LTC4364-1/LTC4364-2
1
436412f
TYPICAL APPLICATION
FEATURES DESCRIPTION
Surge Stopper
with Ideal Diode
The LTC
®
4364 surge stopper with ideal diode controller
protects loads from high voltage transients. It limits and
regulates the output during an overvoltage event, such
as load dump in automobiles, by controlling the voltage
drop across an external N-channel MOSFET pass device.
The LTC4364 also includes a timed, current limited circuit
breaker. In a fault condition, an adjustable fault timer must
expire before the pass device is turned off. The LTC4364-1
latches off the pass device while the LTC4364-2 automati-
cally restarts after a delay. The LTC4364 precisely monitors
the input supply for overvoltage (OV) and undervoltage
(UV) conditions. The external MOSFET is held off in un-
dervoltage and auto-retry is disabled in overvoltage.
An integrated ideal diode controller drives a second MOS-
FET to replace a Schottky diode for reverse input protec-
tion and output voltage holdup. The LTC4364 controls the
forward voltage drop across the MOSFET and minimizes
reverse current transients upon power source failure,
brownout or input short.
Overvoltage Protector Regulates
Output at 27V During Input Transient
Ideal Diode Holds Up Output
During Input Short
4A, 12V Overvoltage Output Regulator with Ideal Diode
Withstands 200V 1ms Transient at VIN
APPLICATIONS
n Wide Operating Voltage Range: 4V to 80V
n Withstands Surges Over 80V with VCC Clamp
n Adjustable Output Clamp Voltage
n Ideal Diode Controller Holds Up Output Voltage
During Input Brownouts
n Reverse Input Protection to –40V
n Reverse Output Protection to –20V
n Overcurrent Protection
n Low 10μA Shutdown Current at 12V
n Adjustable Fault Timer
n 0.1% Retry Duty Cycle During Faults (LTC4364-2)
n Available in 4mm × 3mm 14-Lead DFN, 16-Lead MSOP,
and 16-Lead SO Packages
n Automotive/Avionic Surge Protection
n Hot Swap/Live Insertion
n Redundant Supply ORing
n Output Port Protection
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
+
OUTSENSEDGATESOURCEHGATE
TMRGND
0.22µF
UV
UV
6V
OV
60V OV ENOUT ENABLE
FAULT
436412 TA01a
F LT
SHDN FB
10Ω
2.2k
383k
VIN
12V
90.9k
10k
102k
22µF
VOUT
CLAMPED
AT 27V
4.99k
CMZ5945B
68V
FDB33N25 FDB3682 10mΩ
6.8nF
VCC
LTC4364
50ms/DIV
CTMR = 6.8µF
ILOAD = 0.5A
VIN
20V/DIV
12V
12V
VOUT
20V/DIV
92V INPUT SURGE
27V CLAMP (ADJUSTABLE)
4364 TA01b
1ms/DIV
CLOAD = 6300µF
ILOAD = 0.5A
VIN
10V/DIV
12V
12V
VOUT
10V/DIV
4364 TA01c
INPUT SHORTED
TO GND
OUTPUT HELD UP
LTC4364-1/LTC4364-2
2
436412f
ABSOLUTE MAXIMUM RATINGS
Supply Voltage: VCC ................................. 40V to 100V
SOURCE, OV, UV, SHDN Voltages ............. 40V to 100V
DGATE, HGATE Voltages
(Note 3) ..................... SOURCE – 0.3V to SOURCE + 10V
ENOUT, FLT Voltages ................................ 0.3V to 100V
OUT, SENSE Voltages.................................–20V to 100V
Voltage Difference (SENSE to OUT) ............ –30V to 30V
Voltage Difference (OUT to VCC) ..............–100V to 100V
Voltage Difference (SENSE to SOURCE) ..–100V to 100V
(Notes 1, 2)
1
2
3
4
5
6
7
14
13
12
11
10
9
8
FB
TMR
ENOUT
FLT
GND
OV
UV
OUT
SENSE
DGATE
SOURCE
HGATE
VCC
SHDN
TOP VIEW
15
DE PACKAGE
14-LEAD (4mm × 3mm) PLASTIC DFN
TJMAX = 150°C, θJA = 45°C/W
EXPOSED PAD (PIN 15) PCB GND CONNECTION OPTIONAL
1
2
3
4
5
6
7
8
OUT
SENSE
NC
DGATE
SOURCE
HGATE
NC
VCC
16
15
14
13
12
11
10
9
FB
TMR
ENOUT
F LT
GND
OV
UV
SHDN
TOP VIEW
MS PACKAGE
16-LEAD PLASTIC MSOP
TJMAX = 150°C, θJA = 120°C/W
TOP VIEW
S PACKAGE
16-LEAD PLASTIC SO
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
OUT
SENSE
NC
DGATE
SOURCE
HGATE
NC
VCC
FB
TMR
ENOUT
FLT
GND
OV
UV
SHDN
TJMAX = 150°C, θJA = 100°C/W
PIN CONFIGURATION
ORDER INFORMATION
LEAD FREE FINISH TAPE AND REEL PART MARKING* PACKAGE DESCRIPTION TEMPERATURE RANGE
LTC4364CDE-1#PBF LTC4364CDE-1#TRPBF 43641 14-Lead (4mm × 3mm) Plastic DFN 0°C to 70°C
LTC4364IDE-1#PBF LTC4364IDE-1#TRPBF 43641 14-Lead (4mm × 3mm) Plastic DFN –40°C to 85°C
LTC4364HDE-1#PBF LTC4364HDE-1#TRPBF 43641 14-Lead (4mm × 3mm) Plastic DFN –40°C to 125°C
LTC4364CDE-2#PBF LTC4364CDE-2#TRPBF 43642 14-Lead (4mm × 3mm) Plastic DFN 0°C to 70°C
LTC4364IDE-2#PBF LTC4364IDE-2#TRPBF 43642 14-Lead (4mm × 3mm) Plastic DFN –40°C to 85°C
LTC4364HDE-2#PBF LTC4364HDE-2#TRPBF 43642 14-Lead (4mm × 3mm) Plastic DFN –40°C to 125°C
LTC4364CMS-1#PBF LTC4364CMS-1#TRPBF 43641 16-Lead Plastic MSOP 0°C to 70°C
LTC4364IMS-1#PBF LTC4364IMS-1#TRPBF 43641 16-Lead Plastic MSOP –40°C to 85°C
LTC4364HMS-1#PBF LTC4364HMS-1#TRPBF 43641 16-Lead Plastic MSOP –40°C to 125°C
LTC4364CMS-2#PBF LTC4364CMS-2#TRPBF 43642 16-Lead Plastic MSOP 0°C to 70°C
LTC4364IMS-2#PBF LTC4364IMS-2#TRPBF 43642 16-Lead Plastic MSOP –40°C to 85°C
LTC4364HMS-2#PBF LTC4364HMS-2#TRPBF 43642 16-Lead Plastic MSOP –40°C to 125°C
FB, TMR Voltages ..................................... 0.3V to 5.5V
Operating Ambient Temperature Range
LTC4364C ................................................ 0°C to 70°C
LTC4364I ............................................. 40°C to 85°C
LTC4364H .......................................... 40°C to 125°C
Storage Temperature Range .................. 65°C to 150°C
Lead Temperature (Soldering, 10 sec)
MS, SO Packages ............................................. 300°C
LTC4364-1/LTC4364-2
3
436412f
ORDER INFORMATION
LEAD FREE FINISH TAPE AND REEL PART MARKING* PACKAGE DESCRIPTION TEMPERATURE RANGE
LTC4364CS-1#PBF LTC4364CS-1#TRPBF LTC4364S-1 16-Lead Plastic SO 0°C to 70°C
LTC4364IS-1#PBF LTC4364IS-1#TRPBF LTC4364S-1 16-Lead Plastic SO –40°C to 85°C
LTC4364HS-1#PBF LTC4364HS-1#TRPBF LTC4364S-1 16-Lead Plastic SO –40°C to 125°C
LTC4364CS-2#PBF LTC4364CS-2#TRPBF LTC4364S-2 16-Lead Plastic SO 0°C to 70°C
LTC4364IS-2#PBF LTC4364IS-2#TRPBF LTC4364S-2 16-Lead Plastic SO –40°C to 85°C
LTC4364HS-2#PBF LTC4364HS-2#TRPBF LTC4364S-2 16-Lead Plastic SO –40°C to 125°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
Consult LTC Marketing for information on non-standard lead based finish parts.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VCC = 12V.
SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS
VCC Operating Supply Range l4 80 V
ICC Supply Current VCC = SOURCE = SENSE = OUT = 12V, No Fault l370 750 µA
ICC(SHDN) Supply Current in Shutdown Shutdown l10 50 μA
ICC(REV) Reverse Input Current VCC = −30V l0 –10 μA
Surge Stopper
VHGATE HGATE Gate Drive, (VHGATE − VSOURCE) VCC = 4V, DGATE Low, IHGATE = 0µA, −1µA
VCC = 8V to 80V, DGATE Low, IHGATE = 0µA, −1µA
l
l
5
10
7
12
9
16
V
V
IHGATE(UP) HGATE Pull-Up Current VCC = HGATE = DGATE = SOURCE = 12V l–10 –20 –30 µA
IHGATE(DN) HGATE Pull-Down Current Overvoltage: FB = 1.5V, VHGATE = 5V l60 130 mA
Overcurrent: VSNS = 100mV, VHGATE = 5V l60 130 mA
Shutdown/Fault Turn-Off: VHGATE = 5V l0.4 1 mA
ISRC SOURCE Input Current VCC = SOURCE = SENSE = OUT = 12V
VCC = SOURCE = 12V, Shutdown
VSOURCE = –30V
l
l
l
18
32
–2.0
40
90
–3.5
µA
µA
mA
VFB FB Servo Voltage VCC = 12V to 80V l1.22 1.25 1.28 V
IFB FB Input Current FB = 1.25V l0 1 µA
VSNS Overcurrent Fault Threshold,
(VSENSE – VOUT)
VCC = 4V to 80V, OUT = 2.5V to VCC, 0°C to 125°C
VCC = 4V to 80V, OUT = 2.5V to VCC, –40°C to 125°C
VCC = 4V to 80V, OUT = 0V to 1.5V
l
l
l
45
43
18
50
50
25
55
57
32
mV
mV
mV
ISNS SENSE Input Current SENSE = VCC = SOURCE = OUT = 12V
SENSE = –15V
l
l
55
–2
110
–4
µA
mA
ITMR(UP) TMR Pull-Up Current, Overvoltage TMR = 1V, FB = 1.5V, VCC – OUT = 0.5V
TMR = 1V, FB = 1.5V, VCC – OUT = 75V
l
l
–1.3
–40
–2.2
–50
–3
–60
µA
µA
TMR Pull-Up Current, Overcurrent TMR = 1V, VSNS = 60mV, VCC – OUT = 0.5V
TMR = 1V, VSNS = 60mV, VCC – OUT = 75V
l
l
–6
–210
–10
–260
–14
–310
µA
µA
TMR Pull-Up Current, Warning TMR = 1.3V, FB = 1.5V, VCC – OUT = 0.5V l–3 –5 –7 µA
TMR Pull-Up Current, Retry TMR = 1V, FB = 1.5V l–1.3 –2 –3 µA
ITMR(DN) TMR Pull-Down Current TMR = 1V, FB = 1.5V, Retry
Shutdown
l
l
1.1
0.3
2
0.75
2.7
1.5
µA
mA
VTMR(F) TMR Fault Threshold F LT Falling, VCC = 4V to 80V l1.22 1.25 1.28 V
VTMR(G) TMR Gate Off Threshold HGATE Falling, VCC = 4V to 80V l1.32 1.35 1.38 V
LTC4364-1/LTC4364-2
4
436412f
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VCC = 12V.
SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS
VTMR(R) TMR Retry Threshold HGATE Rising (After 32 Cycles), VCC = 4V to 80V l0.125 0.15 0.175 V
VTMR Early Warning Timer Window VTMR(G) – VTMR(F), VCC = 4V to 80V l75 100 125 mV
VUV UV Input Threshold UV Falling, VCC = 4V to 80V l1.22 1.25 1.28 V
VUV(HYST) UV Input Hysteresis l25 50 80 mV
VUV(RST) UV Reset Threshold UV Falling, VCC = 4V to 80V, LTC4364-1 Only l0.5 0.6 0.7 V
VOV OV Input Threshold OV Rising, VCC = 4V to 80V l1.22 1.25 1.28 V
VOV(HYST) OV Input Hysteresis 12 mV
IIN UV, OV Input Current UV, OV = 1.25V
UV, OV = –30V
l
l
0
–0.3
1
–0.6
µA
mA
VOL ENOUT, F LT Output Low ISINK = 0.25mA
ISINK = 2mA
l
l
0.1
0.5
0.3
1.3
V
V
ILEAK ENOUT, F LT Leakage Current ENOUT, F LT = 80V l0 2.5 µA
VOUT(TH) Out High Threshold (VCC – VOUT) ENOUT from Low to High l0.4 0.7 1 V
VOUT(RST) Out Reset Threshold ENOUT from High to Low l1.4 2.2 3 V
IOUT OUT Input Current VCC = OUT = 12V, SHDN Open
OUT = –15V
l
l
40
–4
80
–8
µA
mA
Output Current in Shutdown, ISNS + IOUT VCC = SOURCE = SENSE = OUT = 12V, Shutdown l12 40 µA
VSHDN SHDN Input Threshold VCC = 4V to 80V l0.5 1.6 2.2 V
VSHDN(FLT) SHDN Pin Float Voltage VCC = 12V to 80V l2.3 4 6.5 V
ISHDN SHDN Input Current SHDN = 0.5V
Maximum Allowable Leakage, VCC = 4V
SHDN = –30V
l
l
–1 –3.3
–1.5
–120
–300
µA
µA
µA
D Retry Duty Cycle, Overvoltage
Retry Duty Cycle, Output Short
FB = 1.5V, VCC = 80V, OUT = 16V
VSNS = 60mV, VCC – OUT = 12V
l
l
0.125
0.075
0.2
0.12
%
%
tOFF,HGATE(UV) Undervoltage to HGATE Low Propagation
Delay
UV Steps from 1.5V to 1V l1.3 4 μs
tOFF,HGATE(OV) Overvoltage to HGATE Low Propagation
Delay
FB Steps from 1V to 1.5V l0.25 1 μs
tOFF,HGATE(OC) Overcurrent to HGATE Low Propagation
Delay VSNS Steps from 0mV to 150mV, OUT = 0V l0.5 2 μs
Ideal Diode
ΔVDGATE DGATE Gate Drive, (VDGATE − VSOURCE) VCC = 4V, No Fault, IDGATE = 0µA, −1µA
VCC = 8V to 80V, No Fault, IDGATE = 0µA, −1µA
l
l
5
10
8.5
12
12
16
V
V
IDGATE(UP) DGATE Pin Pull-Up Current DGATE = SOURCE = VCC = 12V, VSD = 0.1V l–5 –10 –15 µA
IDGATE(DN) DGATE Pin Pull-Down Current VDGATE = 5V, VSD = –0.2V
VDGATE = 5V, Shutdown/Fault Turn-Off
l
l
60
0.4
130
1
mA
mA
VSD Ideal Diode Regulation Voltage,
(VSOURCE − VSENSE)VDGATE = 2.5V, VCC = SOURCE = 12V
VDGATE = 2.5V, VCC = SOURCE = 4V
l
l
10
24
30
48
45
72
mV
mV
tOFF(DGATE) DGATE Turn-Off Propagation Delay VSD Steps from 0.1V to –1V l0.35 1.5 μs
Note 1: Stress beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: All Currents into device pins are positive and all currents out
of device pins are negative. All voltages are referenced to GND unless
otherwise specified.
Note 3: Internal clamps limit the HGATE and DGATE pins to minimum of
10V above the SOURCE pin. Driving these pins to voltages beyond the
clamp may damage the device.
LTC4364-1/LTC4364-2
5
436412f
TYPICAL PERFORMANCE CHARACTERISTICS
ISNS + IOUT in Shutdown vs VCC
ICC(SHDN) vs Temperature
GATE Pull-Up Current vs VCC VHGATE vs IHGATE
VDGATE vs IDGATE VHGATE vs VIN in Figure 1
Supply Current vs VCC ICC(SHDN) vs VCC
VDGATE vs VIN in Figure 1
VCC (V)
0
SUPPLY CURRENT (µA)
250
300
350
80
436412 G01
200
100
150
020 40 60
10 30 50 70
50
450
400
VCC = SOURCE = SENSE = OUT
ICC
ISRC
ISNS + IOUT
VCC (V)
0
0
ICC(SHDN) (µA)
10
20
30
40
20 40 60 80
436412 G02
50
60
10 30 50 70
SHDN = 0
OUT = 0
OUT = VCC
TEMPERATURE (°C)
–50
ICC(SHDN) (µA)
14
25
436412 G03
8
4
–25 0 50
2
0
16
OUT = 0
OUT = 12V
12
10
6
75 100 125
SHDN = 0
VCC = 12V
VCC (V)
0
ISNS + IOUT IN SHUTDOWN (µA)
60
80
100
30 50 80
436412 G04
40
20
0
10 20 40 60 70
SOURCE = VCC
SNS = OUT = 48V
SNS = OUT = 24V
SNS = OUT = 12V
VCC (V)
4
0
IGATE(UP) (µA)
–4
–8
–12
–16
8 12 40 80
436412 G05
–20
–24
6 10 20 60
HGATE
DGATE
HGATE = DGATE = SOURCE = VCC
VSD = 100mV
IHGATE (µA)
0
VHGATE (V)
10
11
12
–20
436412 G06
9
8
6–5 –10 –15
7
14 VCC = 12V
13
IDGATE (µA)
0
VDGATE (V)
10
11
12
–10
436412 G07
9
8
6–4–2 –6 –8
7
14
13
VCC = 12V
VIN (V)
4
2
VHGATE (V)
4
6
8
10
12
14
8 12 16 20
436412 G08
24
2.2k
4.7k
10k
R4 IN FIGURE 1
VIN (V)
4
2
VDGATE (V)
4
6
8
10
12
14
8 12 16 20
436412 G09
24
2.2k
4.7k
10k
R4 IN FIGURE 1
LTC4364-1/LTC4364-2
6
436412f
TYPICAL PERFORMANCE CHARACTERISTICS
Overcurrent Threshold
vs OUT Voltage
Overvoltage TMR Current
vs VCC – VOUT
Overcurrent TMR Current
vs VCC – VOUT
EN, F LT Output Low vs Current
Retry Duty Cycle vs VCC – VOUT
(LTC4364-2 Only)
HGATE Pull-Down Current
vs Temperature
DGATE Pull-Down Current
vs Temperature
Ideal Diode Regulation Voltage
vs VCC
Ideal Diode Regulation Voltage
vs Temperature
TEMPERATURE (°C)
–50
IHGATE(DN) (mA)
150
175
200
25 75
436412 G10
125
100
–25 0 50 100 125
75
50
VSNS = 100mV OR FB = 1.5V
VHGATE = 5V
VCC = 12V
TEMPERATURE (°C)
–50
IDGATE(DN) (mA)
150
175
200
25 75
436412 G11
125
100
–25 0 50 100 125
75
50
VSENSE – VSOURCE = 200mV
VCC = 12V
VDGATE = 5V
VOUT (V)
0
VSNS (mV)
40
50
60
1.5 2.5 4.0
436412 G12
30
20
10
0.5 1.0 2.0 3.0 3.5
VCC – VOUT (V)
0
0
ITMR(UP) (µA)
–10
–20
–30
–40
20 40 60 80
436412 G13
–50
–60
10 30 50 70
OVERVOLTAGE CONDITION
OUT = 5V
TMR = 1V
VCC – VOUT (V)
0
0
ITMR(UP) (µA)
–50
–100
–150
–200
20 40 60 80
436412 G14
–250
–300
10 30 50 70
OVERCURRENT CONDITION
OUT = 5V
TMR = 1V
VCC – VOUT (V)
0
RETRY DUTY CYCLE (%)
0.4
0.6
80
436412 G15
0.2
020 40 60
10 30 50 70
0.8
0.3
0.5
0.1
0.7
OVERVOLTAGE CONDITION
OUT = 16V
OVERCURRENT CONDITION
OUT = 0V
CURRENT (mA)
0
0
VOL (V)
0.25
0.50
0.75
1.00
1.25
1.50
1 2 3 4
436412 G16
5
VCC = 12V
VCC (V)
4
VSD (mV)
30
40
80
436412 G17
20
10 812 40
610 20 60
50
25
35
15
45
TEMPERATURE (°C)
50
10
VSD (mV)
30
60
050 75 100
436412 G18
20
50
40
25 25 125
VCC = 4V
VCC = 12V
LTC4364-1/LTC4364-2
7
436412f
PIN FUNCTIONS
DGATE: Diode Controller Gate Drive Output. When the load
current creates more than 30mV of drop across the MOSFET,
the DGATE pin is pulled high by an internal charge pump
current source and clamped to 12V above the SOURCE pin.
When the load current is small, the DGATE pin is actively
driven to maintain 30mV across the MOSFET. If reverse
current develops, a 130mA fast pull-down circuit quickly
connects the DGATE pin to the SOURCE pin, turning off
the MOSFET. Connect to SOURCE or leave open if unused.
ENOUT: Enable Output. An open-drain output that goes
high impedance when the voltage at the OUT pin is above
(VCC − 0.7V), indicating the external MOSFETs are fully
on. The state of the pin is latched and resets when the
OUT pin drops below 2.2V. The internal FET is capable of
sinking up to 2mA and can withstand up to 80V. Connect
to GND if unused.
Exposed Pad (DE Package Only): Exposed pad may be
left open or connected to device ground (GND).
FB: Voltage Regulator Feedback Input. Connect this pin to
the resistive divider connected between the OUT pin and
ground. During an overvoltage condition, the HGATE pin
is controlled to maintain 1.25V at the FB pin. Connect to
GND to disable the overvoltage clamp.
F LT : Fault Output. An open-drain output that pulls low
after the TMR pin reaches the warning threshold of 1.25V.
It indicates the pass device controlled by the HGATE pin
is about to turn off because either the supply voltage has
stayed at an elevated level for an extended period of time
(overvoltage fault) or the device is in an overcurrent con-
dition (overcurrent fault). The internal FET is capable of
sinking up to 2mA and can withstand up to 80V. Connect
to GND if unused.
GND: Device Ground.
HGATE: Surge Stopper Gate Drive Output. The HGATE pin
is pulled up by an internal charge pump current source and
clamped to 12V above the SOURCE pin. Both voltage and
current amplifiers control the HGATE pin to regulate the
output voltage and limit the current through the MOSFET.
OUT: Output Voltage Sense Input. This pin senses the
voltage at the drain of the external N-channel MOSFET
connected to the DGATE pin. The voltage difference
between VCC and OUT sets the fault timer current. When
this difference drops below 0.7V, the ENOUT pin goes
high impedance.
OV: Overvoltage Comparator Input. When OV is above
its threshold of 1.25V, the fault retry function is inhibited.
When OV falls below its threshold, the HGATE pin is al-
lowed to turn back on when fault conditions are cleared. At
power-up, an OV voltage higher than its threshold blocks
turn-on of the external N-channel MOSFET controlled by
the HGATE pin (see Applications Information). Connect
to GND if unused.
SENSE: Current Sense Input. Connect this pin to the input
side of the current sense resistor. The current limit circuit
controls the HGATE pin to limit the sense voltage between
the SENSE and OUT pins to 50mV if OUT is above 2.5V.
When OUT drops below 1.5V, the sense voltage is reduced
to 25mV for additional protection during an output short.
The sense amplifier also starts a current source to charge
up the TMR pin. The voltage difference between SENSE
and OUT must be limited to less than 30V. Connect to
OUT if unused.
SHDN: Shutdown Control Input. Pulling the SHDN pin
below 0.5V shuts off the LTC4364 and reduces the VCC pin
current to 10μA. Pull this pin above 2.2V or disconnect it
to allow the internal current source to turn the part back
on. When left open, the SHDN voltage is internally clamped
to 4V. The leakage current to ground at the pin should be
limited to no more than 1μA if no pull-up device is used to
turn the part on. The SHDN pin can be pulled up to 100V
or below GND by 40V without damage.
SOURCE: Common Source Input and Gate Drive Return.
Connect this pin directly to the sources of the external
back-to-back N-channel MOSFETs. SOURCE is the anode
of the ideal diode and the voltage sensed between this pin
and the SENSE pin is used to control the source-drain
voltage across the N-channel MOSFET (forward voltage
of the ideal diode).
LTC4364-1/LTC4364-2
8
436412f
PIN FUNCTIONS
TMR: Fault Timer Input. Connect a capacitor between this
pin and ground to set the times for fault warning, fault
turn-off, and cool down periods. Either voltage regulation
or current regulation starts pulling up the TMR pin. The
current charging up this pin during the fault conditions
increases with the voltage difference between VCC and OUT
pins (see Applications Information). When TMR reaches
1.25V, the F LT pin pulls low to indicate the detection of a
fault condition. If the condition persists, the pass device
controlled by HGATE turns off when TMR reaches the
threshold of 1.35V. As soon as the fault condition disap-
pears, a cool down interval commences while the TMR
pin cycles 32 times between 0.15V and 1.35V with 2μA
charge and discharge currents. When TMR crosses 0.15V
the 32nd time, the HGATE pin is allowed to pull high turn-
ing the pass device back on if the OV pin voltage is below
its threshold for the LTC4364-2 version. The HGATE pin
latches low after fault time-out for the LTC4364-1.
UV: Undervoltage Comparator Input. When the UV pin
falls below its 1.25V threshold, the HGATE pin is pulled
down with a 1mA current. When the UV pin rises above
1.25V plus the hysteresis, the HGATE pin is pulled up by
the internal charge pump. For LTC4364-1, after HGATE
is latched off, pulling the UV pin below 0.6V resets the
latch and allows HGATE to retry. If unused, connect to
the SHDN pin.
VCC: Positive Supply Voltage Input. The positive supply
input ranges from 4V to 80V for normal operation. It can
also be pulled below ground potential by up to 40V during
a reverse battery condition, without damaging the part.
Shutting down the LTC4364 by pulling the SHDN pin to
ground reduces the VCC current to 10μA.
LTC4364-1/LTC4364-2
9
436412f
BLOCK DIAGRAM
+
+
+
RETRY
1.35V
0.15V
TMR
VCC
1.25V
2µA
UVIN
SHDN
OV
OC ENOUT SET
VCC – 0.7V
2.2V
ENOUT RESET
50mV/
25mV
+
30mV +
30mV
OUT
FB
1.25V
SHDN
UV
1.25V
OV
CONTROL
CIRCUITRY
+
+
+
+
+
IAVA
+
+
DAFD
20µA
10µA HGATE OFF DGATE OFF
12V
12V
HGATE SOURCE DGATE
F LT
SENSEVCC
CHARGE
PUMP
f = 620kHz
ENOUT
GND
436412 BD
+
+
32x
LTC4364-1/LTC4364-2
10
436412f
OPERATION
The LTC4364 is designed to suppress high voltage surges
and limit the output voltage to protect load circuitry and
ensure normal operation in high availability power systems.
It features an overvoltage protection regulator that drives
an external N-channel MOSFET (M1) as the pass device
and an ideal diode controller that drives a second external
N-channel MOSFET (M2) for reverse input protection and
output voltage holdup.
The LTC4364 operates from a wide range of supply voltage,
from 4V to 80V. With a clamp limiting the VCC supply, the
input voltage may be higher than 80V. The input supply
can also be pulled below ground potential by up to 40V
without damaging the LTC4364. The low power supply
requirement of 4V allows it to operate even during cold
cranking conditions in automotive applications.
Normally, the pass device M1 is fully on, supplying current
to the load with very little power loss. If the input voltage
surges too high, the voltage amplifier (VA) controls the gate
of M1 and regulates the voltage at the OUT pin to a level
that is set by an external resistive divider from the OUT pin
to ground and the internal 1.25V reference. The LTC4364
also detects an overcurrent condition by monitoring the
voltage across an external sense resistor placed between
the SENSE and OUT pins. An active current limit circuit
(IA) controls the gate of M1 to limit the sense voltage to
50mV if OUT is above 2.5V. In the case of a severe output
short that brings OUT below 1.5V, the sense voltage is
reduced to 25mV to reduce the stress on M1.
During an overvoltage or overcurrent event, a current
source starts charging up the capacitor connected at
the TMR pin to ground. The pull-up current source in
overcurrent condition is 5 times of that in overvoltage to
accelerate turn-off. When TMR reaches 1.25V, the F LT pin
pulls low to warn of impending turn-off. The pass device
M1 stays on and the TMR pin is further charged up until it
reaches 1.35V, at which point the HGATE pin pulls low and
turns off M1. The fault timer allows the load to continue
functioning during brief transient events while protecting
the MOSFET from being damaged by a long period of input
overvoltage, such as load dump in vehicles. The fault timer
period decreases with the voltage across the MOSFET,
to help keep the MOSFET within its safe operating area
(SOA). The LTC4364-1 latches off M1 and keeps F LT low
after a fault timeout. The LTC4364-2 allows M1 to turn
back on and F LT to go high impedance after a cool down
timer cycle, provided the OV pin is below its threshold.
After the HGATE pin is latched low following fault, mo-
mentarily pulling the SHDN pin below 0.5V resets the fault
and allows HGATE to pull high for both LTC4364-1 and
LTC4364-2. In addition, momentarily pulling the UV pin
below 0.6V allows HGATE to pull high after the cool down
timer delay for LTC4364-1, but has no effect on LTC4364-2.
The source and drain of MOSFET M2 serve as the anode
and cathode of the ideal diode. The LTC4364 controls the
DGATE pin to maintain a 30mV forward voltage across the
drain and source terminals of M2. It reduces the power
dissipation and increases the available supply voltage to
the load, as compared to using a discrete blocking diode.
If M2 is driven fully on and the load current results in
more than 30mV of forward voltage, the forward voltage
is equal to RDS(ON) • ILOAD.
In the event of an input short or a power supply failure,
reverse current temporarily flows through the MOSFET
M2 that is on. If the reverse voltage exceeds –30mV, the
LTC4364 pulls the DGATE pin low strongly and turns off
M2, minimizing the disturbance at the output.
If the input supply drops below the GND pin voltage, the
DGATE pin is pulled to the SOURCE pin voltage, keeping
M2 off. When the HGATE pin pulls low in any fault condi-
tion, the DGATE pin also pulls low, so both pass devices
are turned off.
If the output (and so the SOURCE pin, through the body
diode of M2) drops below GND, the HGATE pin is pulled
to the SOURCE pin voltage, turning M1 off and shutting
down the forward current path.
An input undervoltage condition is accurately detected
using the UV pin. The HGATE and DGATE pins remain low
if UV is below its 1.25V threshold. The SHDN pin not only
turns off the pass devices but also shuts down the internal
circuitry, reducing the supply current to 10µA.
LTC4364-1/LTC4364-2
11
436412f
APPLICATIONS INFORMATION
Some power systems must cope with high voltage surges
of short duration such as those in automobiles. Load
circuitry must be protected from these transients, yet
critical systems may need to continue operating during
these events.
The LTC4364 drives an N-channel MOSFET (M1) at the
HGATE pin to limit the voltage and current to the load cir-
cuitry during supply transients or overcurrent events. The
selection of M1 is critical for this application. It must stay
on and provide a low impedance path from the input sup-
ply to the load during normal operation and then dissipate
power during overvoltage or overcurrent conditions. The
LTC4364 also drives a second N-channel MOSFET (M2) at
the DGATE pin as an ideal diode to protect the load from
damage during reverse polarity input conditions, and to
block reverse current flow in the event the input collapses.
A typical application circuit using the LTC4364 to regulate
the output at 27V during input surges with reverse input
protection is shown in Figure 1.
Overvoltage Fault
The LTC4364 limits the voltage at the OUT pin during an
overvoltage situation. An internal voltage amplifier regu-
lates the HGATE pin voltage to maintain 1.25V at the FB
pin. During this period of time, the N-channel MOSFET
M1 remains on and supplies current to the load. This
allows uninterrupted operation during brief overvoltage
transient events.
If the voltage regulation loop is engaged for longer than
the timeout period, set by the timer capacitor, an overvolt-
age fault is detected. The HGATE pin is pulled down to the
SOURCE pin by a 130mA current, turning M1 off. This
prevents M1 from being damaged during a long period
of overvoltage, such as during load dump in automobiles.
After the fault condition has disappeared and a cool down
period has transpired, the HGATE pin starts to pull high
again (LTC4364-2). The LTC4364-1 latches the HGATE pin
low after an overvoltage fault timeout and can be reset
using the SHDN or UV pin (see Resetting Faults).
Overcurrent Fault
The LTC4364 features an adjustable current limit that
protects against short circuits and excessive load current.
During an overcurrent event, the HGATE pin is regulated
to limit the current sense voltage across the SENSE and
OUT pins (VSNS) to 50mV when OUT is above 2.5V. The
current limit sense voltage is reduced to 25mV when OUT is
below 1.5V for additional protection during an output short.
A current sense resistor is placed between SENSE and
OUT and its value (RSNS) is determined by:
RSNS =
V
SNS
ILIM
where ILIM is the desired current limit.
Figure 1. 4A, 12V Overvoltage Output Regulator with Reverse Current Protection
+
OUTSENSEDGATESOURCEHGATE
TMRGND
CTMR
47nF
UV
UV = 6V
D1
CMZ5945B
68V
D3
1.5KE200A
MAX DC:
100V/–24V
MAX 1ms
TRANSIENT:
200V
D4
SMAJ24A
C1
0.1µF CHG
0.1µF
R4
2.2k
0.5W
OV = 60V OV ENOUT
FAULT
ENABLE
436412 F01
F LT
SHDN FB
R5
10Ω R6
100Ω
D5
1N4148W
VIN
12V
R2
90.9k
1%
R1
383k
1%
R3
10k
1%
R7
102k
1%
R8
4.99k
1%
COUT
22µF
VOUT
4A
CLAMPED AT 27V
M1
FDB33N25
M2
FDB3682
RSNS
10mΩ
VCC
LTC4364
LTC4364-1/LTC4364-2
12
436412f
APPLICATIONS INFORMATION
An overcurrent fault occurs when the current limit circuitry
has been engaged for longer than the timeout delay set
by the timer capacitor. The HGATE pin is then immediately
pulled low by 130mA to the SOURCE pin, turning off the
MOSFET M1. After the fault condition has disappeared
and a cool down period has transpired, the HGATE pin
is allowed to pull back up and turn on the pass device
(LTC4364-2). The LTC4364-1 latches the HGATE pin low
after the overcurrent fault timeout and can be reset using
the SHDN or UV pin (see Resetting Faults).
Input Overvoltage Comparator
Input overvoltage is detected with the OV pin and an ex-
ternal resistive divider connected to the input (Figure 1).
At power-up, if the OV pin voltage is higher than its 1.25V
threshold before the 100μs internal power-on-reset expires,
or before the input undervoltage condition is cleared at
the UV pin, the HGATE pin will be held low until the OV
pin voltage drops below its threshold. To prevent start-up
in the event the board is hot swapped into an overvoltage
supply, separate resistive dividers with filtering capacitors
can be used for the OV and UV pins (Figure 2). The RC
constants should be skewed so that τUV/τOV > 50. In Fig-
ure2, If the board is plugged into a supply that is higher
than 60V, the LTC4364 will not turn on the pass devices
until the supply voltage drops below 60V.
Once the HGATE pin begins pulling high, an input overvolt-
age condition detected by OV will not turn off the pass
device. Instead, OV prevents the LTC4364 from restarting
following a fault (see Cool Down Period and Restart). This
prevents the pass device from cycling between ON and OFF
states when the input voltage stays at an elevated level for
a long period of time, reducing the stress on the MOSFET.
Input Undervoltage Comparator
The LTC4364 detects input undervoltage conditions such
as low battery using the UV pin. When the voltage at the
UV pin is below its 1.25V threshold, the HGATE pin pulls
low to keep the pass device off. Once the UV pin voltage
rises above the UV threshold plus the UV hysteresis (50mV
typical), the HGATE pin is allowed to pull up without go-
ing through a timer cycle. In Figure 1 and Figure 2, the
input UV threshold is set by the resistive dividers to 6V.
An undervoltage condition does not produce an output
at the F LT pin.
Fault Timer
The LTC4364 includes an adjustable fault timer. Con-
necting a capacitor from the TMR pin to ground sets the
delay period before the MOSFET M1 is turned off during
an overvoltage or overcurrent fault condition. The same
capacitor also sets the cool down period before M1 is
allowed to turn back on after the fault condition has
disappeared. Once a fault condition is detected, a current
source charges up the TMR pin. The current level varies
depending on the voltage drop across the VCC pin and the
OUT pin, corresponding to the MOSFET VDS. The on time
is inversely proportional to the voltage drop across the
MOSFET. This scheme therefore takes better advantage
of the available safe operating area (SOA) of the MOSFET
than would a fixed timer current.
The timer current starts at around 2μA with 0.5V or less
of VCC – VOUT, increasing linearly to 50μA with 75V of
VCC – VOUT during an overvoltage fault (Figure 3a):
ITMR(UP)OV = 2μA + 0.644[μA/V] • (VCC – VOUT – 0.5V)
During an overcurrent fault, the timer current starts at
10μA with 0.5V or less of VCC – VOUT and increases to
260μA with 75V of VCC – VOUT (Figure 3b):
ITMR(UP)OC = 10μA + 3.36[μA/V] • (VCC – VOUT – 0.5V)
This arrangement allows the pass device to turn off faster
during an overcurrent event, since more power is dissipated
under this condition. Refer to the Typical Performance
Characteristics section for the timer current at different
VCC – VOUT in both overvoltage and overcurrent events.
475k
V
IN
UV = 6V
0V = 60V
436412 F02
10k
383k
100k
τUV = (383k||100k) • 10nF
τOV = (475k||10k) •1nF
10nF
1nF
UV
LTC4364
OV
Figure 2. External UV and OV Configuration Blocks Start-Up Into
an Overvoltage Condition
LTC4364-1/LTC4364-2
13
436412f
ITMR = 5µA ITMR = 5µA
0
0
1.25
1.35
1.25
TIME
TIME
436412 F03
tWARNING
20ms/µF
(3a) Overvoltage Fault Timer Current
(3b) Overcurrent Fault Timer Current
tWARNING
0.38ms/µF
tWARNING
20ms/µF
tF LT
25ms/µF
tF LT
4.8ms/µF
tWARNING
2.38ms/µF
tF LT
29.8ms/µF
tF LT
156ms/µF
1.35
VTMR (V)
VTMR (V)
VCC – VOUT = 75V
(ITMR = 50µA)
VCC – VOUT
= 75V
=10V
VCC – VOUT
= 75V
=10V
VCC – VOUT = 75V
(ITMR = 260µA)
VCC – VOUT = 10V
(ITMR = 42µA)
VCC – VOUT = 10V
(ITMR = 8µA)
Figure 3. Fault Timer Current of the LTC4364
When the voltage at the TMR pin, VTMR, reaches 1.25V,
the F LT pin pulls low to indicate the detection of a fault
condition and provide warning of the impending power
loss. In the case of an overvoltage fault, the timer current
then switches to a fixed 5μA. The interval between F LT
asserting low and the MOSFET M1 turning off is given by:
tWARNING =CTMR 100mV
5µA
This constant early warning period allows the load to
perform necessary backup or housekeeping functions
before the supply is cut off. After VTMR crosses the 1.35V
threshold, the pass device M1 turns off immediately. Note
that during an overcurrent event, the timer current is not
reduced to 5μA after VTMR has reached 1.25V threshold,
since it would lengthen the overall fault timer period and
cause more stress on the power transistor during an
overcurrent event.
Assuming VCC – VOUT remains constant, the on-time of
HGATE during an overvoltage fault is:
tOV =
C
TMR
1.25V
ITMR(UP)OV
+
C
TMR
100mV
5µV
and that during an overcurrent fault is:
tOC =
C
TMR
1.35V
ITRM(UP)OC
If the fault condition disappears after TMR reaches 1.25V
but is lower than 1.35V, the TMR pin is discharged by 2μA.
When TMR drops to 0.15V, the F LT pin resets to a high
impedance state.
Cool Down Period and Restart
As soon as TMR reaches 1.35V and HGATE pulls low in
a fault condition, the TMR pin starts discharging with a
2μA current. When the TMR pin voltage drops to 0.15V,
TMR charges with 2μA. When TMR reaches 1.35V, it starts
discharging again with 2μA. This pattern repeats 32 times
to form a long cool down timer period before retry (Fig-
ure4). At the end of the cool down period (when the TMR
pin voltage drops to 0.15V the 32nd time), the voltage at
the OV pin is checked. If the OV voltage is above its 1.25V
threshold, retry is inhibited and the HGATE pin remains
low. If the OV pin voltage is below 1.25V minus the OV
hysteresis, the LTC4364-2 retries, pulling the HGATE pin
up and turning on the pass device M1. The F LT pin will
then go to a high impedance state. The total cool down
timer period is given by:
tCOOL =63 CTMR 1.2V
2µA
The latch-off version, LTC4364-1, latches the HGATE and
F LT pins low after a fault timeout. It also generates the
cool down TMR pulses as shown in Figure 4, but does
not retry after the cool down period. There are two ways
to restart the part. The first method is to pull the UV pin
below 0.6V momentarily (>10μs) after the cool down timer
APPLICATIONS INFORMATION
LTC4364-1/LTC4364-2
14
436412f
period. If the UV reset pulse is asserted during the cool
down period, the TMR pulses are unaffected and the part
restarts after the cool down period ends. If OV is higher
than 1.25V while UV reset pulse is applied, the part will
not restart until OV drops below 1.25V even if the cool
down period ends.
The second method of restarting the LTC4364-1 is to
pulse the SHDN pin low for more than 200μs. If this is
applied during the cool down period, the cool down timer
is reset with 1mA quickly discharging the TMR pin, and
the part will restart when TMR drops below 0.15V. If the
SHDN reset pulse is applied after the cool down period,
the part restarts immediately. Sufficient cool down time
should be allowed before toggling the SHDN pin to prevent
overstressing the pass device.
A UV reset pulse has no effect on the operation of the
LTC4364-2. However, if a SHDN reset pulse as described
above is asserted in the middle of the cool down period, the
TMR pin quickly discharges with 1mA and the LTC4364-2
is allowed to restart once TMR drops below 0.15V. The OV
pin gates the restart of either LTC4364-1 or LTC4364-2
with a SHDN reset pulse. The part will not restart until OV
drops below 1.25V.
Reverse Input Protection
The LTC4364 can withstand reverse voltage without dam-
age. The VCC, SHDN, UV, OV, HGATE, SOURCE and DGATE
pins can all withstand up to –40V with respect to GND.
The LTC4364 controls a second N-channel MOSFET (M2)
as an ideal diode to replace an in-line blocking diode for
reverse input protection with minimum voltage drop in
normal operation. In the event of an input short or a power
supply brownout, reverse current may temporarily flow
through M2. The LTC4364 detects this reverse current
and immediately pulls the DGATE pin to the SOURCE pin,
turning off M2. This minimizes discharge of the output
reservoir capacitor and holds up the output voltage. In
the case where the input supply drops below ground, the
SOURCE pin is pulled below ground through the body
diode of M1. The LTC4364 responds to this condition by
shorting the DGATE pin to the SOURCE pin, keeping M2 off.
MOSFET Selection
The LTC4364 drives two N-channel MOSFETs, M1 and M2,
as the pass devices to conduct the load current (Figure1).
The important features are on-resistance, RDS(ON), the
maximum drain-source voltage, V(BR)DSS, the threshold
voltage, and the safe operating area, SOA.
The maximum drain-source voltage rating must be higher
than the maximum input voltage. If the output is shorted to
ground or in an overvoltage event, the full supply voltage
will appear across M1. If the input is shorted to ground,
M2 will be stressed by the voltage held up at the output.
The gate drive for both MOSFETs is guaranteed to be more
than 10V and less than 16V for those applications with VCC
higher than 8V. This allows the use of standard threshold
voltage N-channel MOSFETs. For systems with VCC less
than 8V, a logic-level MOSFET is required since the gate
drive can be as low as 5V. For supplies of 24V or higher, a
15V Zener diode is recommended to be placed between
1.35V
1.25V
FB
TMR
∆VHGATE
F LT
1.25V
<1.25V
1st 2nd 31st
0.15V
32nd
436412 F04
OV < 1.25V CHECKED
COOL DOWN PERIOD
Figure 4. Auto-Retry Cool Down Timer Cycle Following an Overvoltage Fault (LTC4364-2 Only)
APPLICATIONS INFORMATION
LTC4364-1/LTC4364-2
15
436412f
gate and source of each MOSFET for extra protection
(Figures 8 to 10).
Transient Stress in the MOSFET
The SOA of the MOSFET must encompass all fault condi-
tions. In normal operation the pass devices are fully on,
dissipating very little power. But during either overvoltage or
overcurrent faults, the HGATE pin is controlled to regulate
either the output voltage or the current through MOSFET
M1. Large current and high voltage drop across M1 can
coexist in these cases. The SOA curves of the MOSFET
must be considered carefully along with the selection of
the fault timer capacitor.
During an overvoltage event, the LTC4364 drives the pass
MOSFET M1 to regulate the output voltage at an acceptable
level. The load circuitry may continue operating throughout
this interval, but only at the expense of dissipation in the
MOSFET pass device. MOSFET dissipation or stress is a
function of the input voltage waveform, regulation voltage
and load current. The MOSFET must be sized to survive
this stress.
Most transient event specifications use the model shown
in Figure 5. The idealized waveform comprises a linear
ramp of rise time tr, reaching a peak voltage of VPK and
exponentially decaying back to VIN with a time constant
of τ. A typical automotive transient specification has
constants of tr = 10μs, VPK = 80V and τ = 1ms. A surge
condition known as “load dump” has constants of tr =
5ms, VPK = 60V and τ = 200ms.
MOSFET stress is the result of power dissipated within
the device. For long duration surges of 100ms or more,
stress is increasingly dominated by heat transfer; this is
a matter of device packaging and mounting, and heat sink
thermal mass. This is analyzed by simulation, using the
MOSFETs thermal model.
For short duration transients of less than 100ms, MOS-
FET survival is increasingly a matter of SOA, an intrinsic
property of the MOSFET. SOA quantifies the time required
at any given condition of VDS and ID to raise the junction
temperature of the MOSFET to its rated maximum. MOSFET
SOA is expressed in units of watt-squared-seconds (P2t),
which is an integral of P(t)2dt over the duration of the
transient. This figure is essentially constant for intervals
of less than 100ms for any given device type, and rises
to infinity under DC operating conditions. Destruction
mechanisms other than bulk die temperature distort the
lines of an accurately drawn SOA graph so that P2t is not
the same for all combinations of ID and VDS. In particular
P2t tends to degrade as VDS approaches the maximum
rating, rendering some devices useless for absorbing
energy above a certain voltage.
Calculating Transient Stress
To select a MOSFET suitable for any given application,
the SOA stress of M1 must be calculated for each input
transient which shall not interrupt operation. It is then
a simple matter to choose a device which has adequate
SOA to survive the maximum calculated stress. P2t for a
prototypical transient waveform is calculated as follows
(Figure 6).
Let:
a = VREG – VIN
b = VPK – VIN
where VIN = Nominal Input Voltage.
V
PK
τ
VIN
436412 F05
tr
Figure 5. Prototypical Transient Waveform Figure 6. Safe Operating Area Required to Survive Prototypical
Transient Waveform
V
PK
= 80V
τ = 1ms
VIN = 12V
436412 F06
VREG = 16V
tr = 10µs
APPLICATIONS INFORMATION
LTC4364-1/LTC4364-2
16
436412f
Then:
P2t=ILOAD21
3tr
ba
( )
3
b+1
2τ2a2In b
a+3a2+b2 4ab
Typically VREG ≈ VIN and τ >> tr simplifying the above to:
P2t=1
2
ILOAD2VPK VREG
( )
2τ
For the transient conditions of VPK = 80V, VIN = 12V, VREG
= 16V, tr = 10μs and τ = 1ms, and a load current of 3A,
P2t is 18.4W2s—easily handled by a MOSFET in a D-pak
package. The P2t of other transient waveshapes is evalu-
ated by integrating the square of MOSFET power versus
time. LTSpice™ can be used to simulate timer behavior
for more complex transients and cases where overvoltage
and overcurrent faults coexist.
Short-Circuit Stress
SOA stress of M1 must also be calculated for output short-
circuit conditions. Short-circuit P2t is given by:
P2t=VIN VSNS
RSNS
2
tOC
where VSNS is the overcurrent fault threshold and tOC is
the overcurrent timer interval.
For VIN = 15V, OUT = 0V, VSNS = 25mV, RSNS = 12mΩ
and CTMR = 100nF, P2t is 2.2W2s—less than the transient
SOA calculated in the previous example. Nevertheless,
to account for circuit tolerances this figure should be
doubled to 4.4W2s.
Limiting Inrush Current and HGATE Pin Compensation
The LTC4364 limits the inrush current to any load capaci-
tance by controlling the HGATE pin voltage slew rate. An
external capacitor, CHG, can be connected from HGATE
to ground to slow down the inrush current further at the
expense of slower turn-off time. The gate capacitor is set at:
CHG =IHGATE(UP)
IINRUSH
CL
where IHGATE(UP) is the HGATE pin pull-up current, IINRUSH
is the desired inrush current, CL is total load capacitance
at the output. In typical applications, a CHG of 6.8nF is
recommended for loop compensation during overvoltage
and overcurrent events. With input voltage steps faster
than 5V/μs, a larger gate capacitor helps prevent self
enhancement of the N-channel MOSFET.
The added gate capacitor slows down the turn-off time
during fault conditions and allows higher peak currents to
build up during an output short event. If this is a concern,
an extra resistor, R6, in series with CHG can restore the
turn-off time. A diode, D5, should be placed across R6
with the cathode connected to CHG as shown in Figure 1.
In a fast transient input step, D5 provides a bypass path to
CHG for the benefit of holding HGATE low and preventing
self enhancement.
Shutdown
The LTC4364 can be shut down to a low current mode
by pulling SHDN below 0.5V. The quiescent VCC current
drops to 10μA for both the LTC4364-1 and the LTC4364-2.
The SHDN pin can be pulled up to 100V or below GND by
up to 40V without damage. Leaving the pin open allows
an internal current source to pull it up to about 4V and
turn the part on. The leakage current at the pin should be
limited to no more than 1μA if no pull-up device is used
to help turn it on.
Supply Transient Protection
The LTC4364 is tested to operate to 80V and guaranteed
to be safe from damage between 100V and −40V. Voltage
transients above 100V or below −40V may cause permanent
damage. During a short-circuit condition, the large change
in current flowing through power supply traces coupled
with parasitic inductances from associated wiring can
cause destructive voltage transients in both positive and
negative directions at the VCC, SOURCE, and OUT pins. To
reduce the voltage transients, minimize the power trace
parasitic inductance by using short, wide traces. A small
RC filter (R4 and C1 in Figure 1) at the VCC pin filters high
voltage spikes of short pulse width.
APPLICATIONS INFORMATION
LTC4364-1/LTC4364-2
17
436412f
Another way to limit supply transients above 100V at the
VCC pin is to use a Zener diode and a resistor, D1 and R4,
as shown in Figure 1. D1 clamps voltage spikes at the VCC
pin while R4 limits the current through D1 to a safe level
during the surge. In the negative direction, D1 along with
R4 clamps the VCC pin near GND. The inclusion of R4 in
series with the VCC pin increases the minimum required
supply voltage due to the extra voltage drop across the
resistor, which is determined by the supply current of the
LTC4364 and the leakage current of D1. 2.2k adds about
1V to the minimum operating voltage.
For sustained, elevated suppy voltages, the power dissipa-
tion of R4 becomes unacceptable. This can be resolved
by using an external NPN transistor (Q1 in Figure 7) as
a buffer. To protect Q1 against supply reversal, block the
collector of Q1 with a series diode or tie it to the cathode
of D3 and D4 in Figure 1.
Transient suppressor D3 in Figure 1 clamps the input
voltage to 200V for voltage transients higher than 200V,
to prevent breakdown of M1. It also blocks forward con-
duction in D4. D4 limits the SOURCE pin voltage to 24V
below GND when the input goes negative. COUT helps
absorb the inductive energy at the output upon a sudden
input short, protecting the OUT and SENSE pins.
Output Port Protection
In applications where the output is on a connector, as
shown in Figure 14, if the output is plugged into a supply
that is higher than the input, the ideal diode MOSFET, M2,
turns off to open the backfeeding path. In the case where
the output port is plugged into a supply that is below GND,
the SOURCE pin is pulled below GND through the body
diode of M2. The LTC4364 responds to this condition by
shorting the HGATE pin to the SOURCE pin, turning M1
off and shutting down the current path from VIN to VOUT.
Design Example
As a design example, consider an application with the
following specifications: VIN = 8V to 14V DC with a peak
transient of 200V and decay time constant τ of 1ms, VOUT
≤ 27V, minimum current limit ILIM(MIN) at 4A, low-battery
detection at 6V, input overvoltage level at 60V, and 1ms
of overvoltage early warning (Figure 1).
Selection of CMZ5945B for D1 will limit the voltage at
the VCC pin to less than 71V during the 200V surge. The
minimum required voltage at the VCC pin is 4V when VIN is
at 6V; the maximum supply current for LTC4364 is 750μA.
The maximum value for R4 to ensure proper operation is:
R4 =
6V 4V
0.75mA =2.7k
Select 2.2k for R4 to accommodate all conditions.
With the minimum Zener voltage at 64V, the peak current
through R4 into D1 is then calculated as:
ID1(PK) =
200V 64V
2.2k
=62mA
which can be handled by the CMZ5945B with a peak power
rating of 200W at 10/1000μs.
With a bypass capacitance of 0.1μF (C1), along with R4
of 2.2k, high voltage transients up to 250V with a pulse
width less than 20μs are filtered out at the VCC pin.
Next, calculate the resistive divider value to limit VOUT to
27V during an overvoltage event:
VREG =1.25V R7 +R8
( )
R8 =27V
APPLICATIONS INFORMATION
VCC
LTC4364
GND
436412 F07
C1
100nF
Q1
PZTA42
VIN
200V
D1
CMZ5945B
68V
R4
22k
1/4W
Figure 7. Buffering VCC to Extend Input Supply Range
Output Bypassing
The OUT and SENSE pins can withstand up to 100V above
and 20V below GND. In all applications the output must
be bypassed with at least 22μF low ESR electrolytic (COUT
in Figure 1) to stabilize the voltage and current limiting
loops, and to minimize capacitive feedthrough of input
transients. Total ceramic bypassing of up to one-tenth
the total electrolytic capacitance is permissible without
compromising performance.
LTC4364-1/LTC4364-2
18
436412f
Choosing 250μA for the resistive divider:
R8 =1.25V
250µA =5k
Select 4.99k for R8.
R7 =27V 1.25V
( )
R8
1.25V =102.8k
The closest standard value for R7 is 102k.
Now, calculate the sense resistor, RSNS, value:
RSNS =VSNS(MIN)
ILIM
=45mV
4A =11m
Choose 10mΩ for RSNS.
CTMR is then chosen for 1ms of early warning time:
CTMR =
1ms5µA
100mV =50nF
The closest standard value for CTMR is 47nF.
Finally, calculate R1, R2 and R3 for 6V low battery detec-
tion and 60V input overvoltage level:
6V
R1+R2+R3 =1.25V
R2+R3
60V
R1+R2+R3
=1.25V
R3
Simplify the equations and choose 10k for R3 to get:
R2 =60V
6V 1
R3 =9R3 =90k
R1=6V
1.25V 1
R2+R3
( )
=3.8 R1+R2
( )
=380k
Select 90.9kΩ for R2 and 383kΩ for R1.
The pass device, M1, should be chosen to withstand an
output short condition with VCC = 14V. In the case of a
severe output short where VOUT = 0V, ITMR(UP) = 55μA and
the total overcurrent fault time is:
tOC =CTMR VTMR(G)
ITRM(UP)
=47nF 1.35V
55µA =1.15ms
The maximum power dissipation in M1 is:
P=
V
DS(M1)
V
SNS(MAX)
RSNS
=14V 32mV
10m=45W
The corresponding P2t is 2.3W2s.
During an output overload or soft short, the voltage at the
OUT pin could stay at 2V or higher. The total overcurrent
fault time when VOUT = 2V is:
tOC =
47nF 1.35V
49µA =1.3ms
The maximum power dissipation in M1 is:
P=14V 2V
( )
55mV
10m
=66W
The corresponding P2t is 5.7W2s. Both of the above condi-
tions are well within the safe operating area of FDB33N25.
To select the pass device, M2, first calculate RDS(ON) to
achieve the desired forward drop VFW at maximum load
current (5.5A). If VFW = 0.25V:
RDS(ON) VFW
ILOAD(MAX)
=0.25V
5.5A =45.5m
The FDB3682 offers a maximum RDS(ON) of 36mΩ at
VGS = 10V so is a good fit. Its minimum BVDSS of 100V
is also sufficient to handle VOUT transients up to 100V
during an input short-circuit event.
Layout Considerations
To achieve accurate current sensing, use Kelvin connections
to the current sense resistor, RSNS. Limit the resistance
from the SOURCE pin to the sources of the MOSFETs to
below 10Ω. The minimum trace width for 1oz copper foil
is 0.02" per amp to ensure the trace stays at a reason-
able temperature. Note that 1oz copper exhibits a sheet
resistance of about 530μΩ/square. Small resistances can
cause large errors in high current applications. Noise im-
munity will be improved significantly by locating resistive
dividers close to the pins with short VCC and GND traces.
APPLICATIONS INFORMATION
LTC4364-1/LTC4364-2
19
436412f
TYPICAL APPLICATIONS
Figure 8. 2A Wide Range Hot Swap Controller with Circuit Breaker
Figure 9. 28V Hot Swap with Overvoltage Output Regulation at 27V, Circuit Breaker, and Reverse Current Protection
Figure 10. 48V Hot Swap with Overvoltage Output Regulation at 72V, Circuit Breaker, and Reverse Current Protection
+
OUTSENSEDGATESOURCEHGATE
TMRGND
CTMR
0.22µF
UV
OV ENOUT
436412 F08
F LT
SHDN FB
R5
10Ω
VIN
5V TO 28V
R2
44.2k
R1
118k
UV
4.2V
OV
36V
D1
SMAT70A
R3
5.9k
CLOAD
100µF
VOUT
2A
M1
SUD50N03-9
RSNS
20mΩ
CHG
47nF
D6
DDZ9702T
VCC
LTC4364
+
OUTSENSEDGATESOURCEHGATE
TMRGND
CTMR
0.1µF
UV
OV ENOUT
436412 F09
F LT
SHDN FB
R5
10Ω
R8
4.02k
VIN
18V TO 33V
R2
6.04k
OV
45V
UV
15V
R1
100k
R3
3.01k
CLOAD
100µF
VOUT
2.5A
CLAMPED
AT 36V
M1
FDB3632
D6
DDZ9702T
M2
FDMS86101
RSNS
15mΩ
CHG
47nF
VCC
LTC4364
R7
110k
D7
DDZ9702T
+
OUTSENSEDGATESOURCEHGATE
TMRGND
CTMR
0.1µF
UV
OV ENOUT
436412 F10
F LT
SHDN FB
R5
10Ω
R4
2.2k
VIN
36V TO 72V
R1
205k
UV
36V
OV
76V
R2
3.92k
R3
3.48k
R7
226k
R8
4.02k
CLOAD
330µF
VOUT
4A
CLAMPED
AT 72V
D1
CMZ5945B
68V
M1
FDB33N25
M2
FDB3632
RSNS
10mΩ
CHG
47nF
VCC
LTC4364
D6
DDZ9702T
D7
DDZ9702T
LTC4364-1/LTC4364-2
20
436412f
TYPICAL APPLICATIONS
Figure 11. Redundant Supply Diode-OR with Overvoltage Surge Protection
Figure 12. High Side Switch with Ideal Diode for Load Protection
+
OUTSENSEDGATESOURCEHGATE
TMR
CTMRA
0.22µF
UV
OV
ENOUT
F LT
SHDN FB
R5A
10Ω
VINA
12V
R7A
59k
R8A
4.99k
COUTA
22µF
VOUT
CLAMPED
AT 16V
M1A
FDD16AN08A0
M2A
FDD16AN08A0
RSNSA
10mΩ
CHGA
6.8nF
VCC
LTC4364
+
OUTSENSEDGATESOURCEHGATE
TMR
CTMRB
0.22µF
UV
OV
ENOUT
F LT
SHDN FB
R5B
10Ω
VINB
12V
R7B
59k
R8B
4.99k
436412 F11
COUTB
22µF
M1B
FDD16AN08A0
M2B
FDD16AN08A0
RSNSB
10mΩ
CHGB
6.8nF
VCC
LTC4364
GND
GND
OUTSENSEDGATESOURCEHGATE
TMR GND
UV
SHDN M3
VN2222
100k
OV ENOUT
436412 F12
F LT
SHDN FB
VIN
12V CLOAD
VOUT
M1
FDB3632
M2
FDMS86101
VCC
LTC4364
LTC4364-1/LTC4364-2
21
436412f
TYPICAL APPLICATIONS
Figure 13. Overvoltage Regulator with Output Keep Alive During Shutdown
PACKAGE DESCRIPTION
DE Package
14-Lead Plastic DFN (4mm × 3mm)
(Reference LTC DWG # 05-08-1708 Rev B)
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
3.00 ±0.10
(2 SIDES)
4.00 ±0.10
(2 SIDES)
NOTE:
1. DRAWING PROPOSED TO BE MADE VARIATION OF VERSION (WGED-3) IN JEDEC
PACKAGE OUTLINE MO-229
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE
TOP AND BOTTOM OF PACKAGE
0.40 ± 0.10
BOTTOM VIEW—EXPOSED PAD
1.70 ± 0.10
0.75 ±0.05
R = 0.115
TYP
R = 0.05
TYP
3.00 REF
17
148
PIN 1
TOP MARK
(SEE NOTE 6)
0.200 REF
0.00 – 0.05
(DE14) DFN 0806 REV B
PIN 1 NOTCH
R = 0.20 OR
0.35 × 45°
CHAMFER
0.25 ± 0.05
0.50 BSC
3.30 ±0.10
1.70 ± 0.05
3.00 REF
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
2.20 ±0.05
0.70 ±0.05
3.60 ±0.05
PACKAGE
OUTLINE
0.25 ± 0.05
3.30 ±0.05
0.50 BSC
+
OUTSENSEDGATESOURCEHGATE
TMRGND
CTMR
0.1µF
UV
OV ENOUT
436412 F13
F LT
SHDN FB
R4
2.2k R5
10Ω
VIN
12V
R1
191k
UV
6V
OV
30V
R2
40.2k
R3
10k
R7
287k
R8
24.9k
COUT
22µF
D8
1N4746A
18V, 1W
VOUT
4A
CLAMPED
AT 16V
D1
CMZ5945B
68V
M1
FDD16AN08A0
M2
FDD16AN08A0
RSNS
10mΩ
R9
1k, 1W
CHG
6.8nF
VCC
LTC4364
LTC4364-1/LTC4364-2
22
436412f
MS Package
16-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1669 Rev Ø)
MSOP (MS16) 1107 REV Ø
0.53 ± 0.152
(.021 ± .006)
SEATING
PLANE
0.18
(.007)
1.10
(.043)
MAX
0.17 –0.27
(.007 – .011)
TYP
0.86
(.034)
REF
0.50
(.0197)
BSC
16151413121110
12345678
9
NOTE:
1. DIMENSIONS IN MILLIMETER/(INCH)
2. DRAWING NOT TO SCALE
3. DIMENSION DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR GATE BURRS.
MOLD FLASH, PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
4. DIMENSION DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSIONS.
INTERLEAD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
5. LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE 0.102mm (.004") MAX
0.254
(.010) 0° – 6° TYP
DETAIL “A”
DETAIL “A”
GAUGE PLANE
5.23
(.206)
MIN
3.20 – 3.45
(.126 – .136)
0.889 ± 0.127
(.035 ± .005)
RECOMMENDED SOLDER PAD LAYOUT
0.305 ± 0.038
(.0120 ± .0015)
TYP
0.50
(.0197)
BSC
4.039 ± 0.102
(.159 ± .004)
(NOTE 3)
0.1016 ± 0.0508
(.004 ± .002)
3.00 ± 0.102
(.118 ± .004)
(NOTE 4)
0.280 ± 0.076
(.011 ± .003)
REF
4.90 ± 0.152
(.193 ± .006)
PACKAGE DESCRIPTION
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
LTC4364-1/LTC4364-2
23
436412f
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representa-
tion that the interconnection of its circuits as described herein will not infringe on existing patent rights.
PACKAGE DESCRIPTION
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
.016 – .050
(0.406 – 1.270)
.010 – .020
(0.254 – 0.508)× 45°
0° – 8° TYP
.008 – .010
(0.203 – 0.254)
1
N
2345678
N/2
.150 – .157
(3.810 – 3.988)
NOTE 3
16 15 14 13
.386 – .394
(9.804 – 10.008)
NOTE 3
.228 – .244
(5.791 – 6.197)
12 11 10 9
S16 REV G 0212
.053 – .069
(1.346 – 1.752)
.014 – .019
(0.355 – 0.483)
TYP
.004 – .010
(0.101 – 0.254)
.050
(1.270)
BSC
.245
MIN
N
1 2 3 N/2
.160 ±.005
RECOMMENDED SOLDER PAD LAYOUT
.045 ±.005
.050 BSC
.030 ±.005
TYP
INCHES
(MILLIMETERS)
NOTE:
1. DIMENSIONS IN
2. DRAWING NOT TO SCALE
3. THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.
MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED .006" (0.15mm)
4. PIN 1 CAN BE BEVEL EDGE OR A DIMPLE
S Package
16-Lead Plastic Small Outline (Narrow .150 Inch)
(Reference LTC DWG # 05-08-1610 Rev G)
LTC4364-1/LTC4364-2
24
436412f
Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 FAX: (408) 434-0507 www.linear.com
LINEAR TECHNOLOGY CORPORATION 2012
LT 0712 • PRINTED IN USA
RELATED PARTS
TYPICAL APPLICATION
PART NUMBER DESCRIPTION COMMENTS
LT
®
4356-1/LT4356-2
LT4356-3
Surge Stopper LT4356-1: 7A Shutdown Mode
LT4356-2: Auxiliary Amplifier Alive in Shutdown Mode
LT4356-3: Fault Latchoff
LTC4363 High Voltage Surge Stopper 4V to 80V, VCC Clamp, Adjustable Output Voltage Clamp, 60V Reverse
Input Protection, Overcurrent Protection
LTC4366 Floating Surge Stopper 9V to >500V Operation, Adjustable Output Voltage Clamp
LTC4357 Positive High Voltage Ideal Diode Controller 0.5µs Turn-Off Time, 9V to 80V
LTC4359 Ideal Diode Controller with Reverse Input Protection 4V to 80V Operation, –40V Reverse-Input Protection, Low 13µA
Shutdown Current
LTC4352 Ideal MOSFET ORing Diode External N-Channel MOSFETs Replace ORing Diodes, 0V to 18V
LTC4354 Negative Voltage Diode-OR Controller Controls Two N-Channel MOSFETs, 1µs Turn-Off, 80V Operation
LTC4355 Positive Voltage Diode-OR Controller Controls Two N-Channel MOSFETs, 0.5µs Turn-Off, 80V Operation
LTC4365 Window Passer - OV, UV and Reverse Supply Protection
Controller
2.5V to 34V Operation, Protects 60V to –40V
Figure 14. 0.25A, 12V Surge Stopper with Output Port Protection
OUTSENSEDGATESOURCEHGATE
UV
OV
0.1µF
ENOUT
436412 F14
F LT
SHDN FB
R5
10Ω
VIN
12V
R2
90.9k
1%
R1
383k
1%
UV
6V
OV
60V R3
10k
1%
*PROTECTED AGAINST BACKFEEDING
OR FORWARD CONDUCTING
FROM –20V TO 50V
VOUT*
CLAMPED
AT 18V
M1
FDB3632
M2
FDMS86101
RSNS
0.2Ω
CHG
6.8nF
CIN
10µF
10µF
50V
CER
10µF
50V
CER
VCC
LTC4364
GND TMR
R8
4.99k
1%
R9
16.9k
1%
RESR
100mΩ
D2
DDZ9702T
15V
R7
49.9k
1%