LINER LTC4252A-1IMSTR Negative voltage hot swap controller Datasheet

LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
Negative Voltage
Hot Swap Controllers
U
FEATURES
DESCRIPTIO
■
The LTC®4252 negative voltage Hot SwapTM controller
allows a board to be safely inserted and removed from a
live backplane. Output current is controlled by three stages
of current limiting: a timed circuit breaker, active current
limiting and a fast feedforward path that limits peak
current under worst-case catastrophic fault conditions.
■
■
■
■
■
■
■
■
■
■
Allows Safe Board Insertion and Removal from a
Live – 48V Backplane
Floating Topology Permits Very High Voltage
Operation
Programmable Analog Current Limit With Circuit
Breaker Timer
Fast Response Time Limits Peak Fault Current
Programmable Soft-Start Current Limit
Programmable Timer with Drain Voltage
Accelerated Response
±1% Undervoltage/Overvoltage Threshold Accuracy
(LTC4252A)
Adjustable Undervoltage/Overvoltage Protection
LTC4252-1/LTC4252A-1: Latch Off After Fault
LTC4252-2: Automatic Retry After Fault
Available in 8-Pin and 10-Pin MSOP Packages
U
APPLICATIO S
■
■
■
■
■
■
■
Adjustable undervoltage and overvoltage detectors disconnect the load whenever the input supply exceeds the
desired operating range. The LTC4252’s supply input is
shunt regulated, allowing safe operation with very high
supply voltages. A multifunction timer delays initial startup and controls the circuit breaker’s response time. The
circuit breaker’s response time is accelerated by sensing
excessive MOSFET drain voltage, keeping the MOSFET
within its safe operating area (SOA). An adjustable softstart circuit controls MOSFET inrush current at start-up.
The LTC4252-1/LTC4252A-1 latch off after a circuit breaker
fault times out. The LTC4252-2 provides automatic retry
after a fault. The LTC4252A-1/LTC4252A-2 feature tight
±1% undervoltage/overvoltage threshold accuracy. The
LTC4252 is available in either an 8-pin or 10-pin MSOP.
Hot Board Insertion
Electronic Circuit Breaker
– 48V Distributed Power Systems
Negative Power Supply Control
Central Office Switching
High Availability Servers
ATCA
, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.
Hot Swap is a trademark of Linear Technology Corporation.
U
TYPICAL APPLICATIO
Start-Up Behavior
– 48V/2.5A Hot Swap Controller
GND
RIN
3× 1.8k IN SERIES
1/4W EACH
GND
(SHORT PIN)
+
CIN
1µF
VIN
R1
402k
1%
EN
OV
PWRGD
DRAIN
TIMER
CT
0.33µF
C1
10nF
*
UV
SS
CSS
68nF
VOUT
SENSE
2.5A/DIV
Q1
IRF530S
VOUT
20V/DIV
RD 1M
GATE
VEE
GATE
5V/DIV
LOAD
R3
5.1k
LTC4252-1
R2
32.4k
1%
CL
100µF
SENSE
RC
10Ω
CC
18nF
RS
0.02Ω
PWRGD
10V/DIV
4252-1/2 TA01
–48V
* M0C207
1ms/DIV
4252-1/2 TA01a
425212fb
1
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
W W
W
ABSOLUTE
AXI U RATI GS
All Voltages Referred to VEE (Note 1)
Current into VIN (100µs Pulse) ........................... 100mA
VIN, DRAIN Pin Minimum Voltage ....................... – 0.3V
Input/Output Pins
(Except SENSE and DRAIN) Voltage ..........– 0.3V to 16V
SENSE Pin Voltage ................................... – 0.6V to 16V
Current Out of SENSE Pin (20µs Pulse) ........... – 200mA
Current into DRAIN Pin (100µs Pulse) ................. 20mA
Maximum Junction Temperature .......................... 125°C
Operating Temperature Range
LTC4252-1C/LTC4252-2C
LTC4252A-1C/LTC4252A-2C ................... 0°C to 70°C
LTC4252-1I/LTC4252-2I
LTC4252A-1I/LTC4252A-2I ............... – 40°C to 85°C
Storage Temperature Range ................. – 65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
U
W
U
PACKAGE/ORDER I FOR ATIO
TOP VIEW
TOP VIEW
VIN
SS
SENSE
VEE
1
2
3
4
8
7
6
5
VIN
PWRGD
SS
SENSE
VEE
TIMER
UV/OV
DRAIN
GATE
MS8 PACKAGE
8-LEAD PLASTIC MSOP
1
2
3
4
5
10
9
8
7
6
TIMER
UV
OV
DRAIN
GATE
MS PACKAGE
10-LEAD PLASTIC MSOP
TJMAX = 125°C, θJA = 160°C/W
TJMAX = 125°C, θJA = 160°C/W
ORDER PART NUMBER
MS8 PART MARKING
ORDER PART NUMBER
MS PART MARKING
LTC4252-1CMS8
LTC4252-2CMS8
LTC4252-1IMS8
LTC4252-2IMS8
LTWM
LTWP
LTRQ
LTRR
LTC4252-1CMS
LTC4252-2CMS
LTC4252A-1CMS
LTC4252A-2CMS
LTC4252-1IMS
LTC4252-2IMS
LTC4252A-1IMS
LTC4252A-2IMS
LTWN
LTWQ
LTAFX
LTAGE
LTRS
LTRT
LTAFY
LTAGF
Order Options Tape and Reel: Add #TR Lead Free: Add #PBF Lead Free Tape and Reel: Add #TRPBF
Lead Free Part Marking: http://www.linear.com/leadfree/
Consult LTC Marketing for parts specified with wider operating temperature ranges.
425212fb
2
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 2)
LTC4252-1/-2
MIN TYP MAX
LTC4252A-1/-2
MIN TYP MAX
11.5
11.5
SYMBOL
PARAMETER
CONDITIONS
VZ
VIN – VEE Zener Voltage
IIN = 2mA
rZ
VIN – VEE Zener Dynamic Impedance
IIN = 2mA to 30mA
IIN
VIN Supply Current
UV = OV = 4V, VIN = (VZ – 0.3V)
●
0.8
2
0.9
2
mA
VLKO
VIN Undervoltage Lockout
Coming Out of UVLO (Rising VIN)
●
9.2
11.5
9
10
V
VLKH
VIN Undervoltage Lockout Hysteresis
VCB
Circuit Breaker Current Limit Voltage
VCB = (VSENSE – VEE)
●
40
50
60
55
mV
VACL
Analog Current Limit Voltage
VACL = (VSENSE – VEE),
SS = Open or 2.2V
●
80
100
120
VACL
VCB
Analog Current Limit Voltage
Circuit Breaker Voltage
VACL = (VSENSE – VEE),
SS = Open or 1.4V
●
VFCL
Fast Current Limit Voltage
VFCL = (VSENSE – VEE)
●
VSS
SS Voltage
After End of SS Timing Cycle
RSS
SS Output Impedance
ISS
SS Pin Current
VOS
●
150
200
13
14.5
0.5
300
45
50
UNITS
V
Ω
5
1
V
mV
1.05
1.20
1.38
V/V
150
200
300
mV
2.2
1.4
V
100
50
kΩ
UV = OV = 4V, VSENSE = VEE,
VSS = 0V (Sourcing)
22
28
µA
UV = OV = 0V, VSENSE = VEE,
VSS = 2V (Sinking)
28
28
mA
Analog Current Limit Offset Voltage
GATE Pin Output Current
14.5
5
VACL+VOS Ratio (VACL + VOS) to SS Voltage
VSS
IGATE
13
UV = OV = 4V, VSENSE = VEE,
VGATE = 0V (Sourcing)
●
40
10
10
mV
0.05
0.05
V/V
58
80
40
58
80
µA
UV = OV = 4V, VSENSE – VEE = 0.15V,
VGATE = 3V (Sinking)
17
17
mA
UV = OV = 4V, VSENSE – VEE = 0.3V,
VGATE = 1V (Sinking)
190
190
mA
●
VGATE
External MOSFET Gate Drive
VGATE – VEE, IIN = 2mA
10
12
VZ
VGATEH
Gate High Threshold
VGATEH = VIN – VGATE, IIN = 2mA,
for PWRGD Status (MS Only)
2.8
2.8
V
VGATEL
Gate Low Threshold
(Before Gate Ramp-Up)
0.5
0.5
V
VUVHI
UV Pin Threshold HIGH
VUVLO
UV Pin Threshold LOW
VUV
UV Pin Threshold
Low-to-High Transition
●
VUVHST
UV Pin Hysteresis
(● for LTC4252A Only)
●
VOVHI
OV Pin Threshold HIGH
●
5.85
6.15
6.45
V
VOVLO
OV Pin Threshold LOW
●
5.25
5.55
5.85
V
VOV
OV Pin Threshold
Low-to-High Transition
●
VOVHST
OV Pin Hysteresis
(● for LTC4252A Only)
●
600
ISENSE
SENSE Pin Input Current
UV = OV = 4V, VSENSE = 50mV
●
–15
IINP
UV, OV Pin Input Current
UV = OV = 4V
●
±0.1
VTMRH
TIMER Pin Voltage High Threshold
4
4
V
VTMRL
TIMER Pin Voltage Low Threshold
1
1
V
●
3.075 3.225 3.375
●
2.775 2.925 3.075
300
10
12
VZ
V
V
V
3.05
3.08
3.11
V
292
324
356
mV
5.04
5.09
5.14
V
82
102
122
mV
–30
–15
–30
µA
±1
±0.1
±1
µA
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3
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 2)
LTC4252-1/-2
MIN TYP MAX
LTC4252A-1/-2
MIN TYP MAX
Timer On (Initial Cycle/Latchoff/
Shutdown Cooling, Sourcing),
VTMR = 2V
5.8
5.8
µA
Timer Off (Initial Cycle, Sinking),
VTMR = 2V
28
28
mA
Timer On (Circuit Breaker, Sourcing,
IDRN = 0µA), VTMR = 2V
230
230
µA
Timer On (Circuit Breaker, Sourcing,
IDRN = 50µA), VTMR = 2V
630
630
µA
Timer Off (Circuit Breaker/
Shutdown Cooling, Sinking),
VTMR = 2V
5.8
5.8
µA
SYMBOL
PARAMETER
CONDITIONS
ITMR
TIMER Pin Current
∆ITMRACC [(ITMR at IDRN = 50µA) – (ITMR at IDRN = 0µA)]
∆IDRN
∆IDRN
Timer On (Circuit Breaker with
IDRN = 50µA)
8
8
VDRNL
DRAIN Pin Voltage Low Threshold
For PWRGD Status (MS Only)
2.385
2.385
IDRNL
DRAIN Leakage Current
VDRAIN = 5V (4V for LTC4252A)
±0.1
VDRNCL
DRAIN Pin Clamp Voltage
IDRN = 50µA
VPGL
PWRGD Output Low Voltage
IPG = 1.6mA (MS Only)
IPG = 5mA (MS Only)
IPGH
PWRGD Pull-Up Current
VPWRGD = 0V (Sourcing) (MS Only) ●
tSS
SS Default Ramp Period
SS pin floating, VSS ramps from
0.2V to 2V
±1
±0.1
7
●
●
40
0.4
1.1
58
80
V
±1
40
µA
V
0.2
0.4
1.1
V
V
58
80
µA
µs
180
SS pin floating, VSS ramps from
0.1V to 0.9V
µA/µA
6
0.2
UNITS
230
µs
tPLLUG
UV Low to Gate Low
0.4
0.4
µs
tPHLOG
OV High to Gate Low
0.4
0.4
µs
Note 1: Stresses 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; all currents out of device
pins are negative. All voltages are referenced to VEE unless otherwise
specified.
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4
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U W
TYPICAL PERFOR A CE CHARACTERISTICS
rZ vs Temperature
VZ vs Temperature
14.5
10
IIN = 2mA
IIN vs Temperature
2000
IIN = 2mA
1800
9
VIN = (VZ – 0.3V)
1600
14.0
8
1400
7
13.0
1200
IIN (µA)
VZ (V)
rZ (Ω)
13.5
1000
6
5
800
600
4
400
12.5
3
12.0
–55 –35 –15
200
2
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
0
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G01
4252-1/2 G03
4252-1/2 G04
Undervoltage Lockout Hysteresis
VLKH vs Temperature
Undervoltage Lockout VLKO
vs Temperature
IIN vs VIN
12.0
1000
5 25 45 65 85 105 125
TEMPERATURE (°C)
1.5
11.5
TA = –40°C
VLKH (V)
TA = 85°C
10.5
VLKO (V)
IIN (mA)
TA = 25°C
10
1.3
11.0
100
10.0
9.5
TA = 125°C
1
1.1
0.9
9.0
0.7
8.5
0.1
0
2
4
6
8.0
–55 –35 –15
8 10 12 14 16 18 20 22
VIN (V)
0.5
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G05
4252-1/2 G02
4252-1/2 G06
Analog Current Limit Voltage
VACL vs Temperature
Circuit Breaker Current Limit
Voltage VCB vs Temperature
60
120
58
115
56
Fast Current Limit Voltage VFCL
vs Temperature
300
275
110
50
48
46
250
105
VFCL (mV)
52
VACL (mV)
VCB (mV)
54
100
95
225
200
90
44
175
85
42
40
–55 –35 –15
5 25 45 65 95 105 125
TEMPERATURE (°C)
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G07
80
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G08
150
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G09
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5
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U W
TYPICAL PERFOR A CE CHARACTERISTICS
VSS vs Temperature
2.35
2.30
RSS (kΩ)
2.25
2.20
2.15
110
45
108
40
106
35
104
30
102
ISS (mA)
2.40
VSS (V)
ISS (Sinking) vs Temperature
RSS vs Temperature
100
98
2.00
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
20
10
94
2.05
25
15
96
2.10
UV = OV = VSENSE = VEE
IIN = 2mA
VSS = 2V
92
5
90
–55 –35 –15
0
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G39
4252-1/2 G28
4252-1/2 G26
VOS vs Temperature
(VACL + VOS)/VSS vs Temperature
IGATE (Sourcing) vs Temperature
70
0.058
10.6
0.056
UV/0V = 4V
TIMER = 0V
65 VSENSE = VEE
VGATE = 0V
0.054
60
10.4
VOS (mV)
10.2
10.0
9.8
9.6
0.052
0.050
0.048
0.044
9.2
0.042
5 25 45 65 85 105 125
TEMPERATURE (°C)
45
0.040
–55 –35 –15
400
350
300
IGATE (mA)
IGATE (mA)
10
VGATE vs Temperature
UV/0V = 4V
TIMER = 0V
VSENSE – VEE = 0.3V
VGATE = 1V
200
150
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G11
12.5
12.0
11.5
11.0
50
0
–55 –35 –15
UV/0V = 4V
14.0 TIMER = 0V
VSENSE = VEE
13.5
13.0
250
100
5
14.5
VGATE (V)
UV/0V = 4V
TIMER = 0V
VSENSE – VEE = 0.15V
VGATE = 3V
20
0
–55 –35 –15
4252-1/2 G10
IGATE (FCL, Sinking)
vs Temperature
15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G30
IGATE (ACL, Sinking)
vs Temperature
25
40
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G29
30
55
50
0.046
9.4
9.0
–55 –35 –15
IGATE (µA)
0.060
10.8
(VACL + VOS) / VSS (V/V)
11.0
10.5
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G12
10.0
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G13
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6
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U W
TYPICAL PERFOR A CE CHARACTERISTICS
VGATEH vs Temperature
3.6
3.0
0.5
VGATEL (V)
VGATEH (V)
VGATEH = VIN – VGATE,
IIN = 2mA
(MS ONLY)
2.8
0.3
2.4
0.2
2.2
0.1
5 25 45 65 85 105 125
TEMPERATURE (°C)
2.975
VUVL
2.775
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G15
ISENSE vs (VSENSE – VEE)
–10
0.01
–12
VOVH
–14
6.05
0.1
5.85
5.65
VOVL
5.45
–ISENSE (mA)
–16
ISENSE (µA)
–18
–20
–22
1.0
10
–24
5.25
VOV
–26
5.05
–28
4.85
–55 –35 –15
UV/0V = 4V
TIMER = 0V
GATE = HIGH
VSENSE – VEE = 50mV
–30
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G16
10
6
ITMR (µA)
3.0
2.5
2.0
1.0
TIMER = 2V
45
40
5
4
35
30
25
20
2
0.5
0
–55 –35 –15
50
TIMER = 2V
3
VTMRL
2.0
ITMR (Initial Cycle, Sinking)
vs Temperature
8
7
1.5
4252-1/2 G18
9
VTMRH
3.5
1.5
1000
–1.5 –1.0 –0.5
0
0.5 1.0
(VSENSE – VEE) (V)
ITMR (Initial Cycle, Sourcing)
vs Temperature
5.0
4.0
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G17
TIMER Threshold
vs Temperature
4.5
UV/0V = 4V
TIMER = 0V
GATE = HIGH
TA = 25°C
100
ITMR (mA)
OV THRESHOLD (V)
VUV
3.075
ISENSE vs Temperature
OV Threshold vs Temperature
6.45
TIMER THRESHOLD (V)
3.175
4252-1/2 G14
4252-1/2 G31
6.25
VUVH
2.875
0
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
3.275
0.4
2.6
2.0
–55 –35 –15
3.375
UV THRESHOLD (V)
3.2
UV/0V = 4V
0.7 TIMER = 0V
GATE THRESHOLD
0.6 BEFORE RAMP-UP
3.4
UV Threshold vs Temperature
VGATEL vs Temperature
0.8
15
1
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G19
0
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G20
10
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G21
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7
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U W
TYPICAL PERFOR A CE CHARACTERISTICS
ITMR (Circuit Breaker, Sourcing)
vs Temperature
ITMR (Circuit Breaker, IDRN = 50µA,
Sourcing) vs Temperature
690
280
TIMER = 2V
IDRN = 0µA
670
ITMR (Cooling Cycle, Sinking)
vs Temperature
10
TIMER = 2V
IDRN = 50µA
8
220
650
7
630
6
ITMR (µA)
240
ITMR (µA)
ITMR (µA)
260
610
5
4
3
590
200
2
570
180
–55 –35 –15
1
550
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
0
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G23
IDRN vs VDRAIN
∆ITMRACC/∆IDRN vs Temperature
ITMR vs IDRN
9.0
∆ITMRACC/∆IDRN (µA/µA)
8.8
8.6
100
TIMER ON
(CIRCUIT BREAKING,
IDRN = 50µA)
IIN = 2mA
10
1
8.4
IDRN (mA)
10
1
8.2
8.0
7.8
0.1
TA = 125°C
0.01
TA = 85°C
7.6
0.001
7.4
0.0001
TA = 25°C
7.2
0.1
0.001
0.01
0.1
IDRN (mA)
1
7.0
–55 –35 –15
10
0.00001
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G33
VDRNL vs Temperature
FOR PWRGD STATUS (MS ONLY)
IDRN = 50µA
VPGL (V)
VDRNCL (V)
VDRNL (V)
2.0
7.2
7.0
6.8
0.5
6.2
4252-1/2 G35
6.0
–55 –35 –15
14
16
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G36
IPG = 10mA
1.5
1.0
6.6
5 25 45 65 85 105 125
TEMPERATURE (°C)
12
(MS ONLY)
6.4
2.20
–55 –35 –15
8
10
VDRAIN (V)
2.5
7.4
2.25
6
VPGL vs Temperature
7.6
2.50
2.30
4
3.0
7.8
2.55
2.35
2
4252-1/2 G25
VDRNCL vs Temperature
8.0
2.40
0
TA = –40°C
4252-1/2 G34
2.60
2.45
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G32
4252-1/2 G22
ITMR (mA)
TIMER = 2V
9
0
–55 –35 –15
IPG = 5mA
IPG = 1.6mA
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G37
425212fb
8
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U W
TYPICAL PERFOR A CE CHARACTERISTICS
210
60
200
59
190
tSS (µs)
IPGH (µA)
220
VPWRGD = 0V
(MS ONLY)
58
170
56
160
5 25 45 65 85 105 125
TEMPERATURE °(C)
4252-1/2 G38
0.7
0.6
180
57
55
–55 –35 –15
0.8
SS PIN FLOATING,
VSS RAMPS FROM 0.2V TO 2V
DELAY (µs)
62
61
tPLLUG and tPHLOG
vs Temperature
tSS vs Temperature
IPGH vs Temperature
150
–55 –35 –15
0.4
0.3
tPLLUG
tPHLOG
0.2
0.1
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G27
U
U
U
PI FU CTIO S
0.5
0
–55 –35 –15
5 25 45 65 85 105 125
TEMPERATURE (°C)
4252-1/2 G24
(MS/MS8)
VIN (Pin 1/Pin 1): Positive Supply Input. Connect this pin
to the positive side of the supply through a dropping
resistor. A shunt regulator clamps VIN at 13V. An internal
undervoltage lockout (UVLO) circuit holds GATE low until
the VIN pin is greater than VLKO, overriding UV and OV. If
UV is high, OV is low and VIN comes out of UVLO, TIMER
starts an initial timing cycle before initiating a GATE rampup. If VIN drops below approximately 8.2V, GATE pulls low
immediately.
PWRGD (Pin 2/Not Available): Power Good Status Output (MS only). At start-up, PWRGD latches low if DRAIN
is below 2.385V and GATE is within 2.8V of VIN. PWRGD
status is reset by UV, VIN (UVLO) or a circuit breaker fault
timeout. This pin is internally pulled high by a 58µA current
source.
SS (Pin 3/Pin 2): Soft-Start Pin. This pin is used to ramp
inrush current during start up, thereby effecting control
over di/dt. A 20x attenuated version of the SS pin voltage
is presented to the current limit amplifier. This attenuated
voltage limits the MOSFET’s drain current through the
sense resistor during the soft-start current limiting. At the
beginning of a start-up cycle, the SS capacitor (CSS) is
ramped by a 22µA (28µA for the LTC4252A) current
source. The GATE pin is held low until SS exceeds 20 • VOS
= 0.2V. SS is internally shunted by a 100k resistor (RSS)
which limits the SS pin voltage to 2.2V(50k resistor and
1.4V for the LTC4252A). This corresponds to an analog
current limit SENSE voltage of 100mV (60mV for the
LTC4252A). If the SS capacitor is omitted, the SS pin
ramps up in about 180µs. The SS pin is pulled low under
any of the following conditions: in UVLO, in an undervoltage condition, in an overvoltage condition, during the
initial timing cycle or when the circuit breaker fault times
out.
SENSE (Pin 4/Pin 3): Circuit Breaker/Current Limit Sense
Pin. Load current is monitored by a sense resistor RS
connected between SENSE and VEE, and controlled in
three steps. If SENSE exceeds VCB (50mV), the circuit
breaker comparator activates a (230µA + 8 • IDRN) TIMER
pull-up current. If SENSE exceeds VACL, the analog current
limit amplifier pulls GATE down to regulate the MOSFET
current at VACL/RS. In the event of a catastrophic shortcircuit, SENSE may overshoot. If SENSE reaches VFCL
(200mV), the fast current limit comparator pulls GATE low
with a strong pull-down. To disable the circuit breaker and
current limit functions, connect SENSE to VEE.
425212fb
9
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
U
U
PI FU CTIO S
(MS/MS8)
VEE (Pin 5/Pin 4): Negative Supply Voltage Input. Connect
this pin to the negative side of the power supply.
GATE (Pin 6/Pin 5): N-Channel MOSFET Gate Drive Output. This pin is pulled high by a 58µA current source. GATE
is pulled low by invalid conditions at VIN (UVLO), UV, OV,
or a circuit breaker fault timeout. GATE is actively servoed
to control the fault current as measured at SENSE. A
compensation capacitor at GATE stabilizes this loop. A
comparator monitors GATE to ensure that it is low before
allowing an initial timing cycle, GATE ramp-up after an
overvoltage event or restart after a current limit fault.
During GATE start-up, a second comparator detects if
GATE is within 2.8V of VIN before PWRGD is set (MS
package only).
DRAIN (Pin 7/Pin 6): Drain Sense Input. Connecting an
external resistor, RD, between this pin and the MOSFET’s
drain (VOUT) allows voltage sensing below 6.15V (5V for
LTC4252A) and current feedback to TIMER. A comparator
detects if DRAIN is below 2.385V and together with the
GATE high comparator sets the PWRGD flag. If VOUT is
above VDRNCL, DRAIN clamps at approximately VDRNCL.
The current through RD is internally multiplied by 8 and
added to TIMER’s 230µA pullup current during a circuit
breaker fault cycle. This reduces the fault time and MOSFET
heating.
OV (Pin 8/Pin7): Overvoltage Input. The active high threshold at the OV pin is set at 6.15V with 0.6V hysteresis. If OV
> 6.15V, GATE pulls low. When OV returns below 5.55V,
GATE start-up begins without an initial timing cycle. The
LTC4252A OV pin is set at 5.09V with 102mV hysteresis.
If OV > 5.09V, GATE pulls low. When OV returns below
4.988V, GATE start-up begins without an initial timing
cycle. If an overvoltage condition occurs in the middle of
an initial timing cycle, the initial timing cycle is restarted
after the overvoltage condition goes away. An overvoltage
condition does not reset the PWRGD flag. The internal
UVLO at VIN always overrides OV. A 1nF to 10nF capacitor
at OV prevents transients and switching noise from affecting the OV thresholds and prevents glitches at the GATE
pin.
UV (Pin 9/Pin 7): Undervoltage Input. The active low
threshold at the UV pin is set at 2.925V with 0.3V hysteresis. If UV < 2.925V, PWRGD pulls high, both GATE and
TIMER pull low. If UV rises above 3.225V, this initiates an
initial timing cycle followed by GATE start-up. The
LTC4252A UV pin is set at 3.08V with 324mV hysteresis.
If UV < 2.756V, PWRGD pulls high, both GATE and TIMER
pull low. If UV rises above 3.08V, this initiates an initial
timing cycle followed by GATE start-up. The internal UVLO
at VIN always overrides UV. A low at UV resets an internal
fault latch. A 1nF to 10nF capacitor at UV prevents transients and switching noise from affecting the UV thresholds and prevents glitches at the GATE pin.
TIMER (Pin 10/Pin 8): Timer Input. TIMER is used to
generate an initial timing delay at start-up and to delay
shutdown in the event of an output overload (circuit
breaker fault). TIMER starts an initial timing cycle when
the following conditions are met: UV is high, OV is low, VIN
clears UVLO, TIMER pin is low, GATE is lower than VGATEL,
SS < 0.2V, and VSENSE – VEE < VCB. A pull-up current of
5.8µA then charges CT, generating a time delay. If CT
charges to VTMRH (4V), the timing cycle terminates, TIMER
quickly pulls low and GATE is activated.
If SENSE exceeds 50mV while GATE is high, a circuit
breaker cycle begins with a 230µA pull-up current charging CT. If DRAIN is approximately 7V (6V for LTC4252A)
during this cycle, the timer pull-up has an additional
current of 8 • IDRN. If SENSE drops below 50mV before
TIMER reaches 4V, a 5.8µA pull-down current slowly
discharges the CT. In the event that CT eventually integrates up to the VTMRH threshold, the circuit breaker trips,
GATE quickly pulls low and PWRGD pulls high. The
LTC4252-1 TIMER pin latches high with a 5.8µA pull-up
source. This latched fault is cleared by either pulling
TIMER low with an external device or by pulling UV below
VUVLO. The LTC4252-2 starts a shutdown cooling cycle
following an overcurrent fault. This cycle consists of 4
discharging ramps and 3 charging ramps. The charging
and discharging currents are 5.8µA and TIMER ramps
between its 1V and 4V thresholds. At the completion of a
shutdown cooling cycle, the LTC4252-2 attempts a startup cycle.
425212fb
10
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
W
BLOCK DIAGRA
VIN
–
DRAIN
VIN
+
2.385V
8×
VEE
6.15V
(5V)
1×
1×
1×
VIN
58µA
VEE
PWRGD **
VIN
6.15V
(5.09V)
–
58µA
VEE
GATE
+
OV *
2.8V
–
VEE
– (+)
UV *
–+
VIN
+
2.925V
(3.08V)
+ (–)
LOGIC
230µA VIN
–
+
4V
5.8µA
–
VIN
+
0.5V
TIMER
+
–
VIN
1V
200mV
–
VEE 5.8µA
FCL
+
+–
VEE
VEE
22µA
(28µA)
+
SS
VOS = 10mV
95k
(47.5k)
5k
(2.5k)
VEE
ACL
–
VEE
+
RSS
–+
CB
VEE
SENSE
50mV
+–
VEE
–
4252-1/2 BD
VEE
*OV AND UV ARE TIED TOGETHER ON THE MS8 PACKAGE. OV AND UV ARE SEPARATE PINS ON THE MS PACKAGE
** ONLY AVAILABLE IN THE MS PACKAGE
FOR COMPONENTS, CURRENT AND VOLTAGE WITH TWO VALUES, VALUES IN PARENTHESES REFER
TO THE LTC4252A. VALUES WITHOUT PARENTHESES REFER TO THE LTC4252
425212fb
11
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
OPERATIO
Hot Circuit Insertion
Interlock Conditions
When circuit boards are inserted into a live backplane, the
supply bypass capacitors can draw huge transient currents from the power bus as they charge. The flow of
current damages the connector pins and glitches the
power bus, causing other boards in the system to reset.
The LTC4252 is designed to turn on a circuit board supply
in a controlled manner, allowing insertion or removal
without glitches or connector damage.
A start-up sequence commences once these “interlock”
conditions are met.
The LTC4252 resides on a removable circuit board and
controls the path between the connector and load or
power conversion circuitry with an external MOSFET switch
(see Figure 1). Both inrush control and short-circuit protection are provided by the MOSFET.
A detailed schematic for the LTC4252A is shown in Figure 2. – 48V and – 48RTN receive power through the
longest connector pins and are the first to connect when
the board is inserted. The GATE pin holds the MOSFET off
during this time. UV and OV determine whether or not the
MOSFET should be turned on based upon internal high
accuracy thresholds and an external divider. UV and OV do
double duty by also monitoring whether or not the connector is seated. The top of the divider detects – 48RTN by way
of a short connector pin that is the last to mate during the
insertion sequence.
4. The (SENSE – VEE) voltage is < 50mV (VCB).
6. The voltage on the TIMER capacitor (CT) is < 1V (VTMRL).
7. The voltage at GATE is < 0.5V (VGATEL).
The first three conditions are continuously monitored and
the latter four are checked prior to initial timing or GATE
ramp-up. Upon exiting an OV condition, the TIMER pin
voltage requirement is inhibited. Details are described in
the Applications Information, Timing Waveforms section.
TIMER begins the start-up sequence by sourcing 5.8µA
into CT. If VIN, UV or OV falls out of range, the start-up cycle
stops and TIMER discharges CT to less than 1V, then waits
until the aforementioned conditions are once again met. If
CT successfully charges to 4V, TIMER pulls low and both
SS and GATE pins are released. GATE sources 58µA
(IGATE), charging the MOSFET gate and associated capacitance. The SS voltage ramp limits VSENSE to control the
inrush current. PWRGD pulls active low when GATE is
within 2.8V of VIN and DRAIN is lower than VDRNL.
–48RTN
+
LTC4252
+
CLOAD
RIN
3 × 1.8k IN SERIES
1/4W EACH
+
ISOLATED
DC/DC
CONVERTER
MODULE
–
–48V
3. The voltage at OV < VOVLO.
LONG
PLUG-IN BOARD
–48RTN
LONG
2. The voltage at UV > VUVHI.
5. The voltage at SS is < 0.2V (20 • VOS).
Initial Start-Up
LONG
1. The input voltage VIN exceeds VLKO (UVLO).
LOW
VOLTAGE
CIRCUITRY
SHORT
–
R1
390k
1%
BACKPLANE
CIN
1µF
LTC4252A-1
TIMER
SS
VEE
Figure 1. Basic LTC4252 Hot Swap Topology
R2
30.1k
1%
+
VIN
OV
UV
C1
10nF
4252-1/2 F01
CLOAD
100µF
DRAIN
SENSE
GATE
CSS
68nF
CT
0.68µF
CC
10nF
RC
10Ω
RD
1M
LONG
–48V
RS
0.02Ω
Q1
IRF530S
4252-1/2 F02
Figure 2. –48V, 2.5A Hot Swap Controller
425212fb
12
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
OPERATIO
Two modes of operation are possible during the time the
MOSFET is first turning on, depending on the values of
external components, MOSFET characteristics and nominal design current. One possibility is that the MOSFET will
turn on gradually so that the inrush into the load capacitance remains a low value. The output will simply ramp to
–48V and the LTC4252 will fully enhance the MOSFET. A
second possibility is that the load current exceeds the softstart current limit threshold of [VSS(t)/20 – VOS]/RS. In this
case the LTC4252 will ramp the output by sourcing softstart limited current into the load capacitance. If the softstart voltage is below 1.2V, the circuit breaker TIMER is
held low. Above 1.2V, TIMER ramps up. It is important to
set the timer delay so that, regardless of which start-up
mode is used, the TIMER ramp is less than one circuit
breaker delay time. If this condition is not met, the
LTC4252-1 may shut down after one circuit breaker delay
time whereas the LTC4252-2 may continue to autoretry.
Board Removal
If the board is withdrawn from the card cage, the UV and
OV divider is the first to lose connection. This shuts off the
MOSFET and commutates the flow of current in the
connector. When the power pins subsequently separate,
there is no arcing.
Current Control
Three levels of protection handle short-circuit and overload conditions. Load current is monitored by SENSE and
resistor RS. There are three distinct thresholds at SENSE:
50mV for a timed circuit breaker function; 100mV for an
analog current limit loop (60mV for the LTC4252A); and
200mV for a fast, feedforward comparator which limits
peak current in the event of a catastrophic short-circuit.
If, owing to an output overload, the voltage drop across RS
exceeds 50mV, TIMER sources 230µA into CT. CT eventually charges to a 4V threshold and the LTC4252 shuts off.
If the overload goes away before CT reaches 4V and SENSE
measures less than 50mV, CT slowly discharges (5.8µA).
In this way the LTC4252’s circuit breaker function responds to low duty cycle overloads and accounts for fast
heating and slow cooling characteristics of the MOSFET.
Higher overloads are handled by an analog current limit
loop. If the drop across RS reaches VACL, the current
limiting loop servos the MOSFET gate and maintains a
constant output current of VACL/RS. In current limit
mode, VOUT typically rises and this increases MOSFET
heating. If VOUT > VDRNCL, connecting an external resistor, RD, between VOUT and DRAIN allows the fault timing
cycle to be shortened by accelerating the charging of the
TIMER capacitor. The TIMER pull-up current is increased
by 8 • IDRN. Note that because SENSE > 50mV, TIMER
charges CT during this time and the LTC4252 will eventually shut down.
Low impedance failures on the load side of the LTC4252
coupled with 48V or more driving potential can produce
current slew rates well in excess of 50A/µs. Under these
conditions, overshoot is inevitable. A fast SENSE comparator with a threshold of 200mV detects overshoot and
pulls GATE low much harder and hence much faster than
the weaker current limit loop. The VACL/RS current limit
loop then takes over and servos the current as previously
described. As before, TIMER runs and shuts down the
LTC4252 when CT reaches 4V.
If CT reaches 4V, the LTC4252-1 latches off with a 5.8µA
pull-up current source whereas the LTC4252-2 starts a
shutdown cooling cycle. The LTC4252-1 circuit breaker
latch is reset by either pulling UV momentarily low or dropping the input voltage VIN below the internal UVLO threshold or pulling TIMER momentarily low with a switch. The
LTC4252-2 retries after its shutdown cooling cycle.
Although short-circuits are the most obvious fault type,
several operating conditions may invoke overcurrent
protection. Noise spikes from the backplane or load, input
steps caused by the connection of a second, higher
voltage supply, transient currents caused by faults on
adjacent circuit boards sharing the same power bus or the
insertion of non-hot-swappable products could cause
higher than anticipated input current and temporary detection of an overcurrent condition. The action of TIMER
and CT rejects these events allowing the LTC4252 to “ride
out” temporary overloads and disturbances that could
trip a simple current comparator and, in some cases, blow
a fuse.
425212fb
13
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
U
W
U
APPLICATIO S I FOR ATIO
SHUNT REGULATOR
UV/OV COMPARATORS (LTC4252)
A fast responding regulator shunts the LTC4252 VIN pin.
Power is derived from – 48RTN by an external current
limiting resistor. The shunt regulator clamps VIN to 13V
(VZ). A 1µF decoupling capacitor at VIN filters supply
transients and contributes a short delay at start-up. RIN
should be chosen to accommodate both VIN supply current and the drive required for an optocoupler if the
PWRGD function on the 10-pin MS package is used.
Higher current through RIN results in higher dissipation
for RIN and the LTC4252. An alternative is a separate NPN
buffer driving the optocoupler as shown in Figure 3.
Multiple 1/4W resistors can replace a single higher power
RIN resistor.
An UV hysteretic comparator detects undervoltage conditions at the UV pin, with the following thresholds:
UV low-to-high (VUVHI) = 3.225V
UV high-to-low (VUVLO) = 2.925V
An OV hysteretic comparator detects overvoltage conditions at the OV pin, with the following thresholds:
OV low-to-high (VOVHI) = 6.150V
OV high-to-low (VOVLO) = 5.550V
The UV and OV trip point ratio is designed to match the
standard telecom operating range of 43V to 82V when
connected together as in the typical application. A divider
(R1, R2) is used to scale the supply voltage. Using R1 =
402k and R2 = 32.4k gives a typical operating range of
43.2V to 82.5V. The undervoltage shutdown and overvoltage recovery thresholds are then 39.2V and 74.4V. 1%
divider resistors are recommended to preserve threshold
accuracy.
INTERNAL UNDERVOLTAGE LOCKOUT (UVLO)
A hysteretic comparator, UVLO, monitors VIN for
undervoltage. The thresholds are defined by VLKO and its
hysteresis, VLKH. When VIN rises above VLKO the chip is
enabled; below (VLKO – VLKH) it is disabled and GATE is
pulled low. The UVLO function at VIN should not be
confused with the UV/OV pin(s). These are completely
separate functions.
The R1-R2 divider values shown in the Typical Application
set a standing current of slightly more than 100µA and
define an impedance at UV/OV of 30kΩ. In most applica-
GND
RIN
10k
1/2W
CL
100µF
R4
22k
+
Q2
GND
(SHORT PIN)
CIN
1µF
1
VIN
R1
432k
1%
R3
38.3k
1%
EN
LTC4252-1
9
R2
4.75k
1%
8
10
CT
330nF
C2
10nF
3
UV
PWRGD
OV
DRAIN
TIMER
SS
CSS
68nF
GATE
VEE
5
LOAD
R5
2.2k
SENSE
*
2
7
RD 1M
6
Q1
IRF530S
4
RC
10Ω
CC
18nF
RS
0.02Ω
4252-1/2 F03
–48V
* M0C207
Q2: MMBT5551LT1
Figure 3. – 48V/2.5A Application with Different Input Operating Range
425212fb
14
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
U
W
U
APPLICATIO S I FOR ATIO
tions, 30kΩ impedance coupled with 300mV UV hysteresis makes the LTC4252 insensitive to noise. If more noise
immunity is desired, add a 1nF to 10nF filter capacitor from
UV/OV to VEE.
gives a typical operating range of 43V to 71V. The undervoltage shutdown and overvoltage recovery thresholds are
then 38.5V and 69.6V respectively. 1% divider resistors are
recommended to preserve threshold accuracy.
Separate UV and OV pins are available in the 10-pin MS
package and can be used for a different operating range
such as 35.5V to 76V as shown in Figure 3. Other combinations are possible with different resistor arrangements.
The R1-R2 divider values shown in Figure 2 set a standing
current of slightly more than 100µA and define an impedance at UV/OV of 28kΩ. In most applications, 28kΩ
impedance coupled with 324mV UV hysteresis makes the
LTC4252A insensitive to noise. If more noise immunity is
desired, add a 1nF to 10nF filter capacitor from UV/OV to
VEE.
UV/OV COMPARATORS (LTC4252A)
A UV hysteretic comparator detects undervoltage conditions at the UV pin, with the following thresholds:
UV low-to-high (VUV) = 3.08V
UV high-to-low (VUV – VUVHST) = 2.756V
An OV hysteretic comparator detects overvoltage conditions at the OV pin, with the following thresholds:
OV low-to-high (VOV) = 5.09V
OV high-to-low (VOV – VOVHST) = 4.988V
The UV and OV trip point ratio is designed to match the
standard telecom operating range of 43V to 71V when
connected together as in Figure 2. A divider (R1, R2) is used
to scale the supply voltage. Using R1 = 390k and R2 = 30.1k
The UV and OV pins can be used for a wider operating
range such as 35.5V to 76V as shown in Figure 4. Other
combinations are possible with different resistor
arrangements.
UV/OV OPERATION
A low input to the UV comparator will reset the chip and
pull the GATE and TIMER pins low. A low-to-high UV
transition will initiate an initial timing sequence if the other
interlock conditions are met. A high-to-low transition in
the UV comparator immediately shuts down the LTC4252,
pulls the MOSFET gate low and resets the latched PWRGD
high.
GND
RIN
10k
1/2W
R4
22k
1
CIN
1µF
CL
100µF
+
Q2
GND
(SHORT PIN)
VIN
R1
464k
1%
R3
34k
1%
EN
LTC4252A-1
9
R2
10k
1%
8
10
CT
0.68µF
C2
10nF
3
UV
PWRGD
OV
DRAIN
TIMER
SS
CSS
68nF
GATE
VEE
5
LOAD
R5
2.2k
SENSE
*
2
7
RD 1M
6
Q1
IRF530S
4
RC
10Ω
CC
10nF
RS
0.02Ω
4252-1/2 F04
–48V
* M0C207
Q2: MMBT5551LT1
Figure 4. – 48V/2.5A Application with Wider Input Operating Range
425212fb
15
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
W
U
U
APPLICATIO S I FOR ATIO
Overvoltage conditions detected by the OV comparator
will also pull GATE low, thereby shutting down the load.
However, it will not reset the circuit breaker TIMER,
PWRGD flag or shutdown cooling timer. Returning the
supply voltage to an acceptable range restarts the GATE
pin if all the interlock conditions except TIMER are met.
Only during the initial timing cycle does an OV condition
reset the TIMER.
4) Low impedance switch; resets the TIMER capacitor
after an initial timing delay, in UVLO, in UV and in OV
during initial timing.
For initial start-up, the 5.8µA pull-up is used. The low
impedance switch is turned off and the 5.8µA current
source is enabled when the interlock conditions are met.
CT charges to 4V in a time period given by:
t=
DRAIN
4V • C T
5.8µA
(2)
Connecting an external resistor, RD, to the dual function
DRAIN pin allows VOUT sensing* without it being damaged
by large voltage transients. Below 5V, negligible pin leakage allows a DRAIN low comparator to detect VOUT less
than 2.385V (VDRNL). This condition, together with the
GATE low comparator, sets the PWRGD flag.
When CT reaches 4V (VTMRH), the low impedance switch
turns on and discharges CT. A GATE start-up cycle begins
and both SS and GATE are released.
If VOUT > VDRNCL, the DRAIN pin is clamped at about
VDRNCL and the current flowing in RD is given by:
If the SENSE pin detects more than a 50mV drop across
RS, the TIMER pin charges CT with (230µA + 8 • IDRN). If
CT charges to 4V, the GATE pin pulls low and the LTC4252-1
latches off while the LTC4252-2 starts a shutdown cooling
cycle. The LTC4252-1 remains latched off until the UV pin
is momentarily pulsed low or TIMER is momentarily
discharged low by an external switch or VIN dips below
UVLO and is then restored. The circuit breaker timeout
period is given by:
IDRN ≈
VOUT − VDRNCL
RD
(1)
This current is scaled up 8 times during a circuit breaker
fault and is added to the nominal 230µA TIMER current.
This accelerates the fault TIMER pull-up when the MOSFET’s
drain-source voltage exceeds VDRNCL and effectively shortens the MOSFET heating duration.
TIMER
The operation of the TIMER pin is somewhat complex as
it handles several key functions. A capacitor CT is used at
TIMER to provide timing for the LTC4252. Four different
charging and discharging modes are available at TIMER:
1) A 5.8µA slow charge; initial timing and shutdown
cooling delay.
2) A (230µA + 8 • IDRN) fast charge; circuit breaker delay.
3) A 5.8µA slow discharge; circuit breaker "cool off" and
shutdown cooling.
CIRCUIT BREAKER TIMER OPERATION
t=
4V • C T
230µA + 8 • IDRN
(3)
If VOUT < 5V, an internal PMOS device isolates any DRAIN
pin leakage current, making IDRN = 0µA in Equation (3). If
VOUT > VDRNCLduring the circuit breaker fault period, the
charging of CT accelerates by 8 • IDRN of Equation (1).
Intermittent overloads may exceed the 50mV threshold at
SENSE, but, if their duration is sufficiently short, TIMER
will not reach 4V and the LTC4252 will not shut the external
MOSFET off. To handle this situation, the TIMER discharges CT slowly with a 5.8µA pull-down whenever the
SENSE voltage is less than 50mV. Therefore, any intermittent overload with VOUT > 5V and an aggregate duty cycle
*VOUT as viewed by the MOSFET; i.e., VDS.
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LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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APPLICATIO S I FOR ATIO
SOFT-START
10
NORMALIZED RESPONSE TIME (s/µF)
IDRN = 0µA
Soft-start limits the inrush current profile during GATE
start-up. Unduly long soft-start intervals can exceed the
MOSFET’s SOA rating if powering up into an active load. If
SS floats, an internal current source ramps SS from 0V to
2.2V for the LTC4252 or 0V to 1.4V for the LTC4252A in
about 230µs. Connecting an external capacitor CSS from
SS to ground modifies the ramp to approximate an RC
response of:
1
t
4
=
CT(µF)
[(235.8 + 8 • IDRN) • D – 5.8]
0.1
0.01
0
20
40
60
80
FAULT DUTY CYCLE (%)
100
⎞⎞
⎛
t
⎛
⎜ − R •C ⎟
VSS( t) ≈ VSS • ⎜ 1− e⎝ SS SS ⎠ ⎟
⎜
⎟
⎝
⎠
4252-1/2 F05
Figure 5. Circuit-Breaker Response Time
of 2.5% or more will eventually trip the circuit breaker and
shut down the LTC4252. Figure 5 shows the circuit breaker
response time in seconds normalized to 1µF for IDRN =
0µA. The asymmetric charging and discharging of CT is a
fair gauge of MOSFET heating.
The normalized circuit response time is estimated by
t
4
=
C T (µF ) (235.8 + 8 • IDRN ) • D − 5.8
[
]
(4)
SHUTDOWN COOLING CYCLE
For the LTC4252-1 (latchoff version), TIMER latches high
with a 5.8µA pull-up after the circuit breaker fault TIMER
reaches 4V. For the LTC4252-2 (automatic retry version),
a shutdown cooling cycle begins if TIMER reaches the 4V
threshold. TIMER starts with a 5.8µA pull-down until it
reaches the 1V threshold. Then, the 5.8µA pull-up turns
back on until TIMER reaches the 4V threshold. Four 5.8µA
pull-down cycles and three 5.8µA pull-up cycles occur
between the 1V and 4V thresholds, creating a time interval
given by:
tSHUTDOWN =
7 • 3V • C T
5.8µA
(5)
At the 1V threshold of the last pull-down cycle, a GATE
ramp-up is attempted.
(6)
An internal resistive divider (95k/5k for the LTC4252 or
47.5k/2.5k for the LTC4252A) scales VSS(t) down by 20
times to give the analog current limit threshold:
VACL (t) =
VSS (t)
− VOS
20
(7)
This allows the inrush current to be limited to VACL(t)/RS.
The offset voltage, VOS (10mV), ensures CSS is sufficiently
discharged and the ACL amplifier is in current limit before
GATE start-up. SS is pulled low under any of the following
conditions: in UVLO, in an undervoltage condition, in an
overvoltage condition, during the initial timing cycle or
when the circuit breaker fault times out.
GATE
GATE is pulled low to VEE under any of the following
conditions: in UVLO, in an undervoltage condition, in an
overvoltage condition, during the initial timing cycle or
when the circuit breaker fault times out. When GATE turns
on, a 58µA current source charges the MOSFET gate and
any associated external capacitance. VIN limits the gate
drive to no more than 14.5V.
Gate-drain capacitance (CGD) feedthrough at the first
abrupt application of power can cause a gate-source
voltage sufficient to turn on the MOSFET. A unique circuit
pulls GATE low with practically no usable voltage at VIN
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LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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and eliminates current spikes at insertion. A large external
gate-source capacitor is thus unnecessary for the purpose
of compensating CGD. Instead, a smaller value (≥ 10nF)
capacitor CC is adequate. CC also provides compensation
for the analog current limit loop.
GATE has two comparators: the GATE low comparator
looks for < 0.5V threshold prior to initial timing or a GATE
start-up cycle; the GATE high comparator looks for < 2.8V
relative to VIN and, together with the DRAIN low comparator, sets PWRGD status during GATE startup.
SENSE
The SENSE pin is monitored by the circuit breaker (CB)
comparator, the analog current limit (ACL) amplifier and
the fast current limit (FCL) comparator. Each of these three
measures the potential of SENSE relative to VEE. When
SENSE exceeds 50mV, the CB comparator activates the
230µA TIMER pull-up. At 100mV (60mV for the LTC4252A),
the ACL amplifier servos the MOSFET current and, at
200mV, the FCL comparator abruptly pulls GATE low in an
attempt to bring the MOSFET current under control. If any
of these conditions persists long enough for TIMER to
charge CT to 4V (see Equation 3), the LTC4252 shuts
down and pulls GATE low.
If the SENSE pin encounters a voltage greater than VACL,
the ACL amplifier will servo GATE downwards in an
attempt to control the MOSFET current. Since GATE overdrives the MOSFET in normal operation, the ACL amplifier
needs time to discharge GATE to the threshold of the
MOSFET. For a mild overload the ACL amplifier can control
the MOSFET current, but in the event of a severe overload
the current may overshoot. At SENSE = 200mV the FCL
comparator takes over, quickly discharging the GATE pin
to near VEE potential. FCL then releases and the ACL
amplifier takes over. All the while TIMER is running. The
effect of FCL is to add a nonlinear response to the control
loop in favor of reducing MOSFET current.
Owing to inductive effects in the system, FCL typically
overcorrects the current limit loop and GATE undershoots. A zero in the loop (resistor RC in series with the
gate capacitor) helps the ACL amplifier to recover.
SHORT-CIRCUIT OPERATION
Circuit behavior arising from a load side low impedance
short is shown in Figure 6 for the LTC4252. Initially, the
current overshoots the fast current limit level of VSENSE =
200mV (Trace 2) as the GATE pin works to bring VGS under
control (Trace 3). The overshoot glitches the backplane in
the negative direction and when the current is reduced to
100mV/RS, the backplane responds by glitching in the
positive direction.
TIMER commences charging CT (Trace 4) while the analog
current limit loop maintains the fault current at 100mV/RS,
which in this case is 5A (Trace 2). Note that the backplane
voltage (Trace 1) sags under load. Timer pull-up is accelerated by VOUT. When CT reaches 4V, GATE turns off,
PWRGD pulls high, the load current drops to zero and the
backplane rings up to over 100V. The transient associated
with the GATE turn off can be controlled with a snubber to
reduce ringing and a transient voltage suppressor (such
as Diodes Inc. SMAT70A) to clip off large spikes. The choice
of RC for the snubber is usually done experimentally. The
value of the snubber capacitor is usually chosen between
10 to 100 times the MOSFET COSS. The value of the snubber resistor is typically between 3Ω to 100Ω.
SUPPLY RING OWING TO
CURRENT OVERSHOOT
SUPPLY RING OWING TO
MOSFET TURN OFF
–48RTN
50V/DIV
ONSET OF OUTPUT SHORT-CIRCUIT
SENSE
200mV/DIV
GATE
10V/DIV
TIMER
5V/DIV
FAST CURRENT LIMIT
ANALOG CURRENT LIMIT
CTIMER RAMP
0.5ms/DIV
LATCH OFF
4252-1/2 F06
Figure 6. Output Short-Circuit Behavior of LTC4252
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LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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A low impedance short on one card may influence the
behavior of others sharing the same backplane. The initial
glitch and backplane sag as seen in Figure 6 Trace 1, can
rob charge from output capacitors on adjacent cards.
When the faulty card shuts down, current flows in to
refresh the capacitors. If LTC4252s are used by the other
cards, they respond by limiting the inrush current to a
value of 100mV/RS. If CT is sized correctly, the capacitors
will recharge long before CT times out.
POWER GOOD, PWRGD
PWRGD latches low if GATE charges up to within 2.8V of
VIN and DRAIN pulls below VDRNL during start-up. PWRGD
is reset in UVLO, in a UV condition or if CT charges up to
4V. An overvoltage condition has no effect on PWRGD
status. A 58µA current pulls this pin high during reset. Due
to voltage transients between the power module and
PWRGD, optoisolation is recommended. This pin provides sufficent drive for an optocoupler. Figure 19 shows
an alternative NPN configuration with a limiting base
resistor for the PWRGD interface. The module enable
input should have protection from the negative input
current.
To begin a design, first specify the required load current
and Ioad capacitance, IL and CL. The circuit breaker
current trip point (VCB/RS) should be set to accommodate
the maximum load current. Note that maximum input
current to a DC/DC converter is expected at VSUPPLY(MIN).
RS is given by:
RS =
VCB(MIN)
IL(MAX)
where VCB(MIN) = 40mV (45mV for LTC4252A) represents
the guaranteed minimum circuit breaker threshold.
During the initial charging process, the LTC4252 may
operate the MOSFET in current limit, forcing (VACL) between 80mV to 120mV (VACL is 54mV to 66mV for
LTC4252A) across RS. The minimum inrush current is
given by:
IINRUSH(MIN)=
MOSFET selection is a 3-step process by assuming the
absense of a soft-start capacitor. First, RS is calculated and
then the time required to charge the load capacitance is determined. This timing, along with the maximum short-circuit current and maximum input voltage defines an operating point that is checked against the MOSFET’s SOA curve.
80mV
RS
(9)
Maximum short-circuit current limit is calculated using
the maximum VACL. This gives
ISHORTCIRCUIT(MAX)=
MOSFET SELECTION
The external MOSFET switch must have adequate safe
operating area (SOA) to handle short-circuit conditions
until TIMER times out. These considerations take precedence over DC current ratings. A MOSFET with adequate
SOA for a given application can always handle the required
current, but the opposite may not be true. Consult the
manufacturer’s MOSFET data sheet for safe operating area
and effective transient thermal impedance curves.
(8)
120mV
RS
(10)
The TIMER capacitor CT must be selected based on the
slowest expected charging rate; otherwise TIMER might
time out before the load capacitor is fully charged. A value
for CT is calculated based on the maximum time it takes the
load capacitor to charge. That time is given by:
tCL(CHARGE) =
C • V C L• V SUPPLY(MAX)
=
I
IINRUSH(MIN)
(11)
The maximum current flowing in the DRAIN pin is given
by:
IDRN(MAX) =
V SUPPLY(MAX)− V DRNCL
RD
(12)
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LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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Approximating a linear charging rate as IDRN drops from
IDRN(MAX) to zero, the IDRN component in Equation (3) can
be approximated with 0.5 • IDRN(MAX). Rearranging equation, TIMER capacitor CT is given by:
CT =
tCL(CHARGE) • (230µA + 4 • IDRN(MAX) )
4V
(13)
Returning to Equation (3), the TIMER period is calculated
and used in conjunction with V SUPPLY(MAX) and
ISHORTCIRCUIT(MAX) to check the SOA curves of a prospective MOSFET.
As a numerical design example, consider a 30W load,
which requires 1A input current at 36V. If VSUPPLY(MAX) =
72V and CL = 100µF, RD = 1MΩ, Equation (8) gives RS =
40mΩ; Equation (13) gives CT = 441nF. To account for
errors in RS, CT, TIMER current (230µA), TIMER threshold
(4V), RD, DRAIN current multiplier and DRAIN voltage
clamp (VDRNCL), the calculated value should be multiplied
by 1.5, giving the nearest standard value of CT = 680nF.
If a short-circuit occurs, a current of up to 120mV/
40mΩ = 3A will flow in the MOSFET for 5.6ms as dictated
by CT = 680nF in Equation (3). The MOSFET must be
selected based on this criterion. The IRF530S can handle
100V and 3A for 10ms and is safe to use in this application.
Computing the maximum soft-start capacitor value during
soft-start to a load short is complicated by the nonlinear
MOSFET’s SOA characteristics and the RSSCSS response.
An overly conservative but simple approach begins with
the maximum circuit breaker current, given by:
VCB(MAX)
(14)
RS
where VCB(MAX) = 60mV (55mV for the LTC4252A).
I CB(MAX)=
From the SOA curves of a prospective MOSFET, determine
the time allowed, tSOA(MAX). CSS is given by:
tSOA(MAX)
(15)
0.916 • RSS
In the above example, 60mV/40mΩ gives 1.5A. tSOA(MAX)
for the IRF530S is 40ms. From Equation (15), CSS =
437nF. Actual board evaluation showed that CSS = 100nF
C SS =
was appropriate. The ratio (RSS • CSS) to tCL(CHARGE) is a
good gauge as a large ratio may result in the time-out
period expiring. This gauge is determined empirically with
board level evaluation.
SUMMARY OF DESIGN FLOW
To summarize the design flow, consider the application
shown in Figure 2 with the LTC4252A. It was designed for
80W.
Calculate the maximum load current: 80W/43V = 1.86A;
allowing for 83% converter efficiency, IIN(MAX) = 2.2A.
Calculate RS: from Equation (8) RS = 20mΩ.
Calculate ISHORTCIRCUIT(MAX): from Equation (10)
ISHORTCIRCUIT(MAX) =
66mV
= 3.3A
20mΩ
Select a MOSFET that can handle 3.3A at 71V: IRF530S.
Calculate CT: from Equation (13) CT = 322nF. Select
CT = 680nF, which gives the circuit breaker time-out period t = 5.6ms.
Consult MOSFET SOA curves: the IRF530S can handle
3.3A at 100V for 8.2ms, so it is safe to use in this
application.
Calculate CSS: using Equations (14) and (15) select
CSS = 68nF.
FREQUENCY COMPENSATION
The LTC4252A typical frequency compensation network
for the analog current limit loop is a series RC (10Ω) and
CC connected to VEE. Figure 7 depicts the relationship
between the compensation capacitor CC and the MOSFET’s
CISS. The line in Figure 7 is used to select a starting value
for CC based upon the MOSFET’s CISS specification. Optimized values for CC are shown for several popular
MOSFETs. Differences in the optimized value of CC versus
the starting value are small. Nevertheless, compensation
values should be verified by board level short-circuit
testing.
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LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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CURRENT FLOW
FROM LOAD
COMPENSATION CAPACITANCE CC (nF)
60
NTY100N10
CURRENT FLOW
TO –48V BACKPLANE
50
SENSE RESISTOR
TRACK WIDTH W:
0.03" PER AMP
ON 1 OZ COPPER
40
30
IRF3710
IRF540S
20
W
4252-1/2 F08
IRF530S
IRF740
10
0
0
2000
8000
6000
4000
MOSFET CISS (pF)
4252-1/2 F07
TO
SENSE
TO
VEE
Figure 8. Making PCB Connections to the Sense Resistor
Figure 7. Recommended Compensation
Capacitor CC vs MOSFET CISS
As seen in Figure 6 previously, at the onset of a shortcircuit event, the input supply voltage can ring dramatically owing to series inductance. If this voltage avalanches
the MOSFET, current continues to flow through the MOSFET
to the output. The analog current limit loop cannot control
this current flow and therefore the loop undershoots. This
effect cannot be eliminated by frequency compensation. A
zener diode is required to clamp the input supply voltage
and prevent MOSFET avalanche.
SENSE RESISTOR CONSIDERATIONS
For proper circuit breaker operation, Kelvin-sense PCB
connections between the sense resistor and the LTC4252’s
VEE and SENSE pins are strongly recommended. The
drawing in Figure 8 illustrates the correct way of making
connections between the LTC4252 and the sense resistor.
PCB layout should be balanced and symmetrical to minimize wiring errors. In addition, the PCB layout for the
sense resistor should include good thermal management
techniques for optimal sense resistor power dissipation.
TIMING WAVEFORMS
System Power-Up
Figure 9 details the timing waveforms for a typical powerup sequence in the case where a board is already installed
in the backplane and system power is applied abruptly. At
time point 1, the supply ramps up, together with UV/OV,
VOUT and DRAIN. VIN and PWRGD follow at a slower rate
as set by the VIN bypass capacitor. At time point 2, VIN
exceeds VLKO and the internal logic checks for UV > VUVHI,
OV < VOVLO, GATE < VGATEL, SENSE < VCB, SS < 20 • VOS
and TIMER < VTMRL. If all conditions are met, an initial
timing cycle starts and the TIMER capacitor is charged by
a 5.8µA current source pull-up. At time point 3, TIMER
reaches the VTMRH threshold and the initial timing cycle
terminates. The TIMER capacitor is quickly discharged. At
time point 4, the VTMRL threshold is reached and the
conditions of GATE < V GATEL , SENSE < V CB and
SS < 20 • VOS must be satisfied before a GATE ramp-up
cycle begins. SS ramps up as dictated by RSS • CSS (as in
Equation 6); GATE is held low by the analog current limit
(ACL) amplifier until SS crosses 20 • VOS. Upon releasing
GATE, 58µA sources into the external MOSFET gate and
compensation network. When the GATE voltage reaches
the MOSFET’s threshold, current begins flowing into the
load capacitor at time point 5. At time point 6, load current
reaches the SS control level and the analog current limit
loop activates. Between time points 6 and 8, the GATE
voltage is servoed, the SENSE voltage is regulated at
VACL(t) (Equation 7) and soft-start limits the slew rate of
the load current. If the SENSE voltage (VSENSE – VEE)
reaches the VCB threshold at time point 7, the circuit
breaker TIMER activates. The TIMER capacitor, CT, is
charged by a (230µA + 8 • IDRN) current pull-up. As the load
capacitor nears full charge, load current begins to decline.
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LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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VIN CLEARS VLKO, CHECK UV > VUVHI, OV < VOVLO, GATE < VGATEL, SENSE < VCB, SS < 20 • VOS AND TIMER < VTMRL
TIMER CLEARS VTMRL, CHECK GATE < VGATEL, SENSE < VCB AND SS < 20 • VOS
1
2
3 4 56
7
8 9 10 11
GND – VEE OR
(–48RTN) – (–48V)
UV/OV
VIN
VLKO
VTMRH
230µA + 8 • IDRN
5.8µA
TIMER
5.8µA
VTMRL
58µA
GATE
5.8µA
VIN – VGATEH
58µA
VGATEL
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
SS
VACL
SENSE
VCB
VOUT
VDRNCL
DRAIN
VDRNL
PWRGD
INITIAL TIMING
GATE
START-UP
4252-1/2 F09
Figure 9. System Power-Up Timing (All Waveforms are Referenced to VEE)
At time point 8, the load current falls and the SENSE
voltage drops below VACL(t). The analog current limit loop
shuts off and the GATE pin ramps further. At time point 9,
the SENSE voltage drops below VCB, the fault TIMER cycle
ends, followed by a 5.8µA discharge cycle (cool off). The
duration between time points 7 and 9 must be shorter than
one circuit breaker delay to avoid a fault time out during
GATE ramp-up. When GATE ramps past the VGATEH threshold at time point 10, PWRGD pulls low. At time point 11,
GATE reaches its maximum voltage as determined by VIN.
Live Insertion with Short Pin Control of UV/OV
In the example shown in Figure 10, power is delivered
through long connector pins whereas the UV/OV divider
makes contact through a short pin. This ensures the power
connections are firmly established before the LTC4252 is
activated. At time point 1, the power pins make contact and
VIN ramps through VLKO. At time point 2, the UV/OV divider
makes contact and its voltage exceeds VUVHI. In addition,
the internal logic checks for OV < VOVHI, GATE < VGATEL,
SENSE < VCB, SS < 20 • VOS and TIMER < VTMRL. If all
conditions are met, an initial timing cycle starts and the
TIMER capacitor is charged by a 5.8µA current source
pull-up. At time point 3, TIMER reaches the VTMRH threshold and the initial timing cycle terminates. The TIMER
capacitor is quickly discharged. At time point 4, the VTMRL
threshold is reached and the conditions of GATE < VGATEL,
SENSE < VCB and SS < 20 • VOS must be satisfied before
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LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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UV CLEARS VUVHI, CHECK OV < VOVHI, GATE < VGATEL, SENSE < VCB, SS < 20 • VOS AND TIMER < VTMRL
TIMER CLEARS VTMRL, CHECK GATE < VGATEL, SENSE < VCB AND SS < 20 • VOS
1
2
3 4 56
7
8 9 1011
GND – VEE OR
(–48RTN) – (–48V)
UV/OV
VIN
VUVHI
VLKO
VTMRH
5.8µA
TIMER
230µA + 8 • IDRN
5.8µA
VTMRL
58µA
GATE
VIN – VGATEH
58µA
VGATEL
SS
5.8µA
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
VACL
VCB
SENSE
VOUT
VDRNCL
DRAIN
VDRNL
PWRGD
INITIAL TIMING
GATE
START-UP
4252-1/2 F10
Figure 10. Power-Up Timing with a Short Pin (All Waveforms are Referenced to VEE)
a GATE start-up cycle begins. SS ramps up as dictated by
RSS • CSS; GATE is held low by the analog current limit
amplifier until SS crosses 20 • VOS. Upon releasing GATE,
58µA sources into the external MOSFET gate and compensation network. When the GATE voltage reaches the
MOSFET’s threshold, current begins flowing into the load
capacitor at time point 5. At time point 6, load current
reaches the SS control level and the analog current limit
loop activates. Between time points 6 and 8, the GATE
voltage is servoed, the SENSE voltage is regulated at
VACL(t) and soft-start limits the slew rate of the load
current. If the SENSE voltage (VSENSE – VEE) reaches the
VCB threshold at time point 7, the circuit breaker TIMER
activates. The TIMER capacitor, CT, is charged by a (230µA
+ 8 • IDRN) current pull-up. As the load capacitor nears full
charge, load current begins to decline. At point 8, the load
current falls and the SENSE voltage drops below VACL(t).
The analog current limit loop shuts off and the GATE pin
ramps further. At time point 9, the SENSE voltage drops
below VCB and the fault TIMER cycle ends, followed by a
5.8µA discharge cycle (cool off). When GATE ramps past
VGATEH threshold at time point 10, PWRGD pulls low. At
time point 11, GATE reaches its maximum voltage as
determined by VIN.
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LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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Undervoltage Timing
starts. If the system bus voltage overshoots VOVHI as
shown at time point 2, TIMER discharges. At time point 3,
the supply voltage recovers and drops below the VOVLO
threshold. The initial timing cycle restarts, followed by a
GATE start-up cycle.
In Figure 11 when UV pin drops below VUVLO (time point 1),
the LTC4252 shuts down with TIMER, SS and GATE all
pulling low. If current has been flowing, the SENSE pin
voltage decreases to zero as GATE collapses. When UV
recovers and clears VUVHI (time point 2), an initial timer
cycle begins followed by a GATE start-up cycle.
Overvoltage Timing
During normal operation, if the OV pin exceeds VOVHI as
shown at time point 1 of Figure 13, the TIMER and PWRGD
status are unaffected. Nevertheless, SS and GATE pull
down and the load is disconnected. At time point 2, OV
recovers and drops below the VOVLO threshold. A GATE
start-up cycle begins. If the overvoltage glitch is long
enough to deplete the load capacitor, a full start-up cycle
as shown between time points 4 through 7 may occur.
VIN Undervoltage Lockout Timing
The VIN undervoltage lockout comparator, UVLO, has a
similar timing behavior as the UV pin timing except it looks
for VIN < (VLKO – VLKH) to shut down and VIN > VLKO to
start. In an undervoltage lockout condition, both UV and
OV comparators are held off. When VIN exits undervoltage
lockout, the UV and OV comparators are enabled.
Circuit Breaker Timing
Undervoltage Timing with Overvoltage Glitch
In Figure 14a, the TIMER capacitor charges at 230µA if the
SENSE pin exceeds VCB but VDRN is less than 5V. If the
SENSE pin drops below VCB before TIMER reaches the
In Figure 12, both UV and OV pins are connected together.
When UV clears VUVHI (time point 1), an initial timing cycle
UV DROPS BELOW VUVLO. GATE, SS AND TIMER ARE PULLED DOWN, PWRGD RELEASES
UV CLEARS VUVHI, CHECK OV CONDITION, GATE < VGATEL, SENSE < VCB, SS < 20 • VOS AND TIMER < VTMRL
TIMER CLEARS VTMRL, CHECK GATE < VGATEL, SENSE < VCB AND SS < 20 • VOS
1
UV
2
3 4 56
7
8 9 10 11
VUVHI
VUVLO
VTMRH
5.8µA
TIMER
230µA + 8 • IDRN
5.8µA
VTMRL
5.8µA
58µA
GATE
SS
VIN – VGATEH
58µA
VGATEL
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
VACL
SENSE
VCB
VDRNCL
DRAIN
VDRNL
PWRGD
INITIAL TIMING
GATE
START-UP
4252-1/2 F11
Figure 11. Undervoltage Timing (All Waveforms are Referenced to VEE)
425212fb
24
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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UV/OV CLEARS VUVHI, CHECK OV CONDITION, GATE < VGATEL, SENSE < VCB, SS < 20 • VOS AND TIMER < VTMRL
UV/OV OVERSHOOTS VOVHI AND TIMER ABORTS INITIAL TIMING CYCLE
UV/OV DROPS BELOW VOVLO AND TIMER RESTARTS INITIAL TIMING CYCLE
TIMER CLEARS VTMRL, CHECK GATE < VGATEL, SENSE < VCB AND SS < 20 • VOS
1
2
3
VOVHI
4 5 67
8
10 12
9 11
VOVLO
UV/OV
VUVHI
VTMRH
230µA + 8 • IDRN
5.8µA
TIMER
5.8µA
VTMRL
58µA
GATE
58µA
VGATEL
5.8µA
VIN – VGATEH
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
SS
VACL
VCB
SENSE
VDRNCL
DRAIN
VDRNL
PWRGD
GATE
START-UP
INITIAL TIMING
4252-1/2 F12
Figure 12. Undervoltage Timing with an Overvoltage Glitch (All Waveforms are Referenced to VEE)
OV OVERSHOOTS VOVHI. GATE AND SS ARE PULLED DOWN, PWRGD AND TIMER ARE UNAFFECTED
OV DROPS BELOW VOVLO, CHECK GATE < VGATEL, SENSE < VCB AND SS < 20 • VOS
1
OV
2 34
VOVHI
5
67 8 9
VOVLO
VTMRH
58µA
GATE
5.8µA
230µA + 8 • IDRN
TIMER
VGATEL
5.8µA
VIN – VGATEH
58µA
20 • (VACL + VOS)
SS
20 • (VCB + VOS)
20 • VOS
VACL
VCB
SENSE
GATE
START-UP
4252-1/2 F13
Figure 13. Overvoltage Timing (All Waveforms are Referenced to VEE)
425212fb
25
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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APPLICATIO S I FOR ATIO
CB TIMES OUT
1
1
2
VTMRH
2
1
VTMRH
5.8µA
TIMER
CB TIMES OUT
VTMRH
TIMER
230µA + 8 • IDRN
230µA + 8 • IDRN
GATE
GATE
SS
SS
SS
SENSE
VACL
VCB
VCB
SENSE
VOUT
VOUT
3
230µA + 8 • IDRN
230µA + 8 • IDRN
VACL
VCB
SENSE
VOUT
VDRNCL
VDRNCL
DRAIN
DRAIN
DRAIN
PWRGD
PWRGD
PWRGD
CB FAULT
CB FAULT
4
5.8µA
TIMER
GATE
VACL
2
CB FAULT
CB FAULT
4252-1/2 F14
(14a) Momentary Circuit-Breaker Fault
(14b) Circuit-Breaker Time Out
(14c) Multiple Circuit-Breaker Fault
Figure 14. Circuit-Breaker Timing Behavior (All Waveforms are Referenced to VEE)
VTMRH threshold, TIMER is discharged by 5.8µA. In Figure
14b, when TIMER exceeds VTMRH, GATE pulls down
immediately and the LTC4252 shuts down. In Figure 14c,
multiple momentary faults cause the TIMER capacitor to
integrate and reach VTMRH. GATE pull down follows and
the LTC4252 shuts down. During shutdown, the LTC4252-1
latches TIMER high with a 5.8µA pull-up current source;
the LTC4252-2 activates a shutdown cooling cycle.
Resetting a Fault Latch (LTC4252-1)
The latched circuit breaker fault of LTC4252-1 benefits
from long cooling time. It is reset by pulling the UV pin
below VUVLO with a switch. Reset is also accomplished by
pulling the VIN pin momentarily below (VLKO – VLKH). A
third reset method involves pulling the TIMER pin below
VTMRL as shown in Figure 15. An initial timing cycle is
skipped if TIMER is used for reset. An initial timing cycle
is generated if reset by the UV pin or the VIN pin.
The duration of the TIMER reset pulse should be smaller
than the time taken to reach 0.2V at SS pin. With a single
pole mechanical pushbutton switch, this may not be
feasible. A double pole, single throw pushbutton switch
removes this restriction by connecting the second switch
to the SS pin. With this method, both the SS and TIMER
pins are released at the same time (see Figure 24).
Shutdown Cooling Cycle (LTC4252-2)
Figure 16 shows the timer behavior of the LTC4252-2. At
time point 2, TIMER exceeds VTMRH, GATE pulls down
immediately and the LTC4252 shuts down. TIMER starts
a shutdown cooling cycle by discharging TIMER with
5.8µA to the VTMRL threshold. TIMER then charges with
5.8µA to the VTMRH threshold. There are four 5.8µA
discharge phases and three 5.8µA charge phases in this
shutdown cooling cycle spanning time points 2 and 3. At
time point 3, the LTC4252 automatic retry occurs with a
start-up cycle. Good thermal management techniques are
highly recommended; power and thermal dissipation must
be carefully evaluated when implementing the automatic
retry scheme.
425212fb
26
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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SWITCH RESETS LATCHED TIMER
SWITCH RELEASES SS
1
2 34
5.8µA
5
67 8 9
VTMRH
230µA + 8 • IDRN
VTMRL
TIMER
5.8µA
5.8µA
58µA
GATE
VGATEL
SS
58µA
VIN – VGATEH
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
VACL
VCB
SENSE
VDRNCL
DRAIN
VDRNL
PWRGD
4252-1/2 F15
GATE START-UP
MOMENTARY DPST SWITCH RESET
Figure 15. Pushbutton Reset of LTC4252-1’s Latched Fault
(All Waveforms are Referenced to VEE)
CIRCUIT BREAKER TIMES OUT
1
230µA + 8 • IDRN
TIMER
RETRY
2
5.8µA
5.8µA
VTMRL
3 45
5.8µA
5.8µA
5.8µA
5.8µA
6
78 9 10
VTMRH
230µA + 8 • IDRN
5.8µA
58µA
58µA
VGATEL
GATE
5.8µA
5.8µA
VIN – VGATEH
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
SS
VACL
VCB
SENSE
VOUT
VDRNCL
DRAIN
VDRNL
PWRGD
SHUTDOWN COOLING
CB FAULT
GATE
START-UP
4252-1/2 F16
Figure 16. Shutdown Cooling Timing Behavior of LTC4252-2 (All Waveforms are Referenced to VEE)
425212fb
27
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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Analog Current Limit and Fast Current Limit
In Figure 17a, when SENSE exceeds VACL, GATE is regulated by the analog current limit amplifier loop. When
SENSE drops below VACL, GATE is allowed to pull up. In
Figure 17b, when a severe fault occurs, SENSE exceeds
VFCL and GATE immediately pulls down until the analog
current amplifier establishes control. If the severe fault
causes VOUT to exceed VDRNCL, the DRAIN pin is clamped
at VDRNCL. IDRN flows into the DRAIN pin and is multiplied
by 8. This extra current is added to the TIMER pull-up
current of 230µA. This accelerated TIMER current of
[230µA+8 • IDRN] produces a shorter circuit breaker fault
delay. Careful selection of CT, RD and MOSFET can help
prevent SOA damage in a low impedance fault condition.
Soft-Start
If the SS pin is not connected, this pin defaults to a linear
voltage ramp, from 0V to 2.2V in about 180µs (or 0V to
1.4V in 230µs for the LTC4252A) at GATE start-up, as
shown in Figure 18a. If a soft-start capacitor, CSS, is
connected to this SS pin, the soft-start response is modified from a linear ramp to an RC response (Equation 6), as
shown in Figure 18b. This feature allows load current to
slowly ramp-up at GATE start-up. Soft-start is initiated at
time point 3 by a TIMER transition from VTMRH to VTMRL
(time points 1 to 2) or by the OV pin falling below the VOVLO
threshold after an OV condition. When the SS pin is below
0.2V, the analog current limit amplifier holds GATE low.
Above 0.2V, GATE is released and 58µA ramps up the
compensation network and GATE capacitance at time
point 4. Meanwhile, the SS pin voltage continues to ramp
up. When GATE reaches the MOSFET’s threshold, the
MOSFET begins to conduct. Due to the MOSFET’s high gm,
the MOSFET current quickly reaches the soft-start control
value of VACL(t) (Equation 7). At time point 6, the GATE
voltage is controlled by the current limit amplifier. The
soft-start control voltage reaches the circuit breaker voltage, VCB, at time point 7 and the circuit breaker TIMER
activates. As the load capacitor nears full charge, load
CB TIMES OUT
12
230µA + 8 • IDRN
34
1
VTMRH
5.8µA
TIMER
5.8µA
GATE
GATE
SS
SS
VACL
SENSE
VCB
2
VTMRH
230µA + 8 • IDRN
TIMER
SENSE
VOUT
VOUT
DRAIN
DRAIN
PWRGD
PWRGD
VFCL
VACL
VCB
VDRNCL
4252-1/2 F17
(17a) Analog Current Limit Fault
(17b) Fast Current Limit Fault
Figure 17. Current Limit Behavior (All Waveforms are Referenced to VEE)
425212fb
28
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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END OF INTIAL TIMING CYCLE
12 34 567
7a
END OF INTIAL TIMING CYCLE
8 9
10
VTMRH 230µA + 8 • IDRN
TIMER
5.8µA
VTMRL
58µA
GATE
12 3 4 5 6
11
VIN – VGATEH
TIMER
11
5.8µA
58µA
58µA
20 • (VACL + VOS)
VIN – VGATEH
58µA
20 • (VACL + VOS)
20 • (VCB + VOS)
SS
20 • VOS
20 • VOS
VACL
SENSE
10
VTMRL
VGS(th)
20 • (VCB + VOS)
8 9
GATE
VGS(th)
SS
7
VTMRH 230µA + 8 • IDRN
VCB
VACL
SENSE
VCB
VDRNCL
VDRNL
DRAIN
PWRGD
VDRNCL
VDRNL
DRAIN
PWRGD
4252-1/2 F18
(18a) Without External CSS
(18b) With External CSS
Figure 18. Soft-Start Timing (All Waveforms are Referenced to VEE)
current begins to decline below VACL(t). The current limit
loop shuts off and GATE releases at time point 8. At time
point 9, the SENSE voltage falls below VCB and TIMER
deactivates.
Large values of CSS can cause premature circuit breaker
time out as VACL(t) may exceed the VCB potential during
the circuit breaker delay. The load capacitor is unable to
achieve full charge in one GATE start-up cycle. A more
serious side effect of large CSS values is SOA duration may
be exceeded during soft-start into a low impedance load.
A soft-start voltage below VCB will not activate the circuit
breaker TIMER.
Power Limit Circuit Breaker
Figure 19 shows the LTC4252A-1 in a power limit circuit
breaking application. The SENSE pin is modulated by the
board supply voltage, VSUPPLY. The zener voltage, VZ is set
to be the same as the low supply operating voltage,
VSUPPLY(MIN) = 43V. If the goal is to have the high supply
operating voltage, VSUPPLY(MAX) = 71V giving the same
power at VSUPPLY(MIN), then resistors R4 and R6 are
selected using the ratio:
R6
VCB
=
R4 VSUPPLY(MAX)
(16)
If R6 is 27Ω, R4 is 38.3k. The peak circuit breaker power
limit is:
POWERMAX
2
VSUPPLY(MIN) + VSUPPLY(MAX) )
(
=
4 • VSUPPLY(MIN) • VSUPPLY(MAX)
• POWERSUPPLY(MIN)
(17)
= 1.064 • POWERSUPPLY(MIN)
when
VSUPPLY = 0.5 • (VSUPPLY(MIN) + VSUPPLY(MAX)) = 57V.
The peak power at the fault current limit occurs at the
supply overvoltage threshold. The fault current limited
power is:
POWERFAULT =
VSUPPLY ⎛
R6 ⎞
• ⎜ VACL – (VSUPPLY – VZ ) • ⎟
⎝
RS
R4 ⎠
(18)
425212fb
29
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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GND
RIN
3× 1.8k
1/4W EACH
GND
(SHORT PIN)
CIN
1µF
1
VIN
R1
390k
1%
8
10
R2
30.1k
1%
UV
PWRGD
OV
DRAIN
TIMER
3
CT
SS
0.68µF
C1
10nF
CSS
68nF
GATE
VEE
SENSE
CL
100µF
R5
100k
D1
BZV85C43
LTC4252A-1
9
+
R4
38.3k
LOAD
EN
*
VOUT
2
RD 1M
7
6
Q1
IRF530S
R6 27Ω
4
RC
10Ω
CC
10nF
5
RS
0.02Ω
4252-1/2 F19
–48V
*FMMT493
Figure 19. Power Limit Circuit Breaking Application
Circuit Breaker with Foldback Current Limit
Figure 20 shows the LTC4252A in a foldback current limit
application. When VOUT is shorted to the –48V RTN
supply, current flows through resistors R4 and R5. This
results in a voltage drop across R5 and a corresponding
reduction in voltage drop across the sense resistor, RS, as
the ACL amplifier servos the sense voltage between the
SENSE and VEE pins to about 60mV. The short-circuit
current through RS reduces as the VOUT voltage increases
during an output short-circuit condition. Without foldback
current limiting resistor R5, the current is limited to 3A
during analog current limit. With R5, the short-circuit
current is limited to 0.5A when VOUT is shorted to 71V.
Inrush Control Without a Sense Resistor
During Power-Up
Figure 21 shows the LTC4252A in an application where the
inrush current is controlled without a sense resistor during power-up. This setup is suitable only for applications
that don’t require short-circut protection from the
LTC4252A. Resistor R4 and capacitor C2 act as a feedback
network to accurately control the inrush current. The C2
capacitor can be calculated with the following equation:
IGATE • CL
(19)
IINRUSH
where IGATE = 58µA and CL is the total load capacitance.
C2 =
Capacitor C3 and resistor R4 prevent Q1 from momentarily turning on when the power pins first make contact.
Without C3 and R4, capacitor C2 pulls the gate of Q1 up to
a voltage roughly equal to VEE • C2/CGS(Q1) before the
LTC4252A powers up. By placing capacitor C3 in parallel
with the gate capacitance of Q1 and isolating them from C2
using resistor R4, the problem is solved. The value of C3
is given by:
C3 =
(
VSUPPLY(MAX)
• C2 + CGD(Q1)
VGS(TH),Q1
)
(20)
C3 ≈ 35 • C2 for VSUPPLY(MAX) = 71V
where VGS(TH),Q1 is the MOSFET’s minimum gate threshold and VSUPPLY(MAX) is the maximum operating input
voltage.
Diode-ORing
Figure 22 shows the LTC4252 used as diode-oring with
Hot Swap capability in a dual – 48V power supply application. The conventional diode-OR method uses two high
power diodes and heat sinks to contain the large heat
dissipation of the diodes. With the LTC4252 controlling
the external FETs Q2 and Q3 in a diode-OR manner, the
small turn-on voltage across the fully enhanced Q2 and Q3
reduces the power dissipation significantly.
425212fb
30
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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–48V RTN
(LONG PIN)
–48V RTN
(SHORT PIN)
+
RIN
3× 1.8k
1/4W EACH
CIN
1µF
1
CL
100µF
R3
5.1k
LOAD
EN
VIN
R1
390k
1%
*
LTC4252A-1
8
9
C1
10nF
OV
PWRGD
UV
DRAIN
10
TIMER
3
CT
SS
0.68µF
R2
30.1k
1%
RD 1M
7
R4
38.3k
6
GATE
RC
10Ω
CC
10nF
5
CSS
68nF
Q1
IRF530S
R5 27Ω
4
SENSE
VEE
VOUT
2
RS
0.02Ω
4252-1/2 F20
–48V
*MOC207
Figure 20. Circuit Breaker with Foldback Current Limit Application
–48V RTN
(LONG PIN)
–48V RTN
(SHORT PIN)
+
RIN
3× 1.8k
1/4W EACH
CIN
1µF
1
R3
5.1k
LOAD
EN
VIN
R1
390k
1%
*
LTC4252A-1
8
9
OV
PWRGD
DRAIN
UV
VOUT
2
7
RD 1M
C2
10nF
100V
R4
1k
1%
C1
10nF
R2
30.1k
1%
CL
100µF
10
TIMER
3
CT
SS
0.68µF
CSS
68nF
GATE
VEE
SENSE
5
–48V
6
4
C3
330nF
25V
Q1
IRF530S
4252-1/2 F21
*MOC207
Figure 21. Inrush Control Without a Sense Resistor Application
At power-up, Q5 and Q8 are held off low by the SS pin of
the LTC4252; resistors R5 and R8 pull the SENSE pin
closed to VEE. VEE is connected to the power supply with
lower voltage through the body diodes Q2 or Q3 until Q2
or Q3 is turned on. This allows the LTC4252 to perform a
start-up cycle and ramp up the SS and GATE voltage.
As the SS voltage ramps up to 2.2V, it turns on Q5 and Q8
and pulls TIMER low through Q6 and Q9. The sense
voltage rises as current flows into R5 and R8 through
resistors R3 and R6. The ACL amplifier of the LTC4252
servos the sense voltage to about 100mV as the GATE
voltage regulates Q2 and Q3. Current flows into R4, Q4 and
R7, Q7 as Q2 and Q3 turn on. The respective node voltages
at the R3 and R4 connection and the R6 and R7 connection
are always kept equal to their respective sense voltages by
the Q4 and Q2 VDS drop and the Q7 and Q3 VDS drop
assuming the Q5 and Q8 VDS drop is negligible.
425212fb
31
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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Hot Swap SECTION
–48V RTN
RIN1
3× 1.8k IN SERIES
1/4W EACH
1
R1
420k
7
C1
10nF
8
CT
0.33µF
R2
32.4k
2
UV/OV
VIN
DRAIN
GATE
TIMER
LTC4252-1
SS
VEE SENSE
CSS
68nF
6
LOAD
MODULE
CIN
1µF RD
1M
5
3
RC1
10Ω
CC1
22nF
Q1
IRF530S
RS
0.02Ω
4
DIODE-OR CIRCUIT FOR CHANNEL A
–48V A
RIN2
3× 1.8k IN SERIES
1/4W EACH
1
9
CIN2
1µF
Q6
FDV301N
VIN
7
DRAIN
UV
2
PWRGD
LTC4252-2
4
10
SENSE
TIMER
3
SS
6
8
GATE
OV
VEE
5
R3
12k
Q5
FDV301N
R4
150Ω
Q4
BSS131
R5
560Ω
RC2
10Ω
CC2
22nF
Q2
IRF530S
DIODE-OR CIRCUIT FOR CHANNEL B
–48V B
RIN3
3× 1.8k IN SERIES
1/4W EACH
1
9
CIN3
1µF
VIN
7
DRAIN
UV
PWRGD
LTC4252-2
4
10
TIMER
SENSE
3
SS
6
8
GATE
OV
VEE
2
Q9
FDV301N
5
R6
12k
Q8
FDV301N
R7
150Ω
Q7
BSS131
R8
560Ω
RC3
10Ω
CC3
22nF
Q3
IRF530S
4252-1/2 F22
Figure 22. –48V/2.5A Diode-OR Application
425212fb
32
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
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APPLICATIO S I FOR ATIO
The internal fault latches of the LTC4252 are disabled as
the TIMER pin is always held low by the SS voltage when
Q2 and Q3 are in analog current limit.
If both power supplies from channel A and B are exactly
equal, then equal load current will flow through Q2 and Q3
to the load module via the Hot Swap section.
If the channel A supply is greater than the channel B by
more than 100mV, the sense voltage will rise above the
fast comparator trip threshold of 200mV, the GATE will be
pulled low and Q2 is turned off. The GATE ramps up and
regulates Q2 when the channel A supply is equal to the
channel B supply. Likewise, if the channel B supply is
greater than channel A by more than 100mV, it trips the
fast comparator and GATE is pulled low and Q3 is turned
off. The GATE ramps up and regulates Q3 when the
channel B supply is equal to the channel A supply.
Resistors R4, R7 and external FETs Q4 and Q7 limit the
current flow into Q5 and Q8 during their respective supply
source short. When the channel A supply is shorted to the
– 48V RTN (or GND), large current flows into Q4 momentarily and creates a voltage drop across R4, which in turn
reduces the gate-to-source voltage of Q4, limiting the
–48V RTN
(LONG PIN)
–48V RTN
(SHORT PIN)
Similarly, when the channel B supply is shorted to the
– 48V RTN (or GND), large current flows into Q7 momentarily and creates a voltage drop across R7, which in turn
reduces the gate-to-source voltage of Q7, thus limiting the
current flow. The increase in sense voltage will trip the fast
comparator of LTC4252 and pull the GATE low instantly.
The channel B supply short will not cause Q2 of channel A
diode-OR circuit to turn off. The load short at the output of
Q1 is protected by the Hot Swap section.
Using an EMI Filter Module
Many applications place an EMI filter module in the power
path to prevent switching noise of the module from being
injected back onto the power supply. A typical application
using the Lucent FLTR100V10 filter module is shown in
Figure 23. When using a filter, an optoisolator is required
to prevent common mode transients from destroying the
PWRGD and ON/OFF pins.
RIN
3× 1.8k
1/4W
1
1
R3
5.1k
VIN+
VOUT+
8
10
OV
PWRGD
DRAIN
UV
TIMER
3
CT
SS
0.68µF
CSS
68nF
GATE
SENSE
VEE
5
2
7
6
+
4
RC
10Ω
CC
10nF
5V
SENSE
2
RD
1M
9
+ 8
*
LTC4252A-1
C1
10nF
R2
30.1k
1%
CIN
1µF
VIN
R1
390k
1%
9
–48V
current flow. The sense voltage is lifted up and causes the
fast comparator of LTC4252 to trip and pull the GATE low
instantly. The channel A supply short will not cause Q3 of
channel B diode-OR circuit to turn off.
Q1
IRF530S
RS
0.02Ω
1N4003
VIN
–
7
ON/OFF
+
LUCENT
JW050A1-E
VOUT+
VIN
C2
LUCENT
0.1µF
100V FLTR100V10
TRIM
C3
0.1µF
100V
VOUT–
CASE
+
C4
100µF
100V
C5
0.1µF
100V
4
SENSE–
VIN–
C6
100µF
16V
6
– 5
VOUT
CASE
3
4252-1/2 F20
*MOC207
Figure 23. Typical Application Using a Filter Module
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33
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
PACKAGE DESCRIPTIO
MS8 Package
8-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1660)
0.889 ± 0.127
(.035 ± .005)
5.23
(.206)
MIN
3.20 – 3.45
(.126 – .136)
0.42 ± 0.038
(.0165 ± .0015)
TYP
3.00 ± 0.102
(.118 ± .004)
(NOTE 3)
0.65
(.0256)
BSC
8
7 6 5
0.52
(.0205)
REF
RECOMMENDED SOLDER PAD LAYOUT
0.254
(.010)
3.00 ± 0.102
(.118 ± .004)
(NOTE 4)
4.90 ± 0.152
(.193 ± .006)
DETAIL “A”
0° – 6° TYP
GAUGE PLANE
0.53 ± 0.152
(.021 ± .006)
DETAIL “A”
1
2 3
4
1.10
(.043)
MAX
0.86
(.034)
REF
0.18
(.007)
SEATING
PLANE
0.22 – 0.38
(.009 – .015)
TYP
0.65
(.0256)
NOTE:
BSC
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
0.127 ± 0.076
(.005 ± .003)
MSOP (MS8) 0204
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34
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
PACKAGE DESCRIPTIO
MS Package
10-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1661)
0.889 ± 0.127
(.035 ± .005)
5.23
(.206)
MIN
3.20 – 3.45
(.126 – .136)
3.00 ± 0.102
(.118 ± .004)
(NOTE 3)
0.50
0.305 ± 0.038
(.0197)
(.0120 ± .0015)
BSC
TYP
RECOMMENDED SOLDER PAD LAYOUT
0.254
(.010)
0.497 ± 0.076
(.0196 ± .003)
REF
10 9 8 7 6
3.00 ± 0.102
(.118 ± .004)
(NOTE 4)
4.90 ± 0.152
(.193 ± .006)
DETAIL “A”
0° – 6° TYP
GAUGE PLANE
1 2 3 4 5
0.53 ± 0.152
(.021 ± .006)
DETAIL “A”
1.10
(.043)
MAX
0.86
(.034)
REF
0.18
(.007)
SEATING
PLANE
0.17 – 0.27
(.007 – .011)
TYP
0.50
(.0197)
NOTE:
BSC
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
0.127 ± 0.076
(.005 ± .003)
MSOP (MS) 0603
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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 representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
35
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
U
TYPICAL APPLICATIO
GND
RIN
2× 5.1k IN SERIES
1/4W EACH
GND
(SHORT PIN)
1
VIN
R1
402k
1%
LTC4252-1
7
R2
32.4k
1%
8
2
CT
150nF
C1
10nF
UV/OV
DRAIN
TIMER
GATE
SS
CSS
27nF
PUSH
RESET
VEE
SENSE
4
6
CL
100µF
CIN
1µF
RD
1M
+
LOAD
VOUT
5
Q1
IRF540S
3
R3
22Ω
RC
10Ω
CC
22nF
RS
0.01Ω
4252-1/2 F24
–48V
Figure 24. – 48V/5A Application
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1640AH/LT1640AL
Negative High Voltage Hot Swap Controllers in SO-8
Negative High Voltage Supplies from –10V to – 80V
LT1641-1/LT1641-2
Positive High Voltage Hot Swap Controllers in SO-8
Supplies from 9V to 80V, Latched Off/Autoretry
LTC1642
Fault Protected Hot Swap Controller
3V to 16.5V, Overvoltage Protection up to 33V
LTC4214
Negative Voltage Hot Swap Controller
Operates from –6V to –16V
LTC4220
Dual Supply Hot Swap Controller
±2.2V to ±16.5V Operation
LT4250
– 48V Hot Swap Controller in SO-8
Active Current Limiting, Supplies from – 20V to – 80V
LTC4251/LTC4251-1
– 48V Hot Swap Controllers in SOT-23
Fast Active Current Limiting, Supplies from –15V
LTC4253
–48V Hot Swap Controller with Sequencer
Fast Current Limiting with Three Sequenced Power Good Outputs,
Supplies from –15V
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36
Linear Technology Corporation
LT 0406 REV B • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2001
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