LINER LTC4253AIGN-ADJ

LTC4253A-ADJ
– 48V Hot Swap Controller
with Sequencer
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FEATURES
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DESCRIPTIO
The LTC®4253A-ADJ 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. The LTC4253A-ADJ latches off after a circuit fault.
Allows Safe Board Insertion and Removal from a
Live – 48V Backplane
Floating Topology Permits Very High Voltage
Operation
Adjustable Analog Current Limit with Breaker Timer
Fast Response Time Limits Peak Fault Current
Adjustable Undervoltage/Overvoltage Protection
with ±1% Threshold Accuracy
Three Sequenced Power Good Outputs
Adjustable Soft-Start Current Limit
Adjustable Timer with Drain Voltage Accelerated
Response
Latchoff After Fault
Available in 20-Pin SSOP and 20-Pin (4mm × 4mm)
QFN Packages
Undervoltage and overvoltage detectors with adjustable
thresholds and hystereses disconnect the load whenever
the input supply exceeds the desired operating range. The
LTC4253A-ADJ’s supply input is shunt-regulated, allowing
safe operation with very high supply voltages. A multifunction timer delays initial start-up and controls the circuit
breaker’s response time. The circuit breaker’s response
time can be accelerated by sensing excessive MOSFET drain
voltage. An adjustable soft-start circuit controls MOSFET
inrush current at start-up.
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APPLICATIO S
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– 48V Distributed Power Systems
Negative Power Supply Control
Central Office Switching
High Availability Servers
Disk Arrays
Three power good outputs can be sequenced to enable
external power modules at start-up or disable them if the
circuit breaker trips. The LTC4253A-ADJ is available in
20-pin SSOP and 20-pin (4mm × 4mm) QFN packages.
, LTC and LT are registered trademarks of Linear Technology Corporation.
Hot Swap is a trademark of Linear Technology Corporation. All other trademarks are the
property of their respective owners. Patent pending.
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TYPICAL APPLICATIO
– 48V/2.5A Hot Swap Controller
– 48V RTN
– 48V RTN
2.5k
15k(1/4W)/6
1µF
255k
1%
10nF
5.6k
– 48V A
– 48V B
B3100*
OV
33nF
0.1µF
SS
LOAD2
5.6k
LOAD3
GATE
10V
EN
EN
†
†
†
PWRGD1
4253A TA01
PWRGD2
PWRGD3
SS
1V
SENSE
50mV
DRAIN
SQTIMER
1M
GATE
0.68µF
Start-Up Behavior
LOAD1
EN
UV
OVL
20k
1%
5.6k
UVL
2.1k
1%
B3100*
100µF
EN2 EN3 VIN
LTC4253A-ADJ
RESET
1.24k
1%
0.536k
1%
+
VIN
TIMER
SEL
SENSE
VEE
IRF530S
*DIODES, INC.
†MOC207
VOUT
50V
10Ω
10nF
0.02Ω
1ms/DIV
4253A TA01b
4253a-adjf
1
LTC4253A-ADJ
U
W W
W
ABSOLUTE
AXI U RATI GS
(Note 1) All voltages referred to VEE
Current into VIN (100µs Pulse) ........................... 100mA
Current into DRAIN (100µs Pulse) ........................ 20mA
VIN, DRAIN Minimum Voltage............................... – 0.3V
Input/Output (Except SENSE
and DRAIN) Voltage ...................................– 0.3V to 16V
SENSE Voltage ..........................................– 0.6V to 16V
Current Out of SENSE (20µs Pulse) .................. – 200mA
Maximum Junction Temperature .......................... 125°C
Operating Temperature Range
LTC4253A-ADJC ..................................... 0°C to 70°C
LTC4253A-ADJI .................................. – 40°C to 85°C
Storage Temperature Range
SSOP ................................................ – 65°C to 150°C
QFN .................................................. – 65°C to 125°C
Lead Temperature (Soldering, 10 sec)
SSOP ................................................................ 300°C
U
W
U
PACKAGE/ORDER I FOR ATIO
19 EN3
PWRGD1
3
18 SQTIMER
VIN
4
17 TIMER
RESET
5
16 UVL
SS 3
SS
6
15 UV
SEL 4
8
13 OV
VEE
9
12 DRAIN
VEE 10
13 UVL
12 UV
11 OVL
SENSE 5
6
7
8
9 10
11 GATE
UF PART
MARKING*
OV
SENSE
14 TIMER
21
DRAIN
14 OVL
15 SQTIMER
VIN 1
RESET 2
GATE
7
LTC4253ACUF-ADJ
LTC4253AIUF-ADJ
20 19 18 17 16
NC
SEL
LTC4253ACGN-ADJ
LTC4253AIGN-ADJ
ORDER PART
NUMBER
EN3
20 PWRGD3
2
PWRGD3
1
EN2
PWRGD1
EN2
PWRGD2
VEE
TOP VIEW
PWRGD2
TOP VIEW
ORDER PART
NUMBER
253AJ
UF PACKAGE
20-LEAD (4mm × 4mm) PLASTIC QFN
GN PACKAGE
20-LEAD PLASTIC SSOP
TJMAX = 125°C, θJA = 37°C/W
EXPOSED PAD (PIN 21) IS VEEMUST BE SOLDERED TO PCB
TJMAX = 125°C, θJA = 95°C/W
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. *The temperature grade is identified by a label on the shipping container.
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 2)
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 = UVL = OV = OVL = 4V, VIN = (VZ – 0.3V)
●
1.1
2
mA
VLKO
VIN Undervoltage Lockout
Coming Out of UVLO (Rising VIN)
●
9
10
V
VLKH
VIN Undervoltage Lockout Hysteresis
●
0.25
0.5
0.75
V
VIH
TTL Input High Voltage
●
2
VIL
TTL Input Low Voltage
●
0.8
V
VHYST
TTL Input Buffer Hysteresis
IRESET
RESET Input Current
VEE ≤ VRESET ≤ VIN
●
IEN
EN2, EN3 Input Current
VEN = 4V (Sinking)
VEN = 0V
●
●
●
MIN
TYP
MAX
UNITS
11.5
13
14.5
V
Ω
5
V
600
60
mV
±0.1
±10
µA
120
±0.1
180
±10
µA
µA
4253a-adjf
2
LTC4253A-ADJ
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 2)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
ISEL
SEL Input Current
VSEL = 0V (Sourcing)
VSEL = VIN
●
●
10
20
±0.1
40
±10
µA
µA
VCB
Circuit Breaker Current Limit Voltage
VCB = (VSENSE – VEE)
●
45
50
55
mV
VACL
VCB
Analog Current Limit Voltage x%
Circuit Breaker Current Limit Voltage
VACL = (VSENSE – VEE), SS = Open or 1.4V
●
105
120
138
%
VFCL
Fast Current Limit Voltage
VFCL = (VSENSE – VEE)
●
150
200
300
mV
VSS
SS Voltage
After End of SS Timing Cycle
●
1.25
1.4
1.55
V
ISS
SS Pin Current
UV = UVL = OV = OVL = 4V,
VSENSE = VEE, VSS = 0V (Sourcing)
●
16
28
40
µA
UV = UVL = OV = OVL = 0V,
VSENSE = VEE, VSS = 1V (Sinking)
28
mA
RSS
SS Output Impedance
50
kΩ
VOS
Analog Current Limit Offset Voltage
10
mV
VACL + VOS
VSS
Ratio (VACL + VOS) to SS Voltage
0.05
V/V
IGATE
GATE Pin Output Current
UV = UVL = OV = OVL = 4V, VSENSE = VEE,
VGATE = 0V (Sourcing)
●
30
50
70
µA
UV = UVL = OV = OVL = 4V, VSENSE – VEE = 0.15V,
VGATE = 3V (Sinking)
17
mA
UV = UVL = OV = OVL = 4V, VSENSE – VEE = 0.3V,
VGATE = 1V (Sinking)
190
mA
●
VGATE
External MOSFET Gate Drive
VGATE – VEE, IIN = 2mA
VGATEL
Gate Low Threshold
(Before Gate Ramp Up)
0.5
V
VGATEH
Gate High Threshold
VGATEH = VIN – VGATE,
For PWRGD1, PWRGD2, PWRGD3 Status
2.8
V
VUVHI
UV Pin Threshold
UV Low to High
●
3.05
3.08
3.11
V
VUVLO
UVL Pin Threshold
UVL High to Low
●
3.05
3.08
3.11
V
VOVHI
OV Pin Threshold
OV Low to High
●
5.04
5.09
5.14
V
VOVLO
OVL Pin Threshold
OVL High to Low
●
5.025
5.08
5.135
V
ISENSE
SENSE Pin Input Current
UV = UVL = OV = OVL = 4V, VSENSE = 50mV (Sourcing) ●
15
30
µA
IINP
UV, UVL, OV, OVL Pin Input Current
UV = UVL = OV = OVL = 4V
±0.1
±1
µA
VTMRH
TIMER Pin Voltage High Threshold
●
3.5
4
4.5
V
VTMRL
TIMER Pin Voltage Low Threshold
●
0.8
1
1.2
V
ITMR
TIMER Pin Current
●
3
5
7
Timer On (Initial Cycle/Latchoff, Sourcing), VTMR = 2V
10
●
Timer Off (Initial Cycle, Sinking), VTMR = 2V
Timer On (Circuit Breaker, Sourcing,
IDRN = 0µA), VTMR = 2V
(ITMR at IDRN = 50µA – ITMR at IDRN = 0µA)
50µA
VSQTMRH
SQTIMER Pin Voltage High Threshold
VSQTMRL
SQTIMER Pin Voltage Low Threshold
VZ
28
●
120
Timer On (Circuit Breaker, Sourcing,
IDRN = 50µA), VTMR = 2V
∆ITMRACC
∆IDRN
12
200
V
µA
mA
280
µA
µA
600
Timer Off (Circuit Breaker, Sinking), VTMR = 2V
●
3
5
7
µA
Timer On (Circuit Breaker with IDRN = 50µA)
●
7
8
9
µA/µA
●
3.5
4
4.5
0.33
V
V
4253a-adjf
3
LTC4253A-ADJ
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 2)
SYMBOL
PARAMETER
CONDITIONS
ISQTMR
SQTIMER Pin Current
SQTIMER On (Power Good Sequence, Sourcing),
VSQTMR = 2V
●
MIN
TYP
MAX
3
5
7
SQTIMER On (Power Good Sequence, Sinking),
VSQTMR = 2V
UNITS
µA
28
●
VDRNL
DRAIN Pin Voltage Low Threshold
For PWRGD1, PWRGD2, PWRGD3 Status
IDRNL
DRAIN Leakage Current
VDRAIN = 4V
VDRNCL
DRAIN Pin Clamp Voltage
IDRN = 50µA
●
VPGL
PWRGD1, PWRGD2, PWRGD3 Signals
Output Low Voltage
IPG = 1.6mA
IPG = 5mA
●
●
IPGH
PWRGD1, PWRGD2, PWRGD3
Output High Current
VPG = 0V (Sourcing)
●
tSQ
SQ Timer Default Ramp Period
SQTIMER Pin Floating,
VSQTMR Ramps from 0.5V to 3.5V
tSS
SS Default Ramp Period
SS Pin Floating, VSS Ramps from 0.2V to 1.25V
tPLLUG
UV Low to GATE Low
●
1
5
µs
tPHLOG
OV High to GATE Low
●
1
5
µs
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
2
mA
5
30
2.39
3
V
±0.1
±1
µA
6
7.5
V
0.25
0.4
1.2
V
V
50
70
µA
µs
250
µs
140
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.
U W
TYPICAL PERFOR A CE CHARACTERISTICS
VZ vs Temperature
IIN vs Temperature
IIN vs VIN
1.5
1000
14.5
IIN = 2mA
14.0
TA = 125°C
TA = 85°C
TA = 25°C
TA = –40°C
VZ (V)
IIN (mA)
13.5
13.0
VIN = VZ – 0.3V
1.3
1.2
IIN (mA)
100
1.4
10
1.1
1.0
0.9
0.8
1
0.7
12.5
0.6
12.0
–50
0.1
–25
50
25
0
75
TEMPERATURE (°C)
100
125
0
5
10
15
20
VIN (V)
4253A G01
4253A G02
0.5
–50 –25
50
25
0
75
TEMPERATURE (°C)
100
125
4253A G03
4253a-adjf
4
LTC4253A-ADJ
U W
TYPICAL PERFOR A CE CHARACTERISTICS
55
200
IIN = 2mA
TA = 25°C
54
80
IIN = 2mA
IIN = 2mA
75
53
160
IEN
70
52
80
51
VACL (mV)
120
VCB (mV)
IEN/ISEL (µA)
Analog Current Limit Voltage VACL
vs Temperature
Circuit Breaker Current Limit
Voltage VCB vs Temperature
IEN vs VEN and ISEL vs VSEL
50
49
65
60
55
48
50
47
40
ISEL
45
–50 –25
0
0
2
4
6
8 10 12
VEN/VSEL (V)
45
46
14
16
18
50
25
0
75
TEMPERATURE (°C)
Fast Current Limit Voltage VFCL
vs Temperature
58
230
56
220
54
210
52
190
170
44
160
42
50
25
0
75
TEMPERATURE (°C)
100
IIN = 2mA
UV/UVL/OV/OVL = 4V
TIMER = 0V
VSENSE = VEE
VGATE = 0V
20
5
50
25
0
75
TEMPERATURE (°C)
4253A G07
100
0
–50 –25
125
IGATE (FCL, Sink) vs Temperature
14.0
200
13.5
50
IIN = 2mA
UV/UVL/OV/OVL = 4V
TIMER = 0V
VSENSE = VEE
0.9
0.8
0.7
50
25
0
75
TEMPERATURE (°C)
VGATEL (V)
IGATE (mA)
VGATE (V)
0
–50 –25
12.5
12.0
11.5
100
125
4253A G10
IIN = 2mA
UV/UVL/OV/OVL = 4V
TIMER = 0V
GATE THRESHOLD
BEFORE RAMP UP
0.6
0.5
0.4
0.3
11.0
0.2
10.5
0.1
10.0
–50
125
VGATEL vs Temperature
1.0
13.0
IIN = 2mA
UV/UVL/OV/OVL = 4V
TIMER = 0V
VSENSE – VEE = 0.3V
VGATE = 1V
100
4253A G09
VGATE vs Temperature
14.5
100
50
25
75
0
TEMPERATURE (°C)
4253A G08
250
150
15
10
40
–50 –25
125
125
IIN = 2mA
UV/UVL/OV/OVL = 4V
TIMER = 0V
VSENSE – VEE = 0.15V
VGATE = 3V
25
48
46
100
IGATE (ACL, Sink) vs Temperature
50
180
150
–50 –25
50
75
25
TEMPERATURE (°C)
30
IGATE (mA)
IIN = 2mA
200
0
4253A G06
IGATE (Source) vs Temperature
60
IGATE (µA)
VFCL (mV)
240
40
–50 –25
125
4253A G05
4253A G04
250
100
–25
0
25
50
75
TEMPERATURE (°C)
100
125
4253A G11
0
–50 –25
50
25
0
75
TEMPERATURE (°C)
100
125
4253A G12
4253a-adjf
5
LTC4253A-ADJ
U W
TYPICAL PERFOR A CE CHARACTERISTICS
VGATEH vs Temperature
UV Threshold vs Temperature
3.6
3.11
IIN = 2mA
UV/UVL/OV/OVL = 4V
3.4
VGATEH = VIN – VGATE
OV Threshold vs Temperature
5.14
IIN = 2mA
3.10
IIN = 2mA
5.12
VGATEH (V)
3.0
2.8
2.6
0V THRESHOLD (V)
UV THRESHOLD (V)
3.2
3.09
VUVHI AND VUVLO
3.08
3.07
5.10
VOVHI
5.08
VOVLO
5.06
2.4
3.06
2.2
–25
0
50
75
25
TEMPERATURE (°C)
100
3.05
–50 –25
125
50
25
75
0
TEMPERATURE (°C)
4253A G13
ISENSE vs (VSENSE – VEE)
–5
–10
ISENSE (µA)
–ISENSE (mA)
0.1
1
10
–0.5
0
0.5
VSENSE – VEE (V)
1
IIN = 2mA
UV/UVL/OV/OVL = 4V
TIMER = 0V
VSENSE – VEE = 50mV
VGATE = HIGH
125
IIN = 2mA
4.0
VTMRH
3.5
3.0
2.5
2.0
1.5
VTMRL
1.0
–25
0.5
–30
–50 –25
1.5
50
25
75
0
TEMPERATURE (°C)
100
0
–50 –25
125
50
25
0
75
TEMPERATURE (°C)
4253A G17
ITMR (Initial Cycle, Sourcing)
vs Temperature
9
4.5
–15
4253A G16
10
100
TIMER Threshold vs Temperature
5.0
–20
IIN = 2mA
UV/UVL/OV/OVL = 4V
TIMER = 0V
GATE = HIGH
TA = 25°C
–1
50
25
75
0
TEMPERATURE (°C)
4253A G15
ISENSE vs Temperature
0
1000
–1.5
5.02
–50 –25
125
4253A G14
0.01
100
100
TIMER THRESHOLD (V)
2.0
–50
5.04
IIN = 2mA
VTMR = 2V
230
8
125
4253A G18
ITMR (Circuit Breaker, Sourcing)
vs Temperature
240
100
ITMR vs IDRN
10
IIN = 2mA
IDRN = 0µA
IIN = 2mA
TA = 25°C
220
5
4
210
ITMR (mA)
6
ITMR (µA)
ITMR (µA)
7
200
1
190
3
180
2
170
1
0
–50 –25
50
25
0
75
TEMPERATURE (°C)
100
125
4253A G19
160
–50 –25
0
50
75
25
TEMPERATURE (°C)
100
125
4253A G20
0.1
0.001
0.01
0.1
IDRN (mA)
1
10
4253A G21
4253a-adjf
6
LTC4253A-ADJ
U W
TYPICAL PERFOR A CE CHARACTERISTICS
SQTIMER Threshold
vs Temperature
∆ITMRACC/∆IDRN vs Temperature
4.0
8.6
3.5
8.4
3.0
8.2
8.0
7.8
VDRNL vs Temperature
2.60
IIN = 2mA
IIN = 2mA
VSQTMR (V)
∆ITMRACC/∆IDRN (µA/µA)
8.8
4.5
2.50
2.5
2.0
VSQTMRL
0.5
7.2
7.0
–50 –25
50
25
0
75
TEMPERATURE (°C)
100
0
–50
125
2.25
0
25
50
75
TEMPERATURE (°C)
–25
100
IIN = 2mA
IDRN = 50µA
IIN = 2mA
6.0
5.8
5.6
IPG = 10mA
0.01
0.001
5.4
0.00001
5.2
0.0000001
0.00000001
100
125
TA = 125°C
TA = 85°C
TA = 25°C
TA = –40°C
1
2
4
8
10
6
VDRAIN (V)
12
1.5
1.0
IPG = 5mA
14
0.5
IPGH vs Temperature
0
–50
16
IIN = 2mA
VPWRGD = 0V
190
IIN = 2mA
SS PIN FLOATING
VSS RAMPS FROM 0.2V TO 1.25V
290
280
270
52
160
260
tSQ (µs)
170
tSS (µs)
180
54
150
140
230
44
120
220
IIN = 2mA
SQTMR PIN FLOATING
VSQTMR RAMPS FROM 0.5V TO 3.5V
42
110
210
40
–50 –25
100
–50 –25
200
–50 –25
4253A G28
50
25
0
75
TEMPERATURE (°C)
125
240
130
125
100
250
46
100
50
25
0
75
TEMPERATURE (°C)
tSQ vs Temperature
300
56
48
–25
4253A G27
tSS vs Temperature
200
50
IPG = 1.6mA
4253A G26
4253A G25
IPGH (µA)
IIN = 2mA
0.0001
50
25
0
75
TEMPERATURE (°C)
125
2.0
VPGL (V)
6.2
58
100
VPGL vs Temperature
2.2
0.1
IDRN (mA)
VDRNCL (V)
6.4
50
25
0
75
TEMPERATURE (°C)
50
75
25
TEMPERATURE (°C)
4253A G24
1
5.0
–50 –25
0
10
6.6
60
2.20
–50 –25
125
IDRN vs VDRAIN
VDRNCL vs Temperature
6.8
100
4253A G23
4253A G22
7.0
2.40
2.30
1.0
7.4
2.45
2.35
1.5
7.6
IIN = 2mA
2.55
VSQTMRH
VDRNL (V)
9.0
100
125
4253A G29
50
25
0
75
TEMPERATURE (°C)
100
125
4253A G30
4253a-adjf
7
LTC4253A-ADJ
U
U
U
PI FU CTIO S
(SSOP/QFN)
EN2 (Pin 1/Pin 18): Power Good Status Output Two
Enable. This is a TTL compatible input that is used to
control PWRGD2 and PWRGD3 outputs. When EN2 is
driven low, both PWRGD2 and PWRGD3 will go high.
When EN2 is driven high, PWRGD2 will go low provided
PWRGD1 has been active for more than one power good
sequence delay (tSQT) provided by the sequencing timer.
EN2 can be used to control the power good sequence. This
pin is internally pulled low by a 120µA current source.
PWRGD2 (Pin 2/Pin 19): Power Good Status Output Two.
Power good sequence starts with DRAIN going below
2.39V and GATE is within 2.8V on VIN. PWRGD2 will latch
active low after EN2 goes high and after one power good
sequence delay tSQT provided by the sequencing timer
from the time PWRGD1 goes low, whichever comes later.
PWRGD2 is reset by PWRGD1 going high or EN2 going
low. This pin is internally pulled high by a 50µA current
source.
PWRGD1 (Pin 3/Pin 20): Power Good Status Output One.
At start-up, PWRGD1 latches active low one tSQT after both
DRAIN is below 2.39V and GATE is within 2.8V of VIN.
PWRGD1 status is reset by undervoltage, VIN (UVLO),
RESET going high or circuit breaker fault time-out. This
pin is internally pulled high by a 50µA current source.
VIN (Pin 4/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 above VEE.
An internal undervoltage lockout (UVLO) circuit holds
GATE low until the VIN pin is greater than VLKO (9V),
overriding undervoltage and overvoltage events. If there is
no undervoltage, no overvoltage and VIN comes out of
UVLO, TIMER starts an initial timing cycle before initiating
GATE ramp up. If VIN drops below approximately 8.5V,
GATE pulls low immediately.
RESET (Pin 5/Pin 2): Circuit Breaker Reset Pin. This is an
asynchronous TTL compatible input. RESET going high
will pull GATE, SS, TIMER, SQTIMER low and the PWRGD
outputs high. The RESET pin has an internal glitch filter
that rejects any pulse < 20µs. After the reset of a latched
fault, the chip waits for the interlock conditions before
recovering as described in Interlock Conditions in the
Operation section.
SS (Pin 6/Pin 3): 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 the start-up cycle, the SS capacitor (CSS) is
ramped by a 28µA current source. The GATE pin is held
low until SS exceeds 20 • VOS = 0.2V. SS is internally
shunted by a 50k RSS which limits the SS pin voltage to
1.4V. This corresponds to an analog current limit SENSE
voltage of 60mV.
SEL (Pin 7/Pin 4): Soft-Start Mode Select. This is an
asynchronous TTL compatible input. SEL has an internal
pull-up of 20µA that will pull it high if it is floated. SEL
selects between two modes of SS ramp-up (see Applications Information, Soft-Start section).
SENSE (Pin 8/Pin 5): 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 (200µA + 8 • IDRN) TIMER
pull-up current. If SENSE exceeds VACL (60mV), the
analog current-limit amplifier pulls GATE down to regulate
the MOSFET current at VACL/RS. In the event of a catastrophic short-circuit, SENSE may overshoot VACL. 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.
VEE (Pins 9, 10/Pin 7): Negative Supply Voltage Input.
Connect this pin to the negative side of the power supply.
GATE (Pin 11/Pin 8): N-channel MOSFET Gate Drive
Output. This pin is pulled high by a 50µA current source.
GATE is pulled low by invalid conditions at VIN (UVLO),
undervoltage, overvoltage, during the initial timing cycle,
a circuit breaker fault time-out or the RESET pin going
high. GATE is actively servoed to control the fault current
as measured at SENSE. Compensation capacitor, CC, at
GATE stabilizes this loop. A comparator monitors GATE to
ensure that it is low before allowing an initial timing cycle,
then the GATE ramps up after an overvoltage event or
4253a-adjf
8
LTC4253A-ADJ
U
U
U
PI FU CTIO S
(SSOP/QFN)
restart after a current limit fault. During GATE start-up, a
second comparator detects GATE within 2.8V of VIN
before power good sequencing starts.
DRAIN (Pin 12/Pin 9): Drain Sense Input. Connecting an
external resistor, RD between this pin and the MOSFET’s
drain (VOUT) allows voltage sensing below 5V and current
feedback to TIMER. A comparator detects if DRAIN is
below 2.39V and together with the GATE high comparator,
starts the power good sequencing. If VOUT is above
VDRNCL, the DRAIN pin is clamped at approximately VDRNCL.
RD current is internally multiplied by 8 and added to
TIMER’s 200µA during a circuit breaker fault cycle. This
reduces the fault time and MOSFET heating.
OV/OVL (Pins 13, 14/Pins 10, 11): Overvoltage and
Overvoltage Low Inputs. The OV and OVL pins work
together to implement the overvoltage function. OVL and
OV must be tapped from an external resistive string across
the input supply such that VOVL ≥ VOV under all circumstances. As the input supply ramps up, the OV pin input is
multiplexed to the internal overvoltage comparator input.
If OV > 5.09V, GATE pulls low and the overvoltage comparator input is switched to OVL. When OVL returns below
5.08V, GATE start-up begins without an initial timing cycle
and the overvoltage comparator input is switched to OV.
In this way, an external resistor between OVL and OV can
set a low to high and high to low overvoltage threshold
hysteresis that will add to the internal 10mV hysteresis. A
1nF to 10nF capacitor at OVL prevents transients and
switching noise at both OVL and OV from causing glitches
at the GATE.
UV/UVL (Pins 15, 16/Pins 12, 13): Undervoltage and
Undervoltage Low Inputs. The UV and UVL pins work
together to implement the undervoltage function. UVL and
UV must be tapped from an external resistive string across
the input supply such that VUVL ≥ VUV under all circumstances. As the input supply ramps up, the UV pin input is
multiplexed to the internal undervoltage comparator input. If UV > 3.08V, an initial timing cycle is initiated
followed by GATE start-up and input to the undervoltage
comparator input is switched to UVL. When UVL returns
below 3.08V, PWRGD1 pulls high, both GATE and TIMER
pull low and input to the undervoltage comparator input is
switched to UV. In this way, an external resistor between
UVL and UV can set the low to high and high to low
undervoltage threshold hysteresis. A 1nF to 10nF capacitor at UVL prevents transients and switching noise at both
UVL and UV from causing glitches at the GATE pin.
TIMER (Pin 17/Pin 14): 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). These delays are adjustable by connecting
an appropriate capacitor to this pin.
SQTIMER (Pin 18/Pin 15): Sequencing Timer Input. The
sequencing timer provides a delay tSQT for the power good
sequencing. This delay is adjusted by connecting an
appropriate capacitor to this pin. If the SQTIMER capacitor
is omitted, the SQTIMER pin ramps from 0V to 4V in about
300µs.
EN3 (Pin 19/Pin 16): Power Good Status Output Three
Enable. This is a TTL compatible input that is used to
control the PWRGD3 output. When EN3 is driven low,
PWRGD3 will go high. When EN3 is driven high, PWRGD3
will go low provided PWRGD2 has been active for for more
than one power good sequence delay (tSQT). EN3 can be
used to control the power good sequence. This pin is
internally pulled low by a 120µA current source.
PWRGD3 (Pin 20/Pin 17): Power Good Status Output
Three. Power good sequence starts with DRAIN going
below 2.39V and GATE is within 2.8V of VIN. PWRGD3 will
latch active low after EN3 goes high and after one power
good sequence delay tSQT provided by the sequencing
timer from the time PWRGD2 goes low, whichever comes
later. PWRGD3 is reset by PWRGD1 going high or EN3
going low. This pin is internally pulled high by a 50µA
current source.
4253a-adjf
9
LTC4253A-ADJ
W
BLOCK DIAGRA
VIN
VIN
VIN
–
50µA
4V
5µA
VEE
PWRGD1
SQTIMER
DELAY
+
SQTIMER
VEE
EN2
VIN
–
120µA
50µA
VEE
+
PWRGD2
SQTIMER
DELAY
0.33V
VEE
–
DRAIN
VEE
VIN
EN3
+
VIN
2.39V
8×
120µA
50µA
1×
VEE
5V
1×
PWRGD3
VIN
SQTIMER
DELAY
1×
VEE
50µA
GATE
VEE
VIN
OVL
5.09V
OVIN
OV
UVL
UV
VIN
VEE
–
UVIN
–
3.08V
+
5µA 4V
–
–
OVD
+
+
–
2.8V
+
–
UVD
+
LOGIC
0.5V
VIN
200µA
+
FCL
+
–
+
–
TIMER
VEE
–
5µA
VEE
1V
VIN
200mV
+
VEE
+
28µA
ACL
–
SS
VOS = 10mV
+
–
VEE
47.5k
+
RSS
2.5k
VIN
VEE
SENSE
CB
–
+
–
VEE
20µA
50mV
VEE
4253A BD
SEL
RESET
VEE
4253a-adjf
10
LTC4253A-ADJ
U
OPERATIO
Hot Circuit Insertion
– 48RTN by way of a short connector pin that is the last to
mate during the insertion sequence.
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 LTC4253A-ADJ is designed to turn on a circuit board
supply in a controlled manner, allowing insertion or removal without glitches or connector damage.
Interlock Conditions
A start-up sequence commences once these “interlock”
conditions are met:
1. The input voltage VIN exceeds VLKO (UVLO)
2. The voltage at UV > VUVHI
3. The voltage at OVL < VOVLO
Initial Start-Up
4. The input voltage at RESET < 0.8V
The LTC4253A-ADJ resides on a removable circuit board
and controls the path between the connector and load or
power conversion circuitry with an external MOSFET switch.
Both inrush control and short-circuit protection are provided by the MOSFET.
5. The (SENSE – VEE) voltage < 50mV (VCB)
6. The voltage at SS is < 0.2V (20 • VOS)
7. The voltage on the TIMER capacitor (CT) is
< 1V (VTMRL)
A detailed schematic is shown in Figure 1. – 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/UVL/OV/OVL determines whether or not the
MOSFET should be turned on based upon internal high
accuracy thresholds and an external divider. UV/UVL/OV/
OVL does double duty by also monitoring whether or not
the connector is seated. The top of the divider detects
8. The voltage at GATE is < 0.5V (VGATEL)
The first four conditions are continuously monitored and
the latter four are checked prior to initial timing or GATE
ramp-up. Upon exiting an overvoltage condition, the
TIMER pin voltage requirement is inhibited. Details are
described in the Applications Information, Timing Waveforms section.
– 48V RTN
(LONG PIN)
RIN
2.5k
15k(1/4W)/6
RESET
(LONG PIN)
– 48V RTN
(SHORT PIN)
294k
1%
2.74k
1%
RESET
UV
POWER
CL
100µF MODULE 1
POWER
MODULE 2
EN
EN
POWER
MODULE 3
EN
†
†
†
PWRGD1
PWRGD2
OVL
C1
10nF
CSS 33nF
– 48V
(LONG PIN)
R8
5.6k
VIN
UVL
R3
2.1k 1%
R1
20k
1%
R7
5.6k
LTC4253A-ADJ
R4
2.37k 1%
R2
0.976k
1%
R6
5.6k
CIN
1µF
R5
+
VIN
OV
EN2
SS
DRAIN
SQTIMER
CSQ
0.1µF
PWRGD3
EN3
TIMER
SEL
CT
0.68µF
POWER
MODULE 2
OUTPUT
EN3
EN2
RD 1M
VIN
Q1
IRF530S
GATE
SENSE
VEE
CC
10nF
RC
10Ω
RS
0.02Ω
VIN
POWER
MODULE 1
OUTPUT
†
4253A F01
†
†MOC207
Figure 1. – 48V/2.5A Application with Operating Range from 43V to 82V
4253a-adjf
11
LTC4253A-ADJ
U
OPERATIO
If RESET < 0.8V occurs after the LTC4253A-ADJ comes
out of UVLO (interlock condition 1) and undervoltage
(interlock condition 2), GATE and SS are released without
an initial TIMER cycle once the other interlock conditions
are met (see Figure 13a). If not, TIMER begins the start-up
sequence by sourcing 5µA into CT. If VIN, UVL/UV or OVL/
OV falls out of range or RESET asserts, 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 50µA
(IGATE), charging the MOSFET gate and associated capacitance. The SS voltage ramp limits VSENSE to control the
inrush current. The SEL pin selects between two different
modes of SS ramp-up (refer to Applications Information,
Soft-Start section). SQTIMER starts its ramp-up when
GATE is within 2.8V of VIN and DRAIN is lower than VDRNL.
This sets off the power good sequence in which PWRGD1,
PWRGD2 and then PWRGD3 is subsequently pulled low
after a delay, adjustable through the SQTIMER capacitor
CSQ or by external control inputs EN2 and EN3. In this way,
external loads or power modules controlled by the three
PWRGD signals are turned on in a controlled manner
without overloading the power bus.
Two modes of operation are possible during the time the
MOSFET is first turned 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 LTC4253A-ADJ 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 LTC4253A-ADJ will ramp the output by sourcing
soft-start limited current into the load capacitance. If the
soft-start 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
LTC4253A-ADJ may shut down after one circuit breaker
delay time.
Board Removal
When the board is withdrawn from the card cage, the UVL/
UV/OVL/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; 60mV for an
analog current limit loop; and 200mV for a fast, feedforward
comparator which limits peak current in the event of a
catastrophic short-circuit.
If, due to an output overload, the voltage drop across RS
exceeds 50mV, TIMER sources 200µA into CT. CT eventually charges to a 4V threshold and the LTC4253A-ADJ
shuts off. If the overload goes away before CT reaches 4V
and SENSE measures less than 50mV, CT slowly discharges (5µA). In this way the LTC4253A-ADJ’s circuit
breaker function responds to low duty cycle overloads,
and accounts for the fast heating and slow cooling characteristic 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 (MOSFET drain-source voltage drop) 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 LTC4253A-ADJ will eventually shut down.
Low impedance failures on the load side of the LTC4253AADJ 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
4253a-adjf
12
LTC4253A-ADJ
U
OPERATIO
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 LTC4253A-ADJ when CT reaches 4V.
If CT reaches 4V, the LTC4253A-ADJ latches off with a 5µA
pull-up current source. The LTC4253A-ADJ circuit breaker
latch is reset by either pulling the RESET pin active high for
>20µs, pulling UVL/UV momentarily low, dropping the
input voltage VIN below the internal UVLO threshold or
pulsing TIMER momentarily low with a switch.
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 LTC4253A-ADJ
to “ride out” temporary overloads and disturbances that
could trip a simple current comparator and, in some
cases, blow a fuse.
4253a-adjf
13
LTC4253A-ADJ
U
W
U
U
APPLICATIO S I FOR ATIO
(Refer to Block Diagram)
SHUNT REGULATOR
A fast responding regulator shunts the LTC4253A-ADJ 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 three optocouplers used by
the PWRGD signals. Higher current through RIN results in
higher dissipation for RIN and LTC4253A-ADJ as well as
higher VIN noise. Alternative circuits are VIN with an NPN
buffer as in Figure 16, VIN driving base resistors of NPN
cascodes as in Figure 17 or VIN driving the gates of
MOSFET cascodes replacing the NPNs in Figure 17. An
alternative is a separate NPN buffer driving the optocoupler
as shown in Figure 16. Multiple 1/4W resistors can replace
a single higher power RIN resistor.
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
1
VIN
2
3
enabled; below (VLKO – VLKH) it is disabled and GATE is
pulled low. The UVLO function at VIN should not be
confused with the UVL/UV and OVL/OV pins. These are
completely separate functions.
UNDERVOLTAGE AND OVERVOLTAGE COMPARATORS
The undervoltage comparator has inputs multiplexed from
UVL and UV. When comparator output UVD is high, UV is
multiplexed to the comparator input UVIN. When UVD is
low, UVL is multiplexed to UVIN. By tapping UVL and UV
off a resistive string across the supply such as in the Typical Application, the undervoltage function is implemented
as shown in Figure 2a. During UVLO, UVD is forced high
so UV is multiplexed to UVIN. At time point 1, VIN ramps
past VLKO and the undervoltage comparator is enabled.
UVIN = UV is less than VUVHI (3.08V), so UVD is high and
the part is in undervoltage shutdown. At time point 2, UV
ramps past VUVHI (3.08V) and UVD goes low, bringing the
part out of undervoltage and switching UVL to UVIN. UVL
is tied to UVIN until time point 3 when UVL ramps past
VUVLO (3.08V) and UVD goes high, bringing the part into
undervoltage shutdown and switching UV to UVIN.
4
1
VIN
VLKO
38V
(UNDERVOLTAGE
RECOVERY VOLTAGE)
(–48V RTN)
SHORT PIN
36V
(UNDERVOLTAGE
SHUTDOWN
VOLTAGE)
71V
(OVERVOLTAGE
SHUTDOWN VOLTAGE)
(–48V RTN)
SHORT PIN
OVL
OV
UVD
OVD
OVIN
UV
4
69V
(OVERVOLTAGE
RECOVERY
VOLTAGE)
VOVLO
5.08V
VOVHI
5.09V
UVL
UV
UVL
3
VLKO
VUVLO
3.08V
VUVHI
3.08V
UVIN
2
OV
0VL
4253A F02
UVLO
UNDERVOLTAGE
SHUTDOWN
NORMAL OPERATION
(2a) Undervoltage
UNDERVOLTAGE
SHUTDOWN
UVLO
NORMAL
OPERATION
OVERVOLTAGE SHUTDOWN
(2b) Overvoltage
Figure 2. Undervoltage/Overvoltage Recovery and Shutdown (All Waveforms are Referenced to VEE)
14
NORMAL
OPERATION
4253a-adjf
LTC4253A-ADJ
U
W
U
U
APPLICATIO S I FOR ATIO
Figure 2b shows the implementation of the overvoltage
function of the Typical Application. During UVLO, OVD is
forced high so OVL is multiplexed to OVIN. At time point
1, the part exits UVLO and the overvoltage comparator is
enabled. OVIN = OVL is less than VOVLO (5.08V) so OVD
goes low, switching OV to OVIN and bringing the part to
Normal mode. At time point 2, OV ramps past VOVHI
(5.09V) and OVD goes high, switching OVL to OVIN as well
as turning on the internal 10mV hysteresis as the part goes
into overvoltage. OVL is tied to OVIN until time point 3
when OVL ramps past VOVLO (5.09V – 10mV = 5.08V) and
OVD goes low, bringing the part into Normal mode and
switching OV to OVIN.
The undervoltage (UV) comparator has no internal hysteresis to preserve the accuracy of the hysteresis set across
UVL/UV while the overvoltage (OV) comparator has an
internal low to high hysteresis of 10mV. This will add to the
hysteresis set across OVL/OV and provide some noise
immunity if OVL/OV is shorted together. Any implementation must ensure that VUVL ≥ VUV and VOVL ≥ VOV under all
conditions.
The various thresholds to note are:
UV low-to-high (VUVHI) = 3.08V
UVL high-to-low (VUVLO) = 3.08V
OV low-to-high (VOVHI) = 5.09V
OVL high-to-low (VOVLO) = 5.08V
Using these thresholds and an external resistive divider,
any required supply operating range can be implemented.
An example is shown in Figure 1 where the required typical
operating range is:
Undervoltage low-to-high (V48UVHI) = 43V
Undervoltage high-to-low (V48UVLO) = 39V
Overvoltage low-to-high (V48OVHI) = 82V
Overvoltage high-to-low (V48OVLO) = 78V
A quick check of the resistive divider ratios required at
UVL, UV, OVL and OV confirms that UVL is tapped
between R5/R4, UV is tapped between R4/R3, OVL is
tapped between R3/R2 and OV is tapped between R2/R1.
From Figure 1, by looking at the voltages at OV, OVL, UV
and UVL, the following equations are obtained:
RTOTAL V48OVHI
=
R1
VOVHI
where:
RTOTAL = (R1 + R2 + R3 + R4 + R5)
RTOTAL =
R1 • V48OVHI
VOVHI
(1a)
RTOTAL V48OVLO
=
R1 + R2
VOVLO
⎛ V
⎞
V
R2 = R1⎜ OVLO • 48OVHI ⎟ – R1
⎝ V48OVLO VOVHI ⎠
(1b)
RTOTAL
V
= 48UVHI
R1 + R2 + R3
VUVHI
⎛ V
⎞
V
R3 = R1⎜ UVHI • 48OVHI ⎟ – R1 – R2
⎝ V48UVHI VOVHI ⎠
(1c)
RTOTAL
V
= 48UVLO
R1 + R2 + R3 + R4
VUVLO
⎛ V
⎞
V
R4 = R1⎜ UVLO • 48OVHI ⎟ – R1 – R2 – R3
⎝ V48UVLO VOVHI ⎠
(1d)
Starting with a value of 20k for R1, Equation 1b gives R2
= 0.984k (use closest 1% standard value of 0.976k). Using
R1 = 20k and R2 = 0.976k, Equation 1c gives R3 = 2.103k
(use the closest 1% standard value of 2.1k). Using R1 =
20k, R2 = 0.976k and R3 = 2.1k, Equation 1d gives R4 =
2.37k (use closest 1% standard value of 2.37k). Using R1
= 20k, R2 = 0.976k, R3 = 2.1k and R4 = 2.37k in Equation
1a, R5 = 296.754k (use 1% standard values of 294k in
series with 2.74k).
The divider values shown set a standing current of slightly
more than 150µA and define an impedance at UVL/UV/
OVL/OV of approximately 20k. This impedance will work
with the hysteresis set across UVL/UV and OVL/OV to
provide noise immunity to the UV and OV comparators. If
4253a-adjf
15
LTC4253A-ADJ
U
W
U
U
APPLICATIO S I FOR ATIO
more noise immunity is desired, add a 1nF to 10nF filter
capacitor from UVL to VEE.
UV/OV OPERATION
1. 5µA slow charge; initial timing delay.
An undervoltage condition detected by the UV comparator
immediately shuts down the LTC4253A-ADJ, pulls GATE,
SS and TIMER low and resets the three latched PWRGD
signals high. Recovery from an undervoltage will initiate
an initial timing sequence if the other interlock conditions
are met.
An overvoltage condition is detected by the OV comparator and pulls GATE low, thereby shutting down the load,
but it will not reset the circuit breaker TIMER and PWRGD
flags. Returning from the overvoltage condition will
restart the GATE pin if all the interlock conditions except
TIMER are met. Only during the initial timing cycle does an
overvoltage condition have an effect of resetting TIMER.
The internal UVLO at VIN always overrides an overvoltage
or undervoltage.
DRAIN
Connecting an external resistor, RD, to this dual function
DRAIN pin allows VOUT (MOSFET drain-source voltage
drop) sensing without it being damaged by large voltage
transients. Below 5V, negligible pin leakage allows a
DRAIN low comparator to detect VOUT less than 2.39V
(VDRNL). This, together with the GATE low comparator,
starts the power good sequencing.
When VOUT > VDRNCL, the DRAIN pin is clamped at VDRNCL
and the current flowing in RD is given by:
IDRN ≈
VOUT − VDRNCL
RD
TIMER to provide timing for the LTC4253A-ADJ. Four
different charging and discharging modes are available at
TIMER:
2. (200µA + 8 • IDRN) fast charge; circuit breaker delay.
3. 5µA slow discharge; circuit breaker “cool-off.”
4. Low impedance switch; resets the TIMER capacitor
after an initial timing delay, in UVLO, in UV and in OV
during initial timing and when RESET is high.
For initial timing delay, the 5µA pull-up is used. The low
impedance switch is turned off and the 5µA current source
is enabled when the interlock conditions are met. CT
charges to 4V in a time period given by:
t=
4V • C T
5µA
(3)
When CT reaches VTMRH (4V), the low impedance switch
turns on and discharges CT. A GATE start-up cycle begins
and both SS and GATE outputs are released.
CIRCUIT BREAKER TIMER OPERATION
If the SENSE pin detects more than 50mV drop across
RS, the TIMER pin charges CT with (200µA + 8 • IDRN). If
CT charges to 4V, the GATE pin pulls low and the
LTC4253A-ADJ latches off. The LTC4253A-ADJ remains
latched off until the RESET pin is momentarily pulsed
high, the UVL/UV pin is momentarily pulsed low, the
TIMER pin 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:
(2)
This current is scaled up 8 times during a circuit breaker
fault before being added to the nominal 200µA. 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
t=
4V • C T
200µA + 8 • IDRN
(4)
If VOUT < 5V, an internal PMOS isolates DRAIN pin leakage
current and this makes IDRN = 0 in Equation 4. If VOUT is
above VDRNCL during the circuit breaker fault period, the
charging of CT is accelerated by 8 • IDRN of Equation 2.
Intermittent overloads may exceed the 50mV threshold at
SENSE but, if their duration is sufficiently short, TIMER
will not reach 4V and the LTC4253A-ADJ will not shut the
4253a-adjf
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external MOSFET off. To handle this situation, the TIMER
discharges CT slowly with a 5µA pull-down whenever the
SENSE voltage is less than 50mV. Therefore any intermittent overload with VOUT < 5V and an aggregate duty cycle
of more than 2.5% will eventually trip the circuit breaker
and shut down the LTC4253A-ADJ. Figure 3 shows the
circuit breaker response time in seconds normalized to
1µF. The asymmetric charging and discharging of CT is a
fair gauge of MOSFET heating.
The normalized circuit response time is estimated by:
t
4
for D > 2.5% (5)
=
CT (µF ) (205 + 8 • IDRN ) • D − 5
[
]
10
NORMALIZED RESPONSE TIME (s/µF)
IDRN = 0µA
4
t
=
CT(µF) (205 + 8 • IDRN) • D – 5
1
tSQT. When PWRGD2 successfully pulls low, SQTIMER
ramps up on another delay cycle. PWRGD3 asserts when
EN2 and EN3 go high and PWRGD2 has asserted for more
than one tSQT.
All three PWRGD signals are reset in UVLO, in UV condition, if RESET is high or when CT charges up to 4V. In
addition, PWRGD2 is reset by EN2 going low. PWRGD3 is
reset by EN2 or EN3 going low. An overvoltage condition
has no effect on the PWRGD flags. A 50µA current pulls
each PWRGD pin high when reset. As power modules
signal common are different from PWRGD, optoisolation
is recommended. These three pins can sink an optodiode
current. Figure 17 shows an NPN configuration for the
PWRGD interface. A limiting base resistor should be used
for each NPN and the module enable input should have
protection from negative bias current. Figure 17 also
shows how the LTC4253A-ADJ can be used to sequence
four power modules.
SOFT-START
Soft-start is effective in limiting the inrush current during
GATE start-up. From the Block Diagram, the internal SS
circuit consists of a current ISS (28µA) feeding into a
resistive divider. The resistive divider (47.5k/2.5k) scales
VSS (t) down by 20 times to give the analog current limit
threshold:
0.1
0.01
0
20
40
60
80
FAULT DUTY CYCLE, D (%)
100
4253A F03
VACL ( t) =
Figure 3. Circuit Breaker Response Time
POWER GOOD SEQUENCING
After the initial TIMER cycle, GATE ramps up to turn on the
external MOSFET which in turn pulls DRAIN low. When
GATE is within 2.8V of VIN and DRAIN is lower than VDRNL,
the power good sequence starts off a 5µA pull-up on the
SQTIMER pin which ramps up until it reaches the 4V
threshold then pulls low. When the SQTIMER pin floats,
this delay tSQT is about 300µs. Connecting an external
capacitor CSQ from SQTIMER to VEE modifies the delay to:
tSQT =
4V • C SQ
5µA
(6)
PWRGD1 asserts low after one tSQT and SQTIMER ramps
up on another delay cycle. PWRGD2 asserts when EN2
goes high and PWRGD1 has asserted for more than one
VSS( t)
– VOS
20
(7)
After the initial timing cycle, SS ramps up from 0V to 1.4V
(28µA • 50k), ramping VACL (t) from –10mV to 60mV. The
ACL amplifier will then limit the inrush current to VACL (t)/
RS. The offset voltage, VOS (10mV) ensures CSS is sufficiently discharged and the ACL amplifier is in current limit
mode before GATE start-up.
There are two modes of SS ramp up. If SEL is set high and
the SS pin floats, an internal current source ramps SS from
0V to 1.4V in about 200µs. Connecting an external capacitor, CSS, from SS to ground modifies the ramp to approximate an RC response of:
–t ⎞
⎛
VSS( t) ≈ VSS ⎜ 1 − e RSSCSS ⎟
⎜
⎟
⎝
⎠
(8)
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When VACL (t) exceeds VSENSE, the ACL amplifier exits
current limit mode and releases its pull-down on GATE. VSS
(t) = 20 • (VOS + VSENSE) from Equation 7. So when VSS (t)
> 20 • VOS = 0.2V (since VSENSE = 0V), GATE starts to ramp
up and SS continues to ramp up. When GATE clears the
threshold of the external FET and inrush current starts flowing, VACL (t) = (VSS (t)/20 – VOS) will have a positive offset
from zero. VSENSE will show an initial jump to clear this offset
before going into analog current limit (Figure 4a).
If SEL is set low during SS ramp-up, VSS is servoed when
it exceeds 20 • VOS = 0.2V and GATE starts its ramp-up.
VSS is servoed at a voltage that is just above 20 • VOS to
keep the ACL amplifier off and GATE ramping up freely. Once
GATE clears the threshold of the external FET, inrush current starts flowing and VSENSE will jump above VACL (t). This
will engage the ACL amplifier and mask off VSS servo so
V SS continues its RC ramp-up. In this way, the
LTC4253A-ADJ enters analog current limit with VACL (t) =
(VSS (t)/20 – VOS) ramping up from close to zero. The
resultant inrush current profile presents a smooth ramp up
from zero (Figure 4b). If there is little inrush current so the
LTC4253A-ADJ does not enter current limit, VSS servo will
be masked off when DRAIN goes below 2.39V (VDRNL) and
latched off when GATE goes within 2.8V of VIN (VGATEH).
A minimum CSS of 5nF is required for the stability of the
VSS servo loop.
SS is discharged low during UVLO, UV, OV, during the
initial timing cycle, a latched circuit breaker fault or the
RESET pin going high.
GATE
GATE is pulled low to VEE under any of the following
conditions: in UVLO, when RESET pulls high, in an
undervoltage condition, in an overvoltage condition, during the initial timing cycle or a latched circuit breaker fault.
When GATE turns on, a 50µA 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,
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; the GATE
high comparator looks for < 2.8V relative to VIN and,
together with DRAIN low comparator, starts power good
sequencing during GATE start-up.
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
GATE
10V
GATE
10V
SS
1V
SS
1V
SENSE
50mV
SENSE
50mV
VOUT
50V
VOUT
50V
1ms/DIV
4253A F04a
(4a) SEL Set High
4253A F04b
(4b) SEL Set Low
Figure 4. Two Modes of SS Ramp Up
18
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SENSE exceeds 50mV, the CB comparator activates the
200µA TIMER pull-up. At 60mV 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 4),
the LTC4253A-ADJ 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.
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.
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 5 trace 1, can
rob charge from output capacitors on the adjacent card.
When the faulty card shuts down, current flows in to
refresh the capacitors. If LTC4253A-ADJs are used by the
other cards, they respond by limiting the inrush current to
a value of VACL/RS. If CT is sized correctly, the capacitors
will recharge long before CT times out.
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 datasheet for safe operating area
and effective transient thermal impedance curves.
SHORT-CIRCUIT OPERATION
Circuit behavior arising from a load side low impedance
short is shown in Figure 5. Initially the current overshoots
the analog 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 60mV/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 60mV/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, the
PWRGD signals pull 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
SUPPLY RING OWING
TO MOSFET TURN-OFF
–48V RTN
50V
SENSE
200mV
SUPPLY RING OWING
TO CURRENT OVERSHOOT
TRACE 1
ONSET OF OUTPUT
SHORT CIRCUIT
TRACE 2
FAST CURRENT LIMIT
GATE
10V
ANALOG CURRENT LIMIT
TIMER
5V
CTIMER RAMP
0.5ms/DIV
TRACE 3
TRACE 4
LATCH OFF
4253A F05
Figure 5. Output Short-Circuit Behavior of LTC4253A-ADJ
4253a-adjf
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MOSFET selection is a 3-step process by assuming the
absense of 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 shortcircuit current and maximum input voltage, defines an
operating point that is checked against the MOSFET’s SOA
curve.
Approximating a linear charging rate, IDRN drops from
IDRN(MAX) to zero, the IDRN component in Equation 4 can
be approximated with 0.5 • IDRN(MAX). Rearranging the
equation, TIMER capacitor CT is given by:
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:
Returning to Equation 4, 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.
RS =
VCB(MIN)
IL(MAX)
(9)
where VCB(MIN) = 45mV represents the guaranteed minimum circuit breaker threshold.
During the initial charging process, the LTC4253A-ADJ
may operate the MOSFET in current limit, forcing (VACL)
between 54mV to 66mV across RS. The minimum inrush
current is given by:
IINRUSH(MIN) =
VACL(MIN)
RS
(10)
Maximum short-circuit current limit is calculated using
the maximum VSENSE. This gives
ISHORTCIRCUIT(MAX) =
VACL(MAX)
RS
(11)
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 • VSUPPLY(MAX)
=
I
IINRUSH(MIN)
(12)
The maximum current flowing in the DRAIN pin is given by:
IDRN(MAX) =
20
VSUPPLY(MAX) − VDRNCL
RD
(13)
CT =
tCL(CHARGE) • (200µA + 4 • IDRN(MAX) )
4V
(14)
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 9 gives
RS = 45mΩ; use RS = 40mΩ for more margin. Equation 14
gives CT = 619nF. To account for errors in RS, CT, TIMER
current (200µA), 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 = 1µF.
If a short-circuit occurs, a current of up to
66mV/45mΩ = 1.65A will flow in the MOSFET for 9.1ms
as dictated by CT = 1µF in Equation 4. The MOSFET must
be selected based on this criterion. The IRF530S can
handle 100V and 2A for 22.5ms 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 overconservative but simple approach begins with the
maximum circuit breaker current, given by:
ICB(MAX) =
VCB(MAX)
RS
(15)
From the SOA curves of a prospective MOSFET, determine
the time allowed, tSOA(MAX). CSS is given by:
CSS =
tSOA(MAX)
2.48 • RSS
(16)
In the above example, 55mV/40mΩ gives 1.375A. tSOA for
the IRF530S is 47.6ms. From Equation 16, CSS = 384nF.
4253a-adjf
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Actual board evaluation showed that CSS = 100nF was
appropriate. The ratio (RSS • CSS) to tCL(CHARGE) is a good
gauge as large ratios may result in the time-out period
expiring prematurely. This gauge is determined empirically with board level evaluation.
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.
To summarize the design flow, consider the application
shown in Figure 1. It was designed for 80W and CL = 100µF.
Calculate maximum load current: 80W/43V = 1.86A;
allowing for 83% converter efficiency, IIN(MAX) = 2.2A.
Calculate RS: from Equation 9 RS = 20mΩ.
Calculate I SHORT-CIRCUIT(MAX) : from Equation 11
ISHORTCIRCUIT(MAX) = 3.3A.
COMPENSATION CAPACITOR CC (nF)
50
SUMMARY OF DESIGN FLOW
NTY100N10
45
40
35
30
25
IRF3710
20
IRF540S
15
10
5
IRF740
IRF530S
0
0
2000
Select a MOSFET that can handle 3.3A at 71V: IRF530S.
Calculate CT: from Equation 14 CT = 383nF. Select
CT = 680nF, which gives the circuit breaker time-out
period tMAX = 5.9ms.
Consult MOSFET SOA curves: the IRF530S can handle
3.3A at 100V for 8.3ms, so it is safe to use in this
application.
Calculate CSS: using Equations 15 and 16 select CSS = 33nF.
FREQUENCY COMPENSATION
The LTC4253A-ADJ typical frequency compensation network for the analog current limit loop is a series RC (10Ω)
and CC connected from GATE to VEE. Figure 6 depicts the
relationship between the compensation capacitor CC and
the MOSFET’s CISS. The line in Figure 6 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.
6000
4000
MOSFET CISS (pF)
8000
4253A F06
Figure 6. Recommended Compensation
Capacitor CC vs MOSFET CISS
SENSE RESISTOR CONSIDERATIONS
For proper circuit breaker operation, Kelvin-sense PCB
connections between the sense resistor and the LTC4253AADJ’s VEE and SENSE pins are strongly recommended.
The drawing in Figure 7 illustrates the correct way of
making connections between the LTC4253A-ADJ 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.
CURRENT FLOW
FROM LOAD
CURRENT FLOW
TO –48V BACKPLANE
SENSE RESISTOR
TRACK WIDTH W:
0.03" PER AMP
ON 1 OZ COPPER
W
4253A F07
As seen in Figure 5, at the onset of a short-circuit event, the
input supply voltage can ring dramatically due to series
inductance. If this voltage avalanches the MOSFET, current continues to flow through the MOSFET to the output.
TO
SENSE
TO
VEE
Figure 7. Making PCB Connections to the Sense Resistor
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TIMING WAVEFORMS
time point 1, the supply ramps up, together with UV/OV,
VOUT and DRAIN. VIN and the PWRGD signals 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, OVL < VOVLO, RESET < 0.8V, GATE < VGATEL,
SENSE < VCB, SS < 20 • VOS, and TIMER < VTMRL. When
System Power-Up
Figure 8 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
VIN CLEARS VLKO, CHECK UV > VUVHI, OVL < VOVLO, RESET < 0.8V, 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
C
7 89 A B
D
E
GND – VEE OR
(–48RTN) – (–48V)
UVL
UV
VUVHI
VOVLO
OVL
OV
VIN
VLKO
VTMRH
200µA + 8 • IDRN
5µA
TIMER
5µA
VTMRL
50µA
GATE
SS
VIN – VGATEH
50µA
VGATEL
5µA
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
VACL
SENSE
VCB
VOUT
VDRNCL
DRAIN
VDRNL
50µA
PWRGD1
PWRGD2
PWRGD3
VSQTMRH
5µA
SQTIMER
5µA
VSQTMRL
VIH
EN2
VIH
EN3
INITIAL TIMING
GATE
START-UP
4253A F08
Figure 8. System Power-Up Timing (All Waveforms are Referenced to VEE)
22
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all conditions are met, initial timing starts and the TIMER
capacitor is charged by a 5µA 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 the GATE startup cycle begins. SS ramps up as dictated by RSS • CSS (as
in Equation 8); GATE is held low by the analog current limit
(ACL) amplifier until SS crosses 20 • VOS. Upon releasing
GATE, 50µA sources into the external MOSFET gate and
compensation network. When the GATE voltage reaches
the MOSFET’s threshold, current flows into the load capacitor at time point 5. At time point 6, load current
reaches 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, circuit breaker TIMER
activates. The TIMER capacitor, CT is charged by a
(200µA + 8 • IDRN) current pull-up. As the load capacitor
nears full charge, load current begins to decline. 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 ends, followed
by a 5µA discharge cycle (cool-off). The duration between
time points 7 and 9 must be shorter than one circuit
breaker delay to avoid fault time-out during GATE rampup. At time point B, GATE reaches its maximum voltage as
determined by VIN. At time point A, GATE ramps past
VGATEH and SQTIMER starts its ramp-up to 4V. PWRGD1
pulls low at time point C after one tSQT from time point A,
setting off the second SQTIMER ramp up. Having satisfied
the requirement that PWRGD1 is low for more than one
tSQT, PWRGD2 pulls low after EN2 pulls high above the VIH
threshold at time point D. This sets off the third SQTIMER
ramp-up. Having satisfied the requirement that PWRGD2
is low for more than one tSQT, PWRGD3 pulls low after EN3
pulls high at time point E.
Live Insertion with Short Pin Control of UV/OV
In the example shown in Figure 9, 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 LTC4253A-ADJ
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 UV > VUVHI. In addition, the internal logic checks for OV < VOVHI, RESET < 0.8V, GATE <
VGATEL, SENSE < VCB, SS < 20 • VOS and TIMER < VTMRL.
When all conditions are met, initial timing starts and the
TIMER capacitor is charged by a 5µA current source pullup. 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 < VCB and SS < 20 • VOS must be satisfied before
the 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,
50µA 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 SS control level and the analog current limit loop
activates. Between time points 6 and 8, the GATE voltage
is servoed and 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 (200µA + 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 ends, followed by a 5µA discharge
current source (cool-off). When GATE ramps past VGATEH
threshold at time point A, SQTIMER starts its ramp-up.
PWRGD1 pulls low at time point C after one tSQT from time
4253a-adjf
23
LTC4253A-ADJ
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APPLICATIO S I FOR ATIO
point A, setting off the second SQTIMER ramp-up. PWRGD2
pulls low at time point D when EN2 is high and PWRGD1
is low for more than one tSQT. PWRGD3 pulls low at time
point E when EN2 and EN3 is high and PWRGD2 is low for
more than one tSQT. At time point B, GATE reaches its maximum voltage as determined by VIN.
Undervoltage Timing
In Figure 10 when the UVL pin drops below VUVLO (time
point 1), the LTC4253A-ADJ shuts down with TIMER, SS
and GATE pulled 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 time cycle begins followed by a start-up cycle.
UV CLEARS VUVHI, CHECK OV < VOVHI, RESET < 0.8V, GATE < VGATEL, SENSE < VCB, SS < 20 • VOS AND TIMER < VTMRL
TIMER CLEARS VTMRL, CHECK GATE < VGATEL, SENSE < VCB AND SS < 20 • VOS
1
2
3 456
7
89 A B
C
D
E
GND – VEE OR
(–48RTN) – (–48V)
UVL
UV
VUVHI
VOVHI
OVL
OV
VIN
VLKO
VTMRH
200µA + 8 • IDRN
5µA
TIMER
5µA
VTMRL
50µA
GATE
SS
50µA
VGATEL
5µA
VIN – VGATEH
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
VACL
VCB
SENSE
VOUT
VDRNCL
DRAIN
VDRNL
50µA
PWRGD1
PWRGD2
PWRGD3
VSQTMRH
5µA
SQTIMER
5µA
VSQTMRL
EN2
EN3
INITIAL TIMING
GATE
START-UP
4253A F09
Figure 9. Power-Up Timing with a Short Pin (All Waveforms are Referenced to VEE)
24
4253a-adjf
LTC4253A-ADJ
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APPLICATIO S I FOR ATIO
UVL DROPS BELOW VUVLO. GATE, SS AND TIMER ARE PULLED DOWN, PWRGD RELEASES
UV CLEARS VUVHI, CHECK OV CONDITION, RESET < 0.8V, 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
89 A B
C
D
E
UVL
UV
VUVLO
VUVHI
VTMRH
5µA
TIMER
200µA + 8 • IDRN
5µA
VTMRL
5µA
50µA
GATE
VIN – VGATEH
50µA
VGATEL
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
SS
VACL
SENSE
VCB
VDRNCL
DRAIN
VDRNL
50µA
PWRGD1
PWRGD2
PWRGD3
VSQTMRH
5µA
SQTIMER
5µA
VSQTMRL
EN2
EN3
INITIAL TIMING
GATE
START-UP
4253 F10
Figure 10. Undervoltage Timing (All Waveforms are Referenced to VEE)
VIN Undervoltage Lockout Timing
Overvoltage Timing
VIN undervoltage lockout comparator, UVLO has a similar
timing behavior as the UV pin timing except it looks at 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 undervotlage lockout,
the UV and OV comparators are enabled.
During normal operation, if the OV pin exceeds VOVHI as
shown at time point 1 of Figure 11, the TIMER and PWRGD
status are unaffected; SS and GATE pull down; load
disconnects. At time point 2, OVL recovers and drops
below the VOVLO threshold; GATE start-up begins. If the
overvoltage glitch is long enough to deplete the load
capacitor, time points 4 through 7 may occur.
4253a-adjf
25
LTC4253A-ADJ
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APPLICATIO S I FOR ATIO
OV OVERSHOOTS VOVHI. GATE AND SS ARE PULLED DOWN, PWRGD SIGNALS AND TIMER ARE UNAFFECTED
OVL DROPS BELOW VOVLO, CHECK GATE < VGATEL, SENSE < VCB AND SS < 20 • VOS
1
2 34
VOVHI
5
67 8 9
VOVLO
OVL
OV
VTMRH
200µA + 8 • IDRN
TIMER
5µA
5µA
50µA
GATE
VGATEL
VIN – VGATEH
50µA
20 • (VACL + VOS)
SS
20 • (VCB + VOS)
20 • VOS
VACL
VCB
SENSE
4253A F11
GATE
START-UP
Figure 11. Overvoltage Timing (All Waveforms are Referenced to VEE)
Circuit Breaker Timing
In Figure 12a, the TIMER capacitor charges at 200µA if the
SENSE pin exceeds VCB but VDRN is less than 5V. If the
SENSE pin returns below VCB before TIMER reaches the
VTMRH threshold, TIMER is discharged by 5µA. In
Figure 12b, when TIMER exceeds VTMRH, GATE pulls
down immediately and the chip shuts down. In Figure 12c,
multiple momentary faults cause the TIMER capacitor to
integrate and reach VTMRH followed by GATE pull down
and the chip shuts down. During chip shutdown,
LTC4253A-ADJ latches TIMER high with a 5µA pull-up
current source.
Resetting a Fault Latch
A latched circuit breaker fault of the LTC4253A-ADJ has
the benefit of a long cooling time. The latched fault can be
reset by pulsing the RESET pin high for >20µs to overcome the internal glitch filter as shown in Figure 13b.
After the RESET pulse, SS and GATE ramp up without an
initial timing cycle provided the interlock conditions are
satisfied.
Alternative methods of reset include using an external
switch to pulse the UVL/UV pin below VUVLO or the VIN pin
below (VLKO – VLKH). Pulling the TIMER pin below VTMRL
and the SS pin to 0V then simultaneously releasing them
also achieves a reset. An initial timing cycle is generated
for reset by pulsing the UVL/UV pin or VIN pin, while no
initial timing cycle is generated for reset by pulsing of the
TIMER and SS pins.
Using Reset as an ON/OFF Switch
The asynchronous RESET pin can be used as an on/off
function to cut off supply to the external power modules or
loads controlled by the chip. Pulling RESET high will pull
GATE, SS, TIMER and SQTIMER low and the PWRGD
signal high. The supply is fully cut off if the RESET pulse
is maintained wide enough to overcome the internal 20µs
glitch filter. As long as RESET is high, GATE, SS, TIMER
and SQTIMER are strapped to VEE and the supply is cut off.
When RESET is released, the chip waits for the interlock
conditions before recovering as described in the Operation, Interlock Conditions section and Figure 13c.
4253a-adjf
26
LTC4253A-ADJ
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APPLICATIO S I FOR ATIO
CB TIMES-OUT
1
2
VTMRH
200µA + 8 • IDRN
TIMER
5µA
1
VTMRH
200µA + 8 • IDRN
TIMER
CB TIMES-OUT
2
1
2
3
VTMRH
200µA + 8 • IDRN
TIMER
5µA
GATE
GATE
GATE
SS
SS
SS
SENSE
VACL
VACL
VCB
VCB
SENSE
VACL
VCB
SENSE
VOUT
VOUT
DRAIN
DRAIN
DRAIN
PWRGD1
PWRGD1
PWRGD1
VOUT
VDRNCL
CB FAULT
VDRNCL
CB FAULT
(12a) Momentary Circuit Breaker Fault
4
(12b) Circuit Breaker Time-Out
CB FAULT
CB FAULT
4253A F12
(12c) Multiple Circuit Breaker Fault
Figure 12. Circuit Breaker Timing Behavior (All Waveforms are Referenced to VEE)
Analog Current Limit and Fast Current Limit
In Figure 14a, 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 14b, 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 200µA. This accelerated TIMER current of
(200µA + 8 • IDRN) produces a shorter circuit breaker fault
delay. Careful selection of CT, RD and MOSFET helps
prevent SOA damage in a low impedance fault condition.
Soft-Start
If SEL is floated high and the SS pin is not connected, this
pin defaults to a linear voltage ramp, from 0V to 1.4V in
about 200µs at GATE start-up, as shown in Figure 15a. 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 8), as shown in Figure 15b. 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 and 2), by
the OVL pin falling below the VOVLO threshold after an OV
condition, or by the RESET pin falling < 0.8V after a Reset
condition. When the SS pin is below 0.2V, the analog
current limit amplifier keeps GATE low. Above 0.2V, GATE
is released and 50µA 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 current begins
4253a-adjf
27
RESET
UV
UVL
VIN
PWRGD1
DRAIN
SENSE
SS
GATE
TIMER
5µA
SS
GATE
TIMER
1
VGATEL
20µs
VTMRL
VTMRH
VUVHI
VDRNL
tSQT
VDRNCL
VIL
tSQT
(13b) Reset of LTC4253-ADJ’s
Latched Fault
RESET PULSE
WIDTH MUST BE >20µs
TO OVERCOME
INTERNAL GLITCH FILTER
VIH
VUVHI
VLKO
50µA
VDRNCL
VDRNL
5µA
RESET
UVL
UV
VIN
PWRGD1
DRAIN
SENSE
SS
GATE
TIMER
Figure 13. Reset Functions (All Waveforms are Referenced to VEE)
RESET
UVL
UV
VIN
PWRGD1
DRAIN
VCB
VCB
SENSE
5µA
VIN – VGATEH
VACL
20 • VOS
50µA
67 8 9
VACL
(13a) Reset Forcing Start-Up
Without Initial TIMER Cycle
VIL
VLKO
50µA
20 • VOS
5
200µA + 8 • IDRN
2 34
50µA
20 • (VCB + VOS)
VIN – VGATEH
5µA
5µA
20 • (VACL + VOS)
50µA
56 7 8
20 • (VCB + VOS)
50µA
200µA + 8 • IDRN
4
20 • (VACL + VOS)
VGATEL
VTMRL
1 23
RESET < VIL, CHECK UVLO, UV, OV CONDITION, GATE < VGATEL,
SENSE < VCB, SS < 20 • VOS AND TIMER < VTMRL
20 • (VCB + VOS)
50µA
20µs
VUVHI
VLKO
VIH
50µA
20 • VOS
5
VDRNL
tSQT
VDRNCL
VCB
VACL
VIN – VGATEH
5µA
(13c) Reset as an ON/OFF Switch
VIL
67 8 9
50µA
200µA + 8 • IDRN
20 • (VACL + VOS)
VGATEL
VTMRL
2 34
RESET PULSE
WIDTH MUST BE >20µs
TO OVERCOME
INTERNAL GLITCH FILTER
1
4253A F13
5µA
RESET < VIL, CHECK UVLO, UV, OV CONDITION, GATE < VGATEL,
SENSE < VCB, SS < 20 • VOS AND TIMER < VTMRL
U
U
28
W
LATCHED TIMER RESET BY
RESET PULLING HIGH
APPLICATIO S I FOR ATIO
U
RESET < VIL, CHECK UVLO, UV, OV CONDITION, GATE < VGATEL,
SENSE < VCB, SS < 20 • VOS AND TIMER < VTMRL
LTC4253A-ADJ
4253a-adjf
LTC4253A-ADJ
U
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APPLICATIO S I FOR ATIO
CB TIMES-OUT
12
34
1
VTMRH
200µA + 8 • IDRN
TIMER
2
VTMRH
200µA + 8 • IDRN
TIMER
5µA
GATE
GATE
SS
VACL
SENSE
VFCL
SENSE
VCB
VOUT
VOUT
DRAIN
DRAIN
PWRGD1
PWRGD1
VACL
VCB
VDRNCL
4253A F14
(14b) Fast Current Limit Fault
(14a) Analog Current Limit Fault
Figure 14. Current Limit Behavior (All Waveforms are Referenced to VEE)
END OF INITIAL TIMING CYCLE
12 3 4 5 6 7
7a
END OF INITIAL TIMING CYCLE
8 9
10
11
12 3 4 56
VTMRH
7
8 9
5µA
5µA
7
8 9
GATE
50µA
5µA
GATE
VIN – VGATEH
VGS(th)
50µA
20 • (VACL + VOS)
SS
20 • (VCB + VOS)
20 • VOS
VACL
SS
VCB
VDRNCL
VDRNL
20 • (VCB + VOS)
20 • VOS
VACL
SENSE
50µA
20 • (VACL + VOS)
20 • (VCB + VOS)
20 • VOS
VCB
11
50µA
VIN – VGATEH
VGS(th)
10
200µA + 8 • IDRN
50µA
VIN – VGATEH
20 • (VACL + VOS)
DRAIN
TIMER
VTMRL
50µA
SENSE
12 3 4 56
VTMRL
GATE
SS
11
VTMRH
200µA + 8 • IDRN
TIMER
VTMRL
VGS(th)
10
VTMRH
200µA + 8 • IDRN
TIMER
END OF INITIAL TIMING CYCLE
VACL
SENSE
VDRNCL
DRAIN
VDRNL
VCB
VDRNCL
DRAIN
VDRNL
4253A F15
(15a) Without External CSS
(15b) With External CSS
(15c) With SEL = Low and External CSS
Figure 15. Soft-Start Timing (All Waveforms are Referenced to VEE)
to decline below VACL(t). The current limit loop shuts off
and GATE releases at time point 8. At time point 9, SENSE
voltage falls below VCB and TIMER deactivates.
A third Soft-Start mode is shown in Figure 15c. The SEL
pin is tied low and a soft-start capacitor, CSS, is connected
to the SS pin. The behavior is similar to Figure 15b until
time point 4 when GATE is released and starts to ramp up.
Instead of continuing its ramp-up as in mode two, the SS
pin voltage is servoed at a voltage that is just above 0.2V
(20 • VOS) to keep the current limit amplifier off and the
GATE ramping up freely. At time point 5, GATE ramps past
the external MOSFET’s threshold and inrush current starts
to flow. At time point 6, VSENSE goes above VACL (t) and the
servo on SS is released while the GATE voltage is controlled by the current limit amplifier with VACL (t) ramping
up from near zero. The result is a current profile (as
4253a-adjf
29
LTC4253A-ADJ
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APPLICATIO S I FOR ATIO
reflected in VSENSE) that ramps up smoothly from near
zero. VSENSE does not show a large kink as in Figure 15b
when VACL (t) already has a substantial offset from zero at
time point 6. SEL tied low chooses this SS servo mode
during soft-start while SEL set high allows the SS pin to do
an open-loop ramp-up as in Figures 15a and 15b. The
stability of the SS servo loop requires a CSS > 5nF.
R5 are selected by:
Large values of CSS can cause premature circuit breaker
time-out as VACL(t) may marginally 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 a large CSS value is that 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.
2
VSUPPLY(MIN) + VSUPPLY(MAX) )
(
POWER(MAX) =
R5
VCB
=
R4 VSUPPLY(MAX)
(17)
If R5 is 22Ω, then R4 is 31.6k. The peak circuit breaker
power limit is:
4 • VSUPPLY(MIN) • VSUPPLY(MAX) (18)
• POWER AT VSUPPLY(MIN)
= 1.064 • POWER AT VSUPPLY(MIN)
when VSUPPLY = 0.5 • (VSUPPLY(MIN) + VSUPPLY(MAX))
= 57V
Power Limit Circuit Breaker
The peak power at the fault current limit occurs at the
supply overvoltage threshold. The fault current limited
power is:
Figure 16 shows the LTC4253A-ADJ in a power limit
circuit breaking application. The SENSE pin is modulated
by board voltage VSUPPLY. The zener voltage, VZ of D1, is
set to be the same as the lowest operating voltage,
VSUPPLY(MIN) = 43V. If the goal is to have the high supply
operating voltage, VSUPPLY(MAX) = 71V give the same
power as available at VSUPPLY(MIN), then resistors R4 and
POWER(FAULT) =
( VSUPPLY ) • ⎡V
⎢
⎣
RS
ACL
− ( VSUPPLY − VZ ) •
R5 ⎤
R4 ⎥⎦
(19)
– 48V RTN
(LONG PIN)
RIN
10k
20k(1/4W)/2
RESET
(LONG PIN)
255k
1%
RESET
+
C3
0.1µF
VIN1
R6
2.2k
R7
2.2k
POWER
MODULE 1
R8
2.2k
POWER
MODULE 2
EN
VIN
LTC4253A-ADJ
EN
†
UVL
C1
10nF
†
†
PWRGD1
PWRGD2
UV
CSS 33nF
PWRGD3
EN3
OV
EN2
SS
DRAIN
SQTIMER
CSQ
0.1µF
LOAD 3
EN
R3
OVL
– 48V
(LONG PIN)
C2
100µF
Q2
FZT857
D1
BZV85C43
2k
1%
R1
20k
1%
R9 22k
CIN
1µF
– 48V RTN
(SHORT PIN)
R2
2.05k
1%
R4
31.6k
TIMER
SEL
CT
0.68µF
EN2
RD 1M
VIN1
Q1
IRF530S
GATE
SENSE
VEE
POWER
MODULE 2
OUTPUT
EN3
R5
22Ω
CC
10nF
RC
10Ω
RS
0.02Ω
VIN1
POWER
MODULE 1
OUTPUT
†
4253A F16
†
†MOC207
Figure 16. Power Limit Circuit Breaker Application
4253a-adjf
30
LTC4253A-ADJ
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PACKAGE DESCRIPTIO
GN Package
20-Lead Plastic SSOP (Narrow .150 Inch)
(Reference LTC DWG # 05-08-1641)
.337 – .344*
(8.560 – 8.738)
.045 ±.005
20 19 18 17 16 15 14 13 12
.254 MIN
.150 – .165
.0165 ± .0015
11
.229 – .244
(5.817 – 6.198)
.058
(1.473)
REF
.150 – .157**
(3.810 – 3.988)
.0250 BSC
1
RECOMMENDED SOLDER PAD LAYOUT
.015 ± .004
× 45°
(0.38 ± 0.10)
.0075 – .0098
(0.19 – 0.25)
2 3
4
5 6
7
8
9 10
.0532 – .0688
(1.35 – 1.75)
.004 – .0098
(0.102 – 0.249)
0° – 8° TYP
.016 – .050
(0.406 – 1.270)
.0250
(0.635)
BSC
.008 – .012
(0.203 – 0.305)
TYP
NOTE:
1. CONTROLLING DIMENSION: INCHES
INCHES
2. DIMENSIONS ARE IN
(MILLIMETERS)
GN20 (SSOP) 0204
3. DRAWING NOT TO SCALE
*DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
**DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
UF Package
20-Lead Plastic QFN (4mm × 4mm)
(Reference LTC DWG # 05-08-1710)
BOTTOM VIEW—EXPOSED PAD
4.00 ± 0.10
(4 SIDES)
0.70 ±0.05
4.50 ± 0.05
0.75 ± 0.05
R = 0.115
TYP
PIN 1 NOTCH
R = 0.30 TYP
19 20
0.38 ± 0.10
PIN 1
TOP MARK
(NOTE 6)
1
3.10 ± 0.05
2
2.45 ± 0.05
(4 SIDES)
2.45 ± 0.10
(4-SIDES)
PACKAGE
OUTLINE
0.25 ±0.05
0.50 BSC
(UF20) QFN 10-04
0.200 REF
0.00 – 0.05
0.25 ± 0.05
0.50 BSC
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
NOTE:
1. DRAWING IS PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220
VARIATION (WGGD-1)—TO BE APPROVED
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
4253a-adjf
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.
31
LTC4253A-ADJ
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APPLICATIO S I FOR ATIO
Circuit Breaker with Foldback Current Limit
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.
Figure 17 shows the LTC4253A-ADJ 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
– 48V RTN
(LONG PIN)
+
RIN
10k
20k(1/4W)/2
– 48V RTN
(SHORT PIN)
VIN
CIN
1µF
2k
1%
255k
1%
R3
UV
OVL
PWRGD2
OV
PWRGD3
R11
47k
POWER
MODULE 2
POWER
MODULE 4
R10
3k
†
RD
3.3M
4253 F17
VOUT
DRAIN
TIMER
VEE
POWER
MODULE 3
EN
†
R4
38.3k
†
R5
22Ω
FMMT493
Q1
IRF530S
GATE
SENSE
SEL
CT
1µF
– 48V
(LONG PIN)
EN
†
SS
SQTIMER
CSQ
0.1µF
C3
0.1µF
R8
100k
POWER
MODULE 1
EN
PWRGD1
RESET
C1 10nF
CSS 33nF
R7
100k
R9
100k
EN
VIN EN2 EN3
LTC4253A-ADJ
UVL
R2
2.05k
1%
RESET
(LONG PIN)
R1
20k
1%
R6
100k
C2
100µF
RC
10Ω
RS
0.02Ω
CC
10nF
Figure 17. –48V/2.5A Application with Foldback Current Limiting and Transistor Enabled Sequencing Without Feedback
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, Autoretry/Latched Off
LTC1642
Fault Protected Hot Swap Controller
3V to 16.5V, Overvoltage Protection up to 33V
LT4250
– 48V Hot Swap Controller
Active Current Limiting, Supplies from – 20V to – 80V
LTC4251/LTC4251-1
LTC4251-2
– 48V Hot Swap Controllers in SOT-23
Fast Active Current Limiting, Supplies from – 15V
LTC4252-1/LTC4252-2
LTC4252A-1/LTC4252A-2
– 48V Hot Swap Controllers in MS8/MS10
Fast Active Current Limiting, Supplies from – 15V,
Drain Accelerated Response, 1% Accurate UV/OV Thresholds
LTC4260
Positive Voltage Hot Swap Controller with I2C
Compatible Monitoring
Onboard ADC for Current and Voltage Monitoring,
8.5V to 80V Operation
4253a-adjf
32
Linear Technology Corporation
LT/TP 0805 500 • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
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