain
Current
Figure 10. Normalized Drain to Source On
Resistance vs Junction Temperature
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4
Typical Characteristics T = 25°C unless otherwise noted
C
1.4
1.2
1.0
0.8
0.6
0.4
1.15
1.10
1.05
1.00
0.95
0.90
I
= 250µA
V
= V , I = 250µA
DS D
D
GS
-80
-40
0
40
80
120
160
200
-80
-40
0
40
80
120
160
200
o
o
T , JUNCTION TEMPERATURE ( C)
T , JUNCTION TEMPERATURE ( C)
J
J
Figure 11. Normalized Gate Threshold Voltage vs
Junction Temperature
Figure 12. Normalized Drain to Source
Breakdown Voltage vs Junction Temperature
10000
10
V
= 30V
DD
C
= C + C
GD
ISS
GS
8
6
4
2
0
C
≅ C + C
GD
OSS
DS
1000
C
= C
RSS
GD
WAVEFORMS IN
DESCENDING ORDER:
I
I
= 80A
= 18A
D
D
V
= 0V, f = 1MHz
GS
100
0.1
0
10
20
30
40
50
60
70
60
1
10
V
, DRAIN TO SOURCE VOLTAGE (V)
Q , GATE CHARGE (nC)
DS
g
Figure 13. Capacitance vs Drain to Source
Voltage
Figure 14. Gate Charge Waveforms for Constant
Gate Current
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5
Test Circuits and Waveforms
V
DS
BV
DSS
t
P
L
V
DS
I
VARY t TO OBTAIN
P
AS
+
-
V
DD
R
REQUIRED PEAK I
G
AS
V
DD
V
GS
DUT
t
P
I
0V
AS
0
0.01Ω
t
AV
Figure 15. Unclamped Energy Test Circuit
Figure 16. Unclamped Energy Waveforms
V
DS
V
Q
DD
g(TOT)
V
L
DS
V
GS
V
= 10V
GS
V
GS
+
-
Q
gs2
V
DD
DUT
V
= 2V
GS
I
g(REF)
0
Q
g(TH)
Q
Q
gs
gd
I
g(REF)
0
Figure 17. Gate Charge Test Circuit
Figure 18. Gate Charge Waveforms
V
DS
t
t
ON
OFF
t
d(OFF)
t
d(ON)
R
L
t
t
f
r
V
DS
90%
90%
+
-
V
GS
V
DD
10%
10%
0
DUT
90%
50%
R
GS
V
GS
50%
PULSE WIDTH
V
10%
GS
0
Figure 19. Switching Time Test Circuit
Figure 20. Switching Time Waveforms
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6
Thermal Resistance vs. Mounting Pad Area
The maximum rated junction temperature, TJM, and the
thermal resistance of the heat dissipating path determines
the maximum allowable device power dissipation, PDM, in an
80
60
40
20
R
= 26.51+ 19.84/(0.262+Area) EQ.2
θJA
R
= 26.51+ 128/(1.69+Area) EQ.3
θJA
application.
Therefore the application’s ambient
temperature, TA (oC), and thermal resistance RθJA (oC/W)
must be reviewed to ensure that TJM is never exceeded.
Equation 1 mathematically represents the relationship and
serves as the basis for establishing the rating of the part.
(T
– T )
A
JM
(EQ. 1)
P
= -----------------------------
DM
RθJA
In using surface mount devices such as the TO-263
package, the environment in which it is applied will have a
significant influence on the part’s current and maximum
power dissipation ratings. Precise determination of PDM is
complex and influenced by many factors:
10
0.1
(0.645)
1
(6.45)
(64.5)
2
2
AREA, TOP COPPER AREA in (cm )
Figure 21. Thermal Resistance vs Mounting
Pad Area
1. Mounting pad area onto which the device is attached and
whether there is copper on one side or both sides of the
board.
2. The number of copper layers and the thickness of the
board.
3. The use of external heat sinks.
4. The use of thermal vias.
5. Air flow and board orientation.
6. For non steady state applications, the pulse width, the
duty cycle and the transient thermal response of the part,
the board and the environment they are in.
ON Semiconductor provides thermal information to
assist the designer’s preliminary application evaluation.
Figure 21
defines the RθJA for the device as a function of the top
copper (component side) area. This is for a horizontally
positioned FR-4 board with 1oz copper after 1000 seconds of
steady state power with no air flow. This graph provides the
necessary information for calculation of the steady state
junction temperature or power dissipation. Pulse applications
can be evaluated using the ON Semiconductor device
Spice thermal model or manually utilizing the normalized
maximum transient thermal impedance curve.
Thermal resistances corresponding to other copper areas
can be obtained from Figure 21 or by calculation using
Equation 2 or 3. Equation 2 is used for copper area
defined in inches square and equation 3 is for area in
centimeters square. The area, in square inches or square
centimeters is the top copper area including the gate and
source pads.
19.84
(0.262 + Area)
R
= 26.51 + ------------------------------------
(EQ. 2)
θJA
θJA
Area in Inches Squared
128
R
= 26.51 + ---------------------------------
(EQ. 3)
(1.69 + Area)
Area in Centimeters Squared
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7
PSPICE Electrical Model
.SUBCKT FDB050AN06A0 2 1 3 ; rev February 2003
Ca 12 8 1.5e-9
Cb 15 14 1.5e-9
Cin 6 8 3.75e-9
LDRAIN
DPLCAP
DRAIN
2
5
10
Dbody 7 5 DbodyMOD
Dbreak 5 11 DbreakMOD
Dplcap 10 5 DplcapMOD
RLDRAIN
RSLC1
51
DBREAK
11
+
RSLC2
5
ESLC
51
Ebreak 11 7 17 18 64.8
Eds 14 8 5 8 1
Egs 13 8 6 8 1
Esg 6 10 6 8 1
Evthres 6 21 19 8 1
-
+
17
50
-
DBODY
RDRAIN
6
8
EBREAK 18
-
ESG
EVTHRES
+
16
21
+
-
19
8
MWEAK
Evtemp 20 6 18 22 1
LGATE
EVTEMP
RGATE
GATE
1
6
+
-
18
22
MMED
It 8 17 1
9
20
MSTRO
8
RLGATE
Lgate 1 9 4.7e-9
Ldrain 2 5 1.0e-9
Lsource 3 7 4.03e-9
LSOURCE
CIN
SOURCE
3
7
RSOURCE
RLSOURCE
RLgate 1 9 47
RLdrain 2 5 10
RLsource 3 7 40
S1A
S2A
RBREAK
12
15
13
14
13
17
18
8
RVTEMP
19
-
S1B
S2B
Mmed 16 6 8 8 MmedMOD
Mstro 16 6 8 8 MstroMOD
Mweak 16 21 8 8 MweakMOD
13
CB
CA
IT
14
+
+
VBAT
6
8
5
8
EGS
EDS
+
Rbreak 17 18 RbreakMOD 1
Rdrain 50 16 RdrainMOD 1.1e-3
Rgate 9 20 1.3
-
-
8
22
RVTHRES
RSLC1 5 51 RSLCMOD 1e-6
RSLC2 5 50 1e3
Rsource 8 7 RsourceMOD 2.1e-3
Rvthres 22 8 RvthresMOD 1
Rvtemp 18 19 RvtempMOD 1
S1a 6 12 13 8 S1AMOD
S1b 13 12 13 8 S1BMOD
S2a 6 15 14 13 S2AMOD
S2b 13 15 14 13 S2BMOD
Vbat 22 19 DC 1
ESLC 51 50 VALUE={(V(5,51)/ABS(V(5,51)))*(PWR(V(5,51)/(1e-6*250),10))}
.MODEL DbodyMOD D (IS=1.3E-11 N=1.04 RS=1.76e-3 TRS1=2.7e-3 TRS2=2e-7
+ CJO=2.7e-9 M=5.4e-1 TT=1e-10 XTI=3.9)
.MODEL DbreakMOD D (RS=8e-1 TRS1=5e-4 TRS2=-8.9e-6)
.MODEL DplcapMOD D (CJO=1.3e-9 IS=1e-30 N=10 M=0.45)
.MODEL MmedMOD NMOS (VTO=3.7 KP=9 IS=1e-30 N=10 TOX=1 L=1u W=1u RG=1.3)
.MODEL MstroMOD NMOS (VTO=4.29 KP=155 IS=1e-30 N=10 TOX=1 L=1u W=1u)
.MODEL MweakMOD NMOS (VTO=3.05 KP=0.03 IS=1e-30 N=10 TOX=1 L=1u W=1u RG=13 RS=0.1)
.MODEL RbreakMOD RES (TC1=9.3e-4 TC2=-5.5e-7)
.MODEL RdrainMOD RES (TC1=1.3e-2 TC2=4e-5)
.MODEL RSLCMOD RES (TC1=1e-3 TC2=1e-5)
.MODEL RsourceMOD RES (TC1=1e-3 TC2=1e-6)
.MODEL RvthresMOD RES (TC1=-5.8e-3 TC2=-1.4e-5)
.MODEL RvtempMOD RES (TC1=-2.8e-3 TC2=1e-6)
.MODEL S1AMOD VSWITCH (RON=1e-5 ROFF=0.1 VON=-4 VOFF=-2)
.MODEL S1BMOD VSWITCH (RON=1e-5 ROFF=0.1 VON=-2 VOFF=-4)
.MODEL S2AMOD VSWITCH (RON=1e-5 ROFF=0.1 VON=-1.5 VOFF=0.5)
.MODEL S2BMOD VSWITCH (RON=1e-5 ROFF=0.1 VON=0.5 VOFF=-1.5)
.ENDS
Note: For further discussion of the PSPICE model, consult A New PSPICE Sub-Circuit for the Power MOSFET Featuring Global
Temperature Options; IEEE Power Electronics Specialist Conference Records, 1991, written by William J. Hepp and C. Frank
Wheatley.
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8
SABER Electrical Model
rev February 2003
template FDB050AN06A0 n2,n1,n3
electrical n2,n1,n3
{
var i iscl
dp..model dbodymod = (isl=1.3e-11,nl=1.04,rs=1.76e-3,trs1=2.7e-3,trs2=2e-7,cjo=2.7e-9,m=5.4e-1,tt=1e-10,xti=3.9)
dp..model dbreakmod = (rs=8e-1,trs1=5e-4,trs2=-8.9e-6)
dp..model dplcapmod = (cjo=1.3e-9,isl=10e-30,nl=10,m=0.45)
m..model mmedmod = (type=_n,vto=3.7,kp=9,is=1e-30, tox=1)
m..model mstrongmod = (type=_n,vto=4.29,kp=155,is=1e-30, tox=1)
m..model mweakmod = (type=_n,vto=3.05,kp=0.03,is=1e-30, tox=1,rs=0.1)
LDRAIN
sw_vcsp..model s1amod = (ron=1e-5,roff=0.1,von=-4,voff=-2)
sw_vcsp..model s1bmod = (ron=1e-5,roff=0.1,von=-2,voff=-4)
sw_vcsp..model s2amod = (ron=1e-5,roff=0.1,von=-1.5,voff=0.5)
sw_vcsp..model s2bmod = (ron=1e-5,roff=0.1,von=0.5,voff=-1.5)
c.ca n12 n8 = 1.5e-9
DPLCAP
5
DRAIN
2
10
RLDRAIN
RSLC1
51
RSLC2
c.cb n15 n14 = 1.5e-9
c.cin n6 n8 = 3.75e-9
ISCL
DBREAK
11
50
-
dp.dbody n7 n5 = model=dbodymod
dp.dbreak n5 n11 = model=dbreakmod
dp.dplcap n10 n5 = model=dplcapmod
RDRAIN
6
8
ESG
DBODY
EVTHRES
+
16
21
+
-
19
8
MWEAK
LGATE
EVTEMP
spe.ebreak n11 n7 n17 n18 = 64.8
RGATE
GATE
1
+
6
-
18
22
EBREAK
+
spe.eds n14 n8 n5 n8 = 1
spe.egs n13 n8 n6 n8 = 1
spe.esg n6 n10 n6 n8 = 1
spe.evthres n6 n21 n19 n8 = 1
spe.evtemp n20 n6 n18 n22 = 1
MMED
9
20
MSTRO
8
17
18
-
RLGATE
LSOURCE
CIN
SOURCE
3
7
RSOURCE
RLSOURCE
i.it n8 n17 = 1
S1A
S2A
RBREAK
12
15
13
8
14
13
l.lgate n1 n9 = 4.7e-9
l.ldrain n2 n5 = 1.0e-9
l.lsource n3 n7 = 4.03e-9
17
18
RVTEMP
19
S1B
S2B
13
CB
CA
IT
14
-
+
+
res.rlgate n1 n9 = 47
res.rldrain n2 n5 = 10
res.rlsource n3 n7 = 40
VBAT
6
8
5
8
EGS
EDS
+
-
-
8
22
m.mmed n16 n6 n8 n8 = model=mmedmod, l=1u, w=1u
RVTHRES
m.mstrong n16 n6 n8 n8 = model=mstrongmod, l=1u, w=1u
m.mweak n16 n21 n8 n8 = model=mweakmod, l=1u, w=1u
res.rbreak n17 n18 = 1, tc1=9.3e-4,tc2=-5.5e-7
res.rdrain n50 n16 = 1.1e-3, tc1=1.3e-2,tc2=4e-5
res.rgate n9 n20 = 1.3
res.rslc1 n5 n51 = 1e-6, tc1=1e-3,tc2=1e-5
res.rslc2 n5 n50 = 1e3
res.rsource n8 n7 = 2.1e-3, tc1=1e-3,tc2=1e-6
res.rvthres n22 n8 = 1, tc1=-5.8e-3,tc2=-1.4e-5
res.rvtemp n18 n19 = 1, tc1=-2.8e-3,tc2=1e-6
sw_vcsp.s1a n6 n12 n13 n8 = model=s1amod
sw_vcsp.s1b n13 n12 n13 n8 = model=s1bmod
sw_vcsp.s2a n6 n15 n14 n13 = model=s2amod
sw_vcsp.s2b n13 n15 n14 n13 = model=s2bmod
v.vbat n22 n19 = dc=1
equations {
i (n51->n50) +=iscl
iscl: v(n51,n50) = ((v(n5,n51)/(1e-9+abs(v(n5,n51))))*((abs(v(n5,n51)*1e6/250))** 10))
}
}
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9
SPICE Thermal Model
JUNCTION
th
REV 23 February 2003
FDB050AN06A0T
CTHERM1 TH 6 5e-3
CTHERM2 6 5 1.3e-2
CTHERM3 5 4 1.4e-2
CTHERM4 4 3 1.9e-2
CTHERM5 3 2 4.7e-2
CTHERM6 2 TL 9e-2
RTHERM1
RTHERM2
RTHERM3
RTHERM4
RTHERM5
RTHERM6
CTHERM1
6
RTHERM1 TH 6 1e-2
RTHERM2 6 5 3.1e-2
RTHERM3 5 4 4.5e-2
RTHERM4 4 3 1.2e-1
RTHERM5 3 2 1.3e-1
RTHERM6 2 TL 1.52e-1
CTHERM2
CTHERM3
CTHERM4
CTHERM5
CTHERM6
5
SABER Thermal Model
SABER thermal model FDB050AN06A0T
template thermal_model th tl
thermal_c th, tl
{
ctherm.ctherm1 th 6 =5e-3
ctherm.ctherm2 6 5 =1.3e-2
ctherm.ctherm3 5 4 =1.4e-2
ctherm.ctherm4 4 3 =1.9e-2
ctherm.ctherm5 3 2 =4.7e-2
ctherm.ctherm6 2 tl =9e-2
4
3
2
rtherm.rtherm1 th 6 =1e-2
rtherm.rtherm2 6 5 =3.1e-2
rtherm.rtherm3 5 4 =4.5e-2
rtherm.rtherm4 4 3 =1.2e-1
rtherm.rtherm5 3 2 =1.3e-1
rtherm.rtherm6 2 tl =1.52e-1
}
tl
CASE
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10
Mechanical Dimensions
TO-220 3L
Figure 22. TO-220, Molded, 3Lead, Jedec Variation AB
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Dimension in Millimeters
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11
Mechanical Dimensions
TO-263 2L (D2PAK)
Figure 23. 2LD, TO263, Surface Mount
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any manner without notice. Please note the revision and/or date on the drawing and contact a ON Semiconductor representative to
verify or obtain the most recent revision. Package specifications do not expand the terms of ON Semiconductor's worldwide terms
and conditions, specif-ically the warranty therein, which covers ON Semiconductor products.
Dimension in Millimeters
12
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