LINER LTC4216CMS

LTC4216
Ultralow Voltage
Hot Swap Controller
U
DESCRIPTIO
FEATURES
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The LTC®4216 is a positive low-voltage Hot SwapTM
controller that allows a board to be safely inserted and
removed from a live backplane. It controls load voltages
ranging from 0V to 6V and isolates a severe fault with
instantaneous analog current limiting.
Allows Safe Board Insertion and Removal from
a Live Backplane
Controls Load Voltages from 0V to 6V
Fast Response Limits Peak Fault Current
Adjustable Analog Current Limit
Adjustable Soft-Start with Inrush Current Limiting
Adjustable Response Time for Overcurrent
Protection
Low Circuit Breaker Trip Threshold: 25mV
No External Gate Capacitor Required
Gate Drive for External N-Channel MOSFET
Adjustable Supply Voltage Power-Up Rate
⎯R⎯E⎯S⎯E⎯T and ⎯F⎯A⎯U⎯L⎯T Output
10-Lead MSOP and 12-Lead (4mm × 3mm) DFN
Packages
An internal high side switch driver controls the gate of
an external N-channel MOSFET. An adjustable soft-start
limits the rate of change of the inrush current at start-up
for a large load capacitor. Together with an analog current
limit amplifier, an electronic circuit breaker with adjustable
response time provides dual level overcurrent protection.
No external gate capacitor is required for the analog current limit loop compensation.
The FB pin monitors the output supply voltage and signals
the ⎯R⎯E⎯S⎯E⎯T output pin. An ON pin provides on/off control
and a ⎯F⎯A⎯U⎯L⎯T pin indicates the fault status. The LTC4216
is available in the 10-lead MSOP and 12-lead (4mm ×
3mm) DFN packages.
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APPLICATIO S
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Electronic Circuit Breaker
Live Board Insertion and Removal
Industrial High Side Switch/Circuit Breaker
Optical Networking
, 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.
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TYPICAL APPLICATIO
Single Channel 1.8V Hot Swap Controller
Normal Power-Up
with Soft-Start
BACKPLANE PCB EDGE
CONNECTOR CONNECTOR
(FEMALE)
(MALE)
VIN
1.8V
VCC
3.3V
+
LONG
22Ω
VCC
SENSEP SENSEN GATE
10k
1%
ON
15k
1%
LONG
20k TIMER
1%
10nF
SS
FILTER
10nF
10k
VGATE
5V/DIV
IOUT
2.5A/DIV
FB
LTC4216
SHORT
1000µF
17.4k
1%
3.3V
330nF
GND
VOUT
1.8V
5A
Si4864DY
0.004Ω
LONG
10k
µP
LOGIC
FAULT
FAULT
GND RESET
RESET
VOUT
1V/DIV
18nF
4216 TA01
0.5ms/DIV
4216 TA01b
4216f
1
LTC4216
W W
U
W
ABSOLUTE
AXI U RATI GS
(Note 1)
Bias Supply Voltage (VCC) ............................– 0.3V to 9V
Input Voltages
FB, ON, SS, SENSEP, SENSEN .................– 0.3V to 9V
TIMER, FILTER............................ –0.3V to VCC + 0.3V
Output Voltages
⎯R⎯E⎯S⎯E⎯T, ⎯F⎯A⎯U⎯L⎯T ......................................... –0.3V to 9V
GATE ...................................................... –0.3V to 15V
Operating Temperature Range
LTC4216C ................................................ 0°C to 70°C
LTC4216I .............................................–40°C to 85°C
Storage Temperature Range
MS .....................................................–65°C to 150°C
DE ......................................................–65°C to 125°C
Lead Temperature (Soldering, 10sec)
MS Package ...................................................... 300°C
U
W
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PACKAGE/ORDER I FOR ATIO
TOP VIEW
RESET
1
12 FAULT
ON
2
11 VCC
FILTER
3
10 SENSEP
TIMER
4
9
SENSEN
SS
5
8
GATE
GND
6
7
FB
13
ORDER PART
NUMBER
LTC4216CDE
LTC4216IDE
DE PART*
MARKING
DE PACKAGE
12-LEAD (4mm × 3mm) PLASTIC DFN
TJMAX = 125°C, θJA = 43°C/W, θJC = 4.3°C/W
EXPOSED PAD (PIN 13)
INTERNALLY CONNECTED TO GND
(PCB CONNECTION OPTIONAL)
ORDER PART
NUMBER
LTC4216CMS
LTC4216IMS
TOP VIEW
RESET
ON
FILTER
TIMER
GND
4216
1
2
3
4
5
10
9
8
7
6
VCC
SENSEP
SENSEN
GATE
FB
MS PART*
MARKING
MS PACKAGE
10-LEAD PLASTIC MSOP
LTBKV
TJMAX = 125°C, θJA = 160°C/W
Consult LTC Marketing for parts specified with wider operating temperature ranges.
*The temperature grade is indicated 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. VCC = 3.3V, unless otherwise noted. (Note 2)
SYMBOL
PARAMETER
CONDITIONS
MIN
VCC
Bias Supply Range
●
2.3
6
V
VSENSEP
VSENSEP Supply Range
●
0
6
V
ICC
Bias Supply Current
VON = 2V, VFB = 2V
●
1.6
3
mA
VCC(UVL)
Bias Supply Undervoltage Lockout
VCC Rising
●
1.97
2.12
2.23
V
ΔVCC(UVL,HYST)
Bias Supply Undervoltage
Lockout Hysteresis
●
50
120
190
mV
ΔVCB(TH)
Circuit Breaker Trip Voltage Threshold
(VSENSEP – VSENSEN)
●
22.5
21.5
25
25
27.5
28.5
mV
mV
●
32
40
48
mV
20
70
–7
250
–20
µA
µA
10
–10
15
–15
µA
µA
ΔVACL(TH)
Analog Current Limit Voltage Threshold
(VSENSEP – VSENSEN)
ISENSEP(IN)
SENSEP Pin Input Current
VSENSEP = VSENSEN = VCC = 6V
VSENSEP = VSENSEN = 0V, VCC = 6V
●
●
ISENSEN(IN)
SENSEN Pin Input Current
VSENSEN = VSENSEP = VCC = 6V
VSENSEN = VSENSEP = 0V, VCC = 6V
●
●
–5
TYP
MAX
UNITS
4216f
2
LTC4216
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VCC = 3.3V, unless otherwise noted. (Note 2)
SYMBOL
PARAMETER
CONDITIONS
IGATE(UP)
IGATE(DN)
GATE Pull Up Current
GATE Pull Down Current
●
ΔVGATE
External N-Channel Gate Drive
(VGATE – VSENSEN)
GATE Pin Threshold Voltage
SS Pin Clamp Voltage
SS Pin Threshold Voltage
SS Pull Up Current
Gate Drive On, VGATE = 0V, VON = 2V
Gate Drive Off, VGATE = 5V, VON = 0.6V
VSENSEP - VSENSEN = 55mV, VGATE = 5V
VSENSEP - VSENSEN = 100mV, VGATE = 5V
2.3V ≤ VCC < 3V
3V ≤ VCC ≤ 6V
VGATE Falling
After End of SS Timing Cycle
VSS Falling
VON = 2V, VSS = 1.2V, VFB = 2V
VON = 2V, VFB = 0V
VON = 0V, VSS = 2V
VGATE(TH)
VSS(CLP)
VSS(TH)
ISS(UP)
ISS(DN)
VFB(TH)
SS Pull Down Current
ΔVFB(LINEREG)
ΔVFB(HYST)
IFB(IN)
VON(TH)
ΔVON(HYST)
VON(FC)
ION(IN)
VTMR(TH)
FB Pin Threshold Voltage
FB Pin Threshold Line Regulation
FB Pin Hysteresis
FB Pin Input Current
ON Pin Threshold Voltage
ON Pin Hysteresis
ON Pin Fault Clear Threshold Voltage
ON Pin Input Current
TIMER Pin Threshold Voltage
ITMR(UP)
ITMR(DN)
VFILT(TH)
Timer Pull Up Current
Timer Pull Down Current
FILTER Pin Threshold Voltage
IFILT(UP)
IFILT(DN)
Filter Pull Up Current
Filter Pull Down Current
V⎯F⎯A⎯U⎯L⎯T(TH)
ΔV⎯F⎯A⎯U⎯L⎯T(HYST)
I⎯F⎯A⎯U⎯L⎯T(UP)
VOL
I⎯R⎯E⎯S⎯E⎯T(LEAK)
tCB(TRIP)
⎯F⎯A⎯U⎯L⎯T Pin Threshold Voltage
⎯FA
⎯ U
⎯ L⎯ T⎯ Pin Hysteresis
⎯FA
⎯ U
⎯ L⎯ T⎯ Pin Current
⎯ E⎯ S
⎯ E⎯ T⎯ , F⎯ ⎯A⎯U⎯L⎯T)
Output Low Voltage (R
⎯R⎯E⎯S⎯E⎯T Pin Input Leakage Current
t⎯F⎯A⎯U⎯L⎯T(EXT)
tFILTER
tRST(ONLO)
tRST(VCCLO)
tOFF
Circuit Breaker Trip to Gate
Discharging
⎯ U
⎯ L⎯ T⎯ Low to Gate Discharging
F⎯ A
FILTER High to Gate Discharging
Circuit Breaker Reset Delay Time,
ON Low to ⎯F⎯A⎯U⎯L⎯T High
Circuit Breaker Reset Delay Time,
VCC Low to ⎯F⎯A⎯U⎯L⎯T High
Turn-Off Time, ON Low to GATE Discharging
MIN
TYP
MAX
UNITS
●
●
–16
100
1
15
4.0
4.5
0.15
1.3
0.15
–7
– 0.3
–20
600
5
50
5.0
6.2
0.2
1.65
0.2
–10
–1
8
–26
1500
20
100
7.9
7.9
0.3
2.0
0.35
–13
–2
µA
µA
mA
mA
V
V
V
V
V
µA
µA
mA
VFB Falling
2.3V ≤ VCC ≤ 6V
●
0.593
0.611
3
VFB = 1.2V, VCC = 6V
VON Rising
●
0.602
0.2
3
0
0.8
80
0.4
0
1.253
0.2
–2
8
1.253
0.2
–60
2.4
8
1.253
10
–5
0.15
0
240
–7
0.4
±10
360
V
mV
mV
µA
V
mV
V
µA
V
V
µA
mA
V
V
µA
µA
mA
V
mV
µA
V
µA
µs
20
40
60
µs
µs
µs
100
µs
●
●
●
●
●
●
●
●
●
●
●
VON Falling
VON = 1.2V, VCC = 6V
VTIMER Rising
VTIMER Falling
Timer On, VON = 2V, VTIMER = 1V
Timer Off, VON = 0V, VTIMER = 2V
VFILTER Rising
VFILTER Falling
VON = 2V, VFILTER = 1V, In Fault Mode
VON = 2V, VFILTER = 1V, No Faults
VON = 0V, VFILTER = 2V, In Reset Mode
V⎯F⎯A⎯U⎯L⎯T Falling
●
0.77
40
0.36
●
●
●
●
●
●
1.216
0.15
–1.5
●
1.216
0.15
–45
1.5
●
1.216
VON = 0V, V⎯F⎯A⎯U⎯L⎯T = 1.5V
I⎯R⎯E⎯S⎯E⎯T = I⎯F⎯A⎯U⎯L⎯T = 1.6mA
V⎯R⎯E⎯S⎯E⎯T = VCC = 6V
(VSENSEP - VSENSEN) = Step 0V to 30mV,
VSENSEP = VCC, FILTER = 10nF to GND
V⎯F⎯A⎯U⎯L⎯T = Step 2V to 0V
VFILTER = Step 0V to 2V
VON = Step 2V to 0V
●
–3
●
10
20
30
VON = 2V, VCC = Step 3.3V to 1.8V
●
50
VON = Step 2V to 0.6V
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
●
●
●
●
●
120
±1
0.83
130
0.44
±1
1.291
0.35
–2.5
1.291
0.35
–75
3.3
1.291
15
µs
Note 2: All currents into device pins are positive; all currents out of
the device pins are negative; all voltages are referenced to GND unless
otherwise specified.
4216f
3
LTC4216
U W
TYPICAL PERFOR A CE CHARACTERISTICS
Specifications are at TA = 25°C. VCC = 3.3V,
unless otherwise noted.
ICC vs VCC
ICC vs Temperature
3.0
3.0
2.5
2.5
2.0
2.0
VCC(UVL) vs Temperature
2.20
2.15
RISING
1.5
VCC(UVL) (V)
ICC (mA)
ICC (mA)
2.10
VCC = 6V
1.5
VCC = 3.3V
2.05
FALLING
2.00
VCC = 2.3V
1.0
1.0
0.5
2.0
2.5
3.0
3.5
4.0 4.5
VCC (V)
5.0
5.5
1.95
0.5
–50
6.0
–25
25
75
0
50
TEMPERATURE (°C)
100
4216 G01
25
75
0
50
TEMPERATURE (°C)
100
7.0
VGATE vs VSENSEN
14
VSENSEP = VSENSEN = VCC
VCC = 6V
12
6.5
26
125
4216 G03
ΔVGATE vs Temperature
ΔVCB(TH) vs Temperature
VCC = 5V
25
10
VCC = 3.3V
6.0
VGATE (V)
∆VGATE (V)
∆VCB(TH) (mV)
–25
4216 G02
27
5.5
5.0
23
–50
–25
25
75
0
50
TEMPERATURE (°C)
100
4
4.5
–50
125
2
–25
25
75
0
50
TEMPERATURE (°C)
4216 G04
100
ΔVACL(TH) vs Temperature
–21
39
100
125
4216 G07
3
4
VSENSEN (V)
5
6
VFB(TH) vs Temperature
0.608
RISING
–20
–19
25
75
0
50
TEMPERATURE (°C)
2
0.611
VFB(TH) (V)
IGATE(UP) (µA)
41
40
1
4216 G06
IGATE(UP) vs Temperature
–22
–25
0
125
4216 G05
42
38
–50
8
6
VCC = 2.5V
24
∆VACL(TH) (mV)
1.90
–50
125
–18
–50
0.605
FALLING
0.602
0.599
–25
25
75
0
50
TEMPERATURE (°C)
100
125
4216 G08
0.596
–50
–25
25
75
0
50
TEMPERATURE (°C)
100
125
4216 G09
4216f
4
LTC4216
U W
TYPICAL PERFOR A CE CHARACTERISTICS
VTMR(TH) vs Temperature
VON(TH) vs Temperature
1.27
VFAULT(TH) vs Temperature
0.90
1.27
0.85
VFAULT(TH) (V)
1.25
1.26
RISING
0.80
VON(TH) (V)
VTMR(TH) (V)
1.26
0.75
FALLING
0.70
1.24
1.25
1.24
0.65
1.23
–50
–25
25
75
0
50
TEMPERATURE (°C)
100
0.60
–50
125
–25
25
75
0
50
TEMPERATURE (°C)
4216 G10
1.23
–50
125
1.26
100
125
VSS(CLP) vs Temperature
1.9
1.8
VSS(CLP) (V)
–2.1
VFILT(TH) (V)
1.27
–1.9
25
75
0
50
TEMPERATURE (°C)
4216 G12
VFILT(TH) vs Temperature
–2.2
–2.0
–25
4216 G11
ITMR(UP) vs Temperature
ITMR(UP) (µA)
100
1.25
1.7
1.6
1.24
1.5
–1.8
–50
–25
25
75
0
50
TEMPERATURE (°C)
100
125
1.23
–50
–25
25
75
0
50
TEMPERATURE (°C)
4216 G13
100
1.4
–50
125
–25
4216 G14
IFILT(UP) vs Temperature
ISS(UP) vs Temperature
VFB = 2V
–10
2.6
–60
–55
–8
ISS(UP) (µA)
IFILT(DN) (µA)
IFILT(UP) (µA)
125
–12
2.8
–65
100
4216 G15
IFILT(DN) vs Temperature
–70
2.4
–6
–4
2.2
–2
–50
–50
25
75
0
50
TEMPERATURE (°C)
–25
25
75
0
50
TEMPERATURE (°C)
100
125
4216 G16
2.0
–50
–25
25
75
0
50
TEMPERATURE (°C)
100
125
4216 G17
0
–50
VFB = 0V
–25
25
75
0
50
TEMPERATURE (°C)
100
125
4216 G18
4216f
5
LTC4216
U
U
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PI FU CTIO S
(DE12 Package/MS Package)
⎯R⎯E⎯S⎯E⎯T (Pin 1/Pin 1): Reset or Power-Good Output. Open
drain output that pulls low if the FB pin voltage falls below
its threshold (0.6V). If an undervoltage lockout condition
occurs, the ⎯R⎯E⎯S⎯E⎯T pin pulls low and ignores the FB pin
voltage.
ON (Pin 2/Pin 2): ON Control Input. A rising edge above
the ON pin threshold (0.8V) initiates the start-up cycle and
turns on the external N-channel MOSFET. A falling edge
below 0.72V (80mV ON pin hysteresis) turns it off. If this
pin is pulled below 0.4V, following a circuit breaker trip, it
resets the electronic circuit breaker and fault latch.
FILTER (Pin 3/Pin 3): Fault Filter Input. Connect a capacitor
between this pin and ground to set up the fault filter delay.
This pin sources 60µA or sinks 2.4µA when the voltage
across the sense resistor exceeds 25mV or drops below
25mV respectively.
TIMER (Pin 4/Pin 4): Timer Input. Connect a capacitor
between this pin and ground to set up the start-up timing
⎯ E⎯ S
⎯ E⎯ T⎯ power-good delay
cycle duration. It also defines the R
from the instant the FB pin voltage exceeds 0.6V. This pin
sources 2µA pull-up current during ramp up.
SS (Pin 5/Not Available): Soft-Start Control Input. Connect a capacitor between this pin and ground for soft-start
during power-up. It controls the GATE ramp up, limiting
the rate of change of the inrush current when the external
MOSFET turns on. If soft-start function is not used, leave
this pin unconnected.
GND (Pin 6/Pin 5): Device Ground.
FB (Pin 7/Pin 6): Output Monitor for Reset Output. A resistive divider from the external MOSFET’s source terminal is
tied to this pin. When the voltage at this pin drops below
0.6V, the ⎯R⎯E⎯S⎯E⎯T pin pulls low.
GATE (Pin 8/Pin 7): Gate Drive for External N-Channel
MOSFET. An internal charge pump provides 20µA gate
pull-up current and sufficient gate overdrive to the external MOSFET. An internal shunt regulator limits the GATE
pin voltage to about 6.2V (typ) above the SENSEN pin
voltage.
SENSEN (Pin 9/Pin 8): Circuit Breaker Negative Sense
Input. Connect this pin to the sense resistor terminal wired
to the drain of the external N-channel MOSFET. The sense
resistor is placed in the power path between SENSEP and
SENSEN pins to sense the output current. The electronic
circuit breaker trips if the voltage across the sense resistor
exceeds 25mV for more than a fault filter delay.
SENSEP (Pin 10/Pin 9): Circuit Breaker Positive Sense
Input. Connect this pin to the sense resistor terminal wired
to the positive supply input for the external output load.
This positive supply range extends from 0V to 6V.
VCC (Pin 11/Pin 10): Bias Supply Input. Operates from
2.3V to 6V. An internal undervoltage lockout circuit disables
the device until the input supply voltage at VCC exceeds
2.12V typically.
⎯F⎯A⎯U⎯L⎯T (Pin 12/Not Available): Fault Input and Output. As
an input, driving this pin low (<1.253V) will latch-off the
device to fault mode. As an output, it is either pulled high
by an internal 5µA pull-up or an external pull-up resistor
to positive supply under normal operating condition. It
pulls low when the circuit breaker is tripped due to an
overcurrent fault.
Exposed Pad (Pin 13/Not Available): Exposed pad may
be left open or connected to device ground.
4216f
6
LTC4216
W
BLOCK DIAGRA
VCC
SENSEP
2.12V
25mV
–
+
SENSEN
–
+
40mV
–
+
UVLO
ECB
6µs
DELAY
FILTER DELAY
(SEE NOTE 1)
GATE
D1
–
+
VCC VCC
–
+
20µA
2µA
0.2V
+
OUT OF UVLO
M4
CB TRIPS
OR UVLO
FAULT LATCH-OFF
CP4
–
TIMER
10µA
M1
ACL
M3
VCC
CHARGE
PUMP
Z1
M2
100µA
GATE
OFF
GATE ON
1µA
M5
SS**
M6
R1
GATE OFF
RESET
+
M9
LOGIC
DEVICE RESET, UVLO
OR POWER BAD
CP5
1.253V
NORMAL
60µA
+
DEVICE
RESET
FAULT LATCH
RESET
GATE
ON
30µs
DELAY
+
CB
TRIPS
FILTER
FUNCTION OF
OVERDRIVE
3µs
DELAY
2.4µA
1.253V
D2
CP7
–
FAULT**
M8
CP6
1.253V
5µA
–
VCC
FILTER
VCC
M7
–
M10
CP1
+
CP2
+
–
0.4V
NOTE 1: FILTER DELAY IS SET BY FILTER PIN CAPACITOR
** ONLY AVAILABLE IN THE DE12 PACKAGE
CP3
–
–
0.8V
+
GND
0.6V
4216 BD
ON
FB
U
OPERATIO
The LTC4216 is a Hot Swap controller residing either on
a removable circuit board or on the backplane. It monitors the current and protects the load with an external
N-channel MOSFET and a current sensing resistor (see
Typical Application). Both inrush current limiting and
short-circuit protection are provided by the LTC4216. The
device is powered via the bias supply input (VCC) and it
has a separate sense pin, SENSEP, to monitor the load
supply (VIN). The load supply can extend from 0V to 6V,
with a minimum bias supply voltage of 2.3V.
When the ON pin is pulled from low to high, TIMER begins
the first timing cycle by sourcing 2µA into C1 once these
conditions are met: bias supply voltage out of undervoltage lockout (> 2.12V); TIMER, SS, FILTER and GATE
pin voltages < 0.2V. When the C1 voltage rises above
the TIMER pin threshold (1.253V), TIMER pulls low and
releases both the SS and GATE pins. C2 starts to ramp
up at the SS pin, controlling the rate of GATE ramp. This
limits the rate of change of the inrush current flowing into
the output load capacitance. ⎯R⎯E⎯S⎯E⎯T pin goes high after
the second timing cycle when the FB pin voltage exceeds
0.6V and its hysteresis.
When the external MOSFET is fully turned on, the output
will ramp to load supply voltage if the inrush into the load
capacitance is low. However, if the inrush current exceeds
the analog current limit of ΔVACL(TH)/RSENSE, the LTC4216
will ramp the output by sourcing the limited current into
the load capacitance.
The LTC4216 provides protection against output shortcircuits or current overload through an internal electronic
circuit breaker with trip threshold of 25mV and an analog
current limit circuit. The circuit breaker response time is
set by C3 at the FILTER pin.
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Hot Circuit Insertion
When circuit boards are inserted into a live backplane, the
supply bypass capacitors can draw huge transient current
from the power bus as they charge. Potentially, the flow
of current could damage the connector pins and glitch
the power bus, causing other boards in the system to
reset. The LTC4216 is designed to turn on or off a circuit
board supply in a controlled manner, allowing insertion
or removal without glitches or connector damage.
Overview of LTC4216 Features
1. Allows safe board insertion and removal from a live
backplane.
2. Controls load voltages from 0V to 6V.
3. High side gate drive for external N-channel MOSFET.
4. Adjustable soft-start with inrush current limiting for
large load capacitor during start-up.
5. Adjustable analog current limit (ACL) with circuit
breaker fault time-out during an overcurrent fault condition. No external gate capacitor is required for the ACL
loop compensation.
6. Electronic circuit breaker tripping at 25mV across the
sense resistor. The response time is adjustable through
an external capacitor at the FILTER pin.
7. Provides an ON pin to turn on and off the device. This
can also be used to reset the device after a circuit breaker
trip.
8. Provides output supply voltage monitoring through the
FB pin and signals the ⎯R⎯E⎯S⎯E⎯T pin output.
9. Provides fault status output.
ON Control
The ON pin has two hysteretic comparators with different threshold levels (0.8V and 0.4V) and they serve two
purposes:
1. Turn on the device if the ON pin voltage > 0.8V for more
than 6µs and turn it off if the ON pin voltage < 0.72V for
more than 15µs.
2. Reset the device if the ON pin voltage < 0.4V for more
than 30µs after a circuit breaker trip.
There are various methods of setting the ON pin
voltage:
1. Tie the ON pin to the load supply (VIN) through a 10k
pull-up resistor.
2. Drive the ON pin with an ON/OFF logic signal from the
system controller.
3. Connect an external resistive divider at the ON pin.
This divider can be used to set a higher value for the load
supply undervoltage lockout voltage than the internal VCC
undervoltage lockout circuit.
For example, as shown in Figure 17, if both VCC and
SENSEP pins are connected to a 5V load supply, choosing
the resistive divider values, R1 = 20k, R2 = 80.6k, turns on
the device when the load supply voltage reaches around
80% of its final value.
VCC Undervoltage Lockout
A hysteretic comparator, UVLO, monitors bias supply (VCC)
for undervoltage. The thresholds are defined by VCC(UVL)
(2.12V) and its hysteresis, ΔVCC(UVL,HYST) (120mV).
When VCC rises above VCC(UVL), the device is enabled.
When VCC falls below (VCC(UVL) – ΔVCC(UVL,HYST)), the
device is disabled and GATE is pulled low. If VCC cycles
below this threshold for more than 200µs, following a
circuit breaker trip, it clears the fault latch. Any bias supply glitches that last less than 10µs will be rejected by the
UVLO glitch filter.
Timer
An external capacitor, C1, is used at TIMER pin to provide
two timing cycles for the LTC4216. The first timing cycle
is the debounce cycle when the ON pin is first turned on,
both the GATE and SS pins are held low and any shortcircuit faults are ignored by the electronic circuit breaker.
Second timing cycle is the power-good delay before the
⎯R⎯E⎯S⎯E⎯T pin goes high when the FB pin voltage exceeds
0.6V and its hysteresis.
The TIMER pin sources 2µA into C1 during the two timing
cycles and is then pulled low by an internal N-channel
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tTIMER =
1.253V • C1
2µA
(1)
For example, if C1 = 10nF, tTIMER = 6.2ms.
FB Glitch Filtering
The FB pin is used to monitor the output voltage of the
external MOSFET through a resistive divider. Any transients on the FB pin due to the output low spikes will
pull ⎯R⎯E⎯S⎯E⎯T low. To prevent ⎯R⎯E⎯S⎯E⎯T from generating an
unwanted system reset, the FB comparator has a glitch
filter to ride out these glitches. The filter time is 20µs for
large transients (greater than 150mV) and up to 100µs
for small transients. The relationship between glitch filter
time and the FB pin transient voltage or FB overdrive is
shown in Figure 1.
FB pin voltage rises above 0.6V, the FB comparator output
goes low and a new timing cycle starts. After a complete
timing cycle at time point 6, ⎯R⎯E⎯S⎯E⎯T is pulled high by the
external pull-up resistor, R5. The timer period given by
Equation (1) sets the power-good delay for ⎯R⎯E⎯S⎯E⎯T going
high. If the FB pin voltage stays above 0.6V for less than
a timing cycle at time point 4, the ⎯R⎯E⎯S⎯E⎯T output remains
low. Any overcurrent fault detected by the electronic circuit
breaker or ⎯F⎯A⎯U⎯L⎯T pin driven low externally during the
timing cycle, will also pull the TIMER pin low and ⎯R⎯E⎯S⎯E⎯T
output remains low.
When the device enters an undervoltage lockout condition
or the ON pin voltage drops below 0.4V, ⎯R⎯E⎯S⎯E⎯T is pulled
low, ignoring the FB pin voltage.
RSENSE
CLOAD
R4
SENSEP SENSEN
GATE
VCC
FB
LOGIC
R5
R3
+
TA = 25°C
TIMER
120
GLITCH FILTER TIME (µs)
VOUT
+
ON
140
M1
VIN
–
switch when the TIMER pin voltage exceeds its threshold.
The timer period for C1 to charge up to the TIMER pin
threshold, VTMR(TH) (1.253V), is given by:
+
–
0.6V
µP
100
RESET
RESET
80
M2
60
TIMER
40
C1
20
0
0
40
80
120
160
FB OVERDRIVE (mV)
Figure 1. FB Comparator Glitch Filter Time vs FB Overdrive
As shown in Figure 2, the output voltage is monitored
through a resistive divider, R3 and R4, connected at the
FB pin, and a FB comparator with 0.6V threshold.
The normal operation of the output voltage monitor after a
start-up cycle is shown in Figure 3. At time point 1, when the
FB pin voltage falls below 0.6V, the FB comparator output
goes high. ⎯R⎯E⎯S⎯E⎯T is pulled low by an internal N-channel
switch after a glitch filter delay at time point 2. When the
4216 F02
Figure 2. Output Voltage Monitor Block Diagram
200
Output Voltage Monitor
LTC4216**
**ADDITIONAL DETAILS
OMITTED FOR CLARITY
3
1 2
VOUT
VFB < 0.6V
4
VFB > 0.6V
5
VFB < 0.6V
6
VFB > 0.6V
2µA
2µA
VTMR(TH)
TIMER
POWER-GOOD
DELAY
RESET
GLITCH FILTER DELAY
4216 F03
Figure 3. Output Voltage Monitor
Waveforms in Normal Operation
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Electronic Circuit Breaker
The LTC4216 features an electronic circuit breaker function
that protects the external MOSFET against short-circuits or
excessive load current conditions on the supply. An external
sense resistor connected between SENSEP and SENSEN
pins is used to measure the load current. If the voltage
across the sense resistor exceeds the circuit breaker trip
threshold of 25mV for more than a fault filter delay, the
gate of the MOSFET is pulled low, turning it off.
The fault filter delay is determined by a capacitor, C3, connected between the FILTER pin and ground as in Equation
(2). The FILTER pin sources 60µA pull-up current when
the sense voltage across the sense resistor exceeds 25mV.
Otherwise, it pulls down with 2.4µA. When the FILTER
pin voltage exceeds VFILT(TH) threshold (1.253V), there
is an internal 20µs delay before the GATE pulls low and
the ⎯F⎯A⎯U⎯L⎯T pin will be pulled low. If no FILTER capacitor
is used, the filter fault delay defaults to 20µs. The circuit
breaker response time or fault filter delay with the FILTER
capacitor, C3, is given by:
tCB(TRIP)
1.253V • C 3
=
+ 20µs
60µA
t
1.253
(s / µF ) =
C3
(60 • D)– 2.4
Following a circuit breaker trip, the device is latched-off
and ⎯F⎯A⎯U⎯L⎯T is pulled low until the fault latch is cleared by
pulling the ON pin low (< 0.4V) for at least 100µs. The
FILTER pin is pulled low by an internal N-channel switch
to discharge the capacitor quickly when the ON pin voltage falls below 0.4V and pulls down with 2.4µA when the
ON pin voltage rises above 0.8V to initiate a new start-up
cycle. The new timing cycle will not start until the FILTER
pin voltage is below 0.2V. The electronic circuit breaker
is disabled during the first timing cycle upon start-up and
any short-circuit faults will be ignored.
A
CIRCUIT BREAKER TRIPS
VFILTER
60µA
2.4µA
FAULT
MODE
4216 F04
Figure 4. A Continuous Fault Timing
(2)
Intermittent overloads may exceed the current limit as in
Figure 5, but if the duration is sufficiently short, the FILTER
pin voltage may not reach the VFILT(TH) threshold and the
device will not shut off. To handle this situation, the FILTER
discharges with 2.4µA whenever voltage across the sense
resistor is below 25mV. Any intermittent overload with
an aggregate duty cycle of more than 4% will eventually
trip the circuit breaker. Figure 6 shows the circuit breaker
response time in seconds normalized to 1µF as given by
Equation (3). The asymmetric charging and discharging
of FILTER is a fair gauge of MOSFET heating.
B
1.253V
NORMAL
MODE
The FILTER capacitor, C3, should be chosen so that the
fault filter delay is not too short to trip the circuit breaker
as the MOSFET current charges up a large output load
capacitance in analog current limit during power-up. It
also should not be too long to exceed the safe operating
area (SOA) of the external MOSFET.
(3)
A1
B1
A2
B2
A3
B3
25mV/RSENSE
ILOAD
2.4µA
1.253V
60µA
60µA
60µA
CIRCUIT
BREAKER
TRIPS
2.4µA
2.4µA
VFILTER
VGATE
CB
FAULT
CB
FAULT
CB
FAULT
Figure 5. Multiple Intermittent Overcurrent Condition
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NORMALIZED RESPONSE TIME (s/µF)
1
If the voltage across the sense resistor is greater than
ΔVACL(TH) during an overload condition, the ACL amplifier
will servo GATE downwards in an attempt to control the
MOSFET current. Since the GATE pin voltage overdrives
the MOSFET in normal operation, the ACL amplifier needs
time to discharge the GATE to the threshold of the MOSFET
for gate regulation. For mild overload, the ACL amplifier
can control the MOSFET current, but in the event of a
severe overload, the MOSFET current may overshoot as
the MOSFET has large GATE overdrive initially. The GATE
is quickly discharged to ground followed by the ACL amplifier taking control. For applications that require very fast
analog current limit recovery from the GATE undershoot as
it discharges, connect a series resistor, RZ, with an external
capacitor, CZ, at the GATE pin as shown in Figure 17.
t/C3(s/µF) = 1.253/[(60 • D) – 2.4]
0.1
0.01
0
20
40
60
80
OVERLOAD DUTY CYCLE, D (%)
100
4216 F06
Figure 6. Circuit Breaker Filter
Response for Intermittent Overload
Analog Current Limiting
Soft-Start
In addition to an electronic circuit breaker, the LTC4216
has included a novel analog current limit (ACL) amplifier
that does not require an external compensation capacitor
at the GATE pin. The amplifier’s stability is compensated
by the large gate input capacitance (CISS) of the external
MOSFET used. These MOSFETs usually have CISS ≥ 1nF.
However, if the MOSFET’s gate input capacitance (CISS)
is too small for loop stability, then connect an external
capacitor between the GATE pin and ground to increase
the total gate capacitance to ≥ 1nF. As given by Equation
(4), the MOSFET current, IACL, is limited to the analog
current limit voltage, ΔVACL(TH), 40mV typical, across
the sense resistor, RSENSE, connected between SENSEP
and SENSEN pins.
IACL =
∆VACL(TH)
RSENSE
(4)
The ΔVACL(TH) threshold is 1.6 times higher than the
ΔVCB(TH) threshold (25mV typical) to provide dual level current sensing. When the ACL amplifier servos the MOSFET
current at ΔVACL(TH) across the sense resistor, it exceeds
ΔVCB(TH) threshold causing the FILTER pin to charge C3
with 60µA pull-up. If the condition persists long enough
for C3 to reach the VFILT(TH) threshold (1.253V), GATE is
pulled low and ⎯F⎯A⎯U⎯L⎯T latched low.
The LTC4216 features a soft-start function that controls
the di/dt of the inrush current during power-up. As large
output load capacitors are commonly used in low-voltage
applications, the normal inrush can be large enough to
glitch the load supply. With the soft-start function, the
gate of the external MOSFET is allowed to turn on very
gradually to control the inrush current flowing into the
load capacitor without causing a supply glitch.
With an external capacitor, C2, connected between the SS
pin and ground, the GATE is servoed by the ACL amplifier
to track the rate of SS ramp-up during power-up. There
are two slopes in the SS ramp-up profile: 10µA current
source pull-up for a normal ramp rate; and 1µA current
source pull-up for a slower ramp rate. Both the SS ramp
rates are given as follows:
Normal SS Ramp Rate:
Slower SS Ramp Rate:
dVSS(NOM) 10µA
=
dt
C2
(5)
dVSS(SLOW) 1µA
=
dt
C2
(6)
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For example, if C 2 = 10nF,
dVSS(NOM)
= 1V /ms and
dt
dVSS(SLOW)
= 0.1V /ms.
dt
After the initial timing cycle, the SS capacitor is charged
by a 10µA current source pull-up and GATE is held low
by the ACL amplifier. As SS ramps up, the ACL amplifier
releases the GATE when it crosses its input offset voltage. At this instant, SS switches the pull-up current from
10µA to 1µA for a slower ramp rate. GATE continues to
charge up with 20µA pull-up before the MOSFET reaches
its turn-on threshold voltage. When the external MOSFET
is first turned on, there is always a current step due to the
high gain of the MOSFET. The slower SS ramp rate allows
the gate of the external MOSFET to be turned on with a
smaller inrush current step.
When the external MOSFET is turned on, load current starts
to flow through the sense resistor, developing a voltage drop
across it. This allows the ACL amplifier to servo the GATE
to the voltage across the sense resistor, thus controlling
the rate of change of the inrush current. At this instant, SS
switches back from 1µA to 10µA current source pull-up
for a normal ramp rate. GATE continues to ramp up as
the ACL amplifier servos to track the SS ramp rate. At the
end of SS ramp-up when SS reaches its final value, GATE
is servoed to ΔVACL(TH) across the sense resistor. If the
voltage across the sense resistor drops below ΔVACL(TH)
due to a falling load current, the ACL amplifier shuts off
and GATE ramps further by a 20µA pull-up.
SS is pulled low under any of the following conditions:
in VCC undervoltage lockout condition, during the first
timing cycle or when the circuit breaker fault times out.
If the soft-start function is not used, leave the SS pin
unconnected.
Inrush Control with GATE Capacitor
For applications not requiring soft-start to control the
di/dt of the inrush current during power-up, an alternative
way to limit the inrush is to control the GATE pin voltage
slew rate by connecting an external capacitor, C4, from
the GATE pin to ground, as shown in Figure 7. The GATE
slew rate is given by:
20µA
dVGATE
=
dt
C 4 + C GATE
(7)
where CGATE is the associated parasitic GATE capacitance
due to the external MOSFET’s gate input capacitance,
CISS.
The inrush current flowing into the load capacitor, CLOAD,
is limited to:
IINRUSH = C LOAD •
dVGATE
C LOAD
=
• 20µA
dt
C 4 + C GATE
(8)
For example, if CLOAD = 4700µF, C4 = 33nF and CGATE =
5nF, IINRUSH = 2.5A.
If CLOAD is very large and IINRUSH exceeds the analog
current limit, the GATE is servoed to control the inrush
current to ΔVACL(TH)/RSENSE.
One limitation with this technique is that it slows down
the system turn-on and turn-off time by adding a capacitor at the GATE pin. Should this technique be used, C4 ≤
50nF is recommended. However, having an external gate
capacitor helps to eliminate voltage spikes coupled through
the MOSFET’s drain-to-gate capacitance to the GATE pin
when the supply power is first applied.
VIN
RSENSE
M1
+
C4
SENSEP SENSEN GATE
LTC4216**
**ADDITIONAL DETAILS
OMITTED FOR CLARITY
R4
VOUT
CLOAD
FB
R3
4216 F07
Figure 7. Inrush Control with External Gate Capacitor
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Normal Power-Up and Power-Down
Figure 8 illustrates the timing diagram for a normal powerup sequence in the case where a printed circuit board is
inserted into a live backplane.
At time point 1, the bias supply (VCC) ramps up and enables the device when the supply voltage rises above the
undervoltage lockout threshold (2.12V). At time point 2,
SENSEP supply, together with the ON pin, ramp up and
start the first timing cycle when the ON pin voltage exceeds
0.8V. The TIMER capacitor is allowed to ramp up with 2µA
pull-up once all these conditions are met: GATE < 0.2V,
FILTER < 0.2V, TIMER < 0.2V, SS < 0.2V. At time point 3,
TIMER reaches the VTMR(TH) threshold and the first timing
cycle terminates. The electronic circuit breaker is enabled
and TIMER capacitor is quickly discharged. At time point
4 checks are made for TIMER, GATE, FILTER and SS <
0.2V, ∆VSENSE below 25mV and ⎯F⎯A⎯U⎯L⎯T high before a GATE
ramp-up cycle begins. GATE is held low by the analog current limit amplifier as SS capacitor ramps up with a 10µA
current source. SS switches to 1µA pull-up for a slower
ramp rate when it crosses the input offset voltage of the
ACL amplifier. At this time point, the ACL amplifier releases
the GATE and allows it to ramp up with a 20µA pull-up. At
time point 6, when the GATE voltage reaches the turn-on
threshold of the external MOSFET, current begins flowing
into the load capacitor. The MOSFET current level at this
time point is controlled by the ACL amplifier and the GATE
ramp is slowed down. SS switches the pull-up current
from 1µA to 10µA for a normal ramp rate. Between time
points 6 and 7, the ACL amplifier servos the GATE voltage
to track the SS ramp rate, limiting the slew rate of the load
current. At time point 7, SS reaches its final value and
GATE continue to ramp up with the 20µA pull-up if the load
current is not in analog current limit. At time point 8, the
FB pin voltage exceeds 0.6V and the second timing cycle
is started. When the conditions of TIMER < 0.2V, ∆VSENSE
< 25mV and ⎯F⎯A⎯U⎯L⎯T high are met, the TIMER capacitor is
allowed to ramp up. When TIMER reaches the VTMR(TH)
threshold at time point 9, ⎯R⎯E⎯S⎯E⎯T goes high, indicating to
the system controller that power is good. After this, the
TIMER is held low.
When the ON pin voltage falls below (VON(TH) – ΔVON(HYST))
threshold (0.72V), it initiates a power-down sequence. At
time point 11, GATE is discharged by both the ACL amplifier and a 100µA current source pull-down, causing the
output voltage to fall gradually. When the FB pin voltage
falls below 0.6V at time point 12, ⎯R⎯E⎯S⎯E⎯T goes low after a
glitch filter delay (see the section on FB glitch filtering),
indicating that power is bad. When the ON pin voltage falls
below 0.4V, the device resets and GATE is pulled low by a
strong pull-down device.
Soft-Start with Analog Current Limiting
When a very large output load capacitor is connected
during soft-start, the GATE voltage is servoed to regulate
the inrush current to ΔVACL(TH)/RSENSE. This is illustrated
in the timing diagram of Figure 9. After the initial timing
cycle, the GATE is allowed to ramp up, tracking the SS
ramp rate between time points 5 and 8. At time point 7,
when the load current builds up as the GATE pin voltage
increases, the voltage across the sense resistor rises above
ΔVCB(TH) (25mV typical). The FILTER capacitor starts to
charge up by a 60µA current source pull-up. At time point
8, SS reaches its final value at the end of SS ramp cycle.
This allows the GATE to be regulated by the ACL amplifier
at ΔVACL(TH) (40mV typical) across the sense resistor,
RSENSE, limiting the inrush to:
ILIMIT =
40mV
RSENSE
(9)
The FILTER pin voltage continues to rise as the load capacitor charges up with the limited load current. At time
point 9, the FB pin voltage exceeds 0.6V, but the second
timing cycle is not allowed to start as the voltage across
the sense resistor exceeds 25mV. At time point 10, the load
current falls as the load capacitor is near full charge and
the voltage across the sense resistor drops below 40mV.
The analog current limit loop shuts off and the GATE ramps
further till its final value. The FILTER capacitor discharges
by a 2.4µA pull-down when the voltage across the sense
resistor falls below 25mV at time point 11. The duration
between time points 7 and 11 must be shorter than one
circuit breaker delay, as given by Equation (2), to avoid
a fault time-out during GATE ramp-up for very large load
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capacitors. A second timing cycle starts at time point 11
when the FB pin voltage exceeds 0.6V and the voltage
across the sense resistor drops below 25mV. ⎯R⎯E⎯S⎯E⎯T goes
ELECTRONIC CIRCUIT
BREAKER ARMED
CHECK FOR GATE,
FILTER, TIMER,
SS < 0.2V
12
high at the end of the second timing cycle (time point 12)
when TIMER reaches the VTMR(TH) threshold.
ON GOES LOW
CHECK FOR GATE, FILTER,
TIMER, SS < 0.2V AND FAULT HIGH
START 2ND TIMING CYCLE
START
(CHECK TIMER < 0.2V AND
GATE
FAULT HIGH)
RAMP
3
4
5 6
78
IN
RESET
MODE
RESET GOES HIGH
9
RESET PULLED LOW
DUE TO POWER BAD
10 11 12
13
VCC
SENSEP
ON
0.72V
0.8V
0.4V
VTMR(TH)
VTMR(TH)
TIMER
2µA
2µA
10µA
1µA
SS
10µA
TRACKS SS RAMP
20µA
GATE
(VGATE – VOUT) > VGS(TH)
POWER GOOD
VFB > 0.6V
VOUT
POWER BAD
VFB < 0.6V
RESET
4216 F08
PLUG-IN CYCLE
FIRST TIMING CYCLE
POWER-GOOD DELAY
SECOND TIMING CYCLE
Figure 8. Normal Power-Up/Power-Down Sequence
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FILTER RAMPS UP WHEN (VSENSEP – VSENSEN) > 25mV
OUTPUT IN ANALOG CURRENT LIMIT,
(VSENSEP – VSENSEN) = 40mV
CHECK FOR GATE, FILTER, TIMER, SS < 0.2V AND FAULT HIGH
ELECTRONIC CIRCUIT BREAKER ARMED
CHECK FOR GATE,
FILTER, TIMER,
SS < 0.2V
OUTPUT NO LONGER
IN CURRENT LIMIT
12
3
RESET PULLED LOW
DUE TO POWER BAD
2ND TIMING CYCLE CANNOT START WITH
OUTPUT IN ANALOG CURRENT LIMIT
4
5 6
7 8
RESET
GOES HIGH
9 10 11
ON GOES LOW
(ON < 0.72V)
12
IN RESET
MODE
(ON < 0.4V)
13 14 15
16
VCC
SENSEP
0.72V
0.8V
ON
0.4V
VTMR(TH)
VTMR(TH)
TIMER
2µA
2µA
10µA
1µA
SS
10µA
IN REGULATION
TRACKS SS RAMP
GATE
20µA
(VGATE – VOUT) > VGS(TH)
POWER GOOD
VFB > 0.6V
VOUT
POWER BAD
VFB < 0.6V
LOAD CURRENT REGULATING
AT 40mV/RSENSE
ILOAD
(VSENSEP – VSENSEN) > 25mV
(VSENSEP – VSENSEN) < 25mV
VFILT(TH)
60µA
FILTER
2.4µA
RESET
4216 F09
PLUG-IN CYCLE
FIRST TIMING CYCLE
POWER-GOOD DELAY
SECOND TIMING CYCLE
Figure 9. Normal Power-Up Sequence (with Analog Current Limiting)
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Power-Up into an Output-Short
Sense Resistor Considerations
Figure 10 shows the timing diagram in the case when the
output is a dead short during power-up. As GATE ramps
up at time point 6, the MOSFET current increases due to
the output short causing the voltage drop across the sense
resistor to rise above 25mV. FILTER sources 60µA, charging the external capacitor. At time point 7, GATE regulates
to limit the output current to 40mV/RSENSE. If the output
continues to be in analog current limit when the FILTER
pin voltage reaches its threshold (1.253V) at time point
8, the circuit breaker trips and GATE is pulled low. The
device latches-off and ⎯F⎯A⎯U⎯L⎯T is pulled low, indicating a
fault condition. The FILTER capacitor discharges through
a 2.4µA pull-down until the device resets.
The circuit breaker trip threshold of 25mV and the value of
the sense resistor, RSENSE, connected between the SENSEP
and SENSEN pins, determine the trip current level as given
by Equation (10). If the fault current level exceeds the
analog current limit, the current is limited to a value given
by Equation (11). Should the overload condition exist for
more than one fault filter delay as given by Equation (2),
the circuit breaker trips and the device is latched-off.
ITRIP(CB) =
IACL =
Resetting the Electronic Circuit Breaker
When the LTC4216’s electronic circuit breaker is tripped
during a fault condition, ⎯F⎯A⎯U⎯L⎯T is asserted low and the
⎯R⎯E⎯S⎯E⎯T, SS and GATE pins are all pulled to ground. This is
shown in the timing diagram of Figure 11. The LTC4216
remains latched-off until the external fault is cleared. To
clear the internal fault latch and restart the device, pull
the ON pin low (< 0.4V) at time point 4 for at least 100µs,
after which the ⎯F⎯A⎯U⎯L⎯T will go high at time point 5. Toggling the ON pin from low to high (> 0.8V) initiates a new
start-up cycle.
∆VCB(TH) 25mV
=
RSENSE
RSENSE
∆VACL(TH) 40mV
=
RSENSE
RSENSE
ON
23
45 67
RSENSE =
∆VCB(TH,MIN)
21.5mV
=
ILOAD(MAX)
ILOAD(MAX)
CIRCUIT BREAKER TRIPS
AND LATCHED-OFF
(12)
RESET PULLED LOW
DUE TO POWER BAD
MILD
OVERCURRENT
FAULT LATCH
RESET
23
4
ON
8
5
0.4V
0.8V
SS
10µA
SS
GATE
(11)
For a new circuit design, the sense resistor value is first
calculated from the maximum operating load current under
normal conditions and the minimum circuit breaker trip
threshold. This is given by:
1
1
(10)
10µA
1µA
TRACKS SS RAMP
VGATE – VOUT < VGS(TH)
GATE
REGULATING
FPD
FPD
GATE
VOUT
40mV
POWER BAD
VFB < 0.6V
VOUT
25mV
SENSEP-SENSEN
<40mV
VTMR(TH)
TIMER
SENSEP-SENSEN
25mV
2µA
VFILT(TH)
FILTER
60µA
VFILT(TH)
FILTER
2.4µA
FAULT
FILTER
DELAY
2.4µA
60µA
FAULT
FAULT
tRST(ONLO)
RESET
RESET
4216 F10
4216 F11
Figure 10. Power-Up into an Output-Short and
Circuit Breaker Trips
Figure 11. Mild Overcurrent Circuit Breaker Trips Followed by
Device Reset
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For example, if ILOAD(MAX) = 5A, RSENSE = 4.3mΩ. The
nearest standard value is 4mΩ.
For proper circuit breaker operation, kelvin-sense PCB
connections between the sense resistor and the LTC4216’s
SENSEP and SENSEN pins are strongly recommended.
Figure 12 illustrates the correct way of making connections
between the LTC4216 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.
The power rating of the sense resistor should accommodate the fault current level during analog current limit
so that the component is not damaged before the circuit
breaker trips.
CURRENT FLOW
TO LOAD
CURRENT FLOW
TO LOAD
W
4216 F12
TO
SENSEP
TO
SENSEN
Figure 12. Making PCB Connections to the Sense Resistor
Circuit Breaker Trip Current Calculation
For a selected RSENSE value, the typical load current that
trips the circuit breaker is given by:
ITRIP(TYP) =
∆VCB(TH,TYP)
25mV
=
RSENSE(TYP) RSENSE(TYP)
(13)
The minimum load current that trips the circuit breaker
is given by:
ITRIP(MIN) =
∆VCB(TH,MIN)
21.5mV
=
RSENSE(MAX) RSENSE(MAX)
⎛ R ⎞
RSENSE(MAX) = RSENSE(TYP) • ⎜ 1 + TOL ⎟
⎝
100 ⎠
The maximum load current that trips the circuit breaker
is given by:
ITRIP(MAX) =
∆VCB(TH,MAX)
28.5mV
=
RSENSE(MIN)
RSENSE(MIN)
where
(15)
⎛ R ⎞
RSENSE(MIN) = RSENSE(TYP) • ⎜ 1– TOL ⎟
⎝
100 ⎠
For example, if a sense resistor of 4mΩ ± 1% RTOL is used
for current sensing, the typical trip current, ITRIP(TYP) =
6.25A. From Equations (14) and (15), ITRIP(MIN) = 5.3A
and ITRIP(MAX) = 7.2A respectively.
For proper operation and to avoid tripping the circuit breaker
unnecessarily, the minimum trip current, ITRIP(MIN), must
exceed the maximum operating load current of the circuit
connected to the output of the MOSFET.
SENSE RESISTOR
TRACK WIDTH W:
0.03˝ PER AMPERE
ON 1OZ COPPER
where
(14)
MOSFET Selection
The external MOSFET switch must have adequate safe
operating area (SOA) to handle short-circuit conditions
before the circuit breaker trips. These considerations
take precedence over continuous drain current ratings. A
MOSFET with adequate SOA for a given application can
always handle the required drain current, but the opposite
may not be true. Consult the manufacturer’s MOSFET
datasheet for safe operating area and effective transient
thermal impedance curves.
MOSFET selection is a 3-step process by assuming the
absence of a soft-start capacitor. First, RSENSE is chosen
and then the time required to charge the load capacitance
is determined. This timing, along with the maximum shortcircuit current and maximum load supply voltage, defines
an operating point that is checked against the MOSFET’s
SOA curve.
In addition, consider three other key parameters:
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APPLICATIO S I FOR ATIO
1. Maximum drain-to-source voltage, VDS(MAX)
The VDS(MAX) rating must exceed the maximum load supply voltage including spikes and ringing.
2. Gate-to-source voltage, VGS, overdrive
The absolute maximum rating for VGS is typically ±8V for
“logic level” and “sub-logic level” MOSFETs.
3. Drain-to-source resistance, RDS(ON)
The RDS(ON) should be low for low-voltage applications
to allow its drain-to-source voltage, VDS(ON), to be a very
small percentage of the supply voltage.
To begin a design, first specify the maximum operating load
current and load capacitance. Calculate the RSENSE value
from Equation (12). The minimum trip current, ITRIP(MIN),
given by Equation (14) should be set to accommodate the
maximum operating load current.
During the start-up cycle, the LTC4216 may operate the
MOSFET in analog current limit, forcing ΔVACL(TH) between
32mV to 48mV across RSENSE. The minimum inrush current
given by Equation (16) is calculated using the minimum
ΔVACL(TH) and maximum RSENSE value.
IINRUSH(MIN) =
∆VACL(TH,MIN)
32mV
=
RSENSE(MAX)
RSENSE(MAX)
(16)
The maximum short-circuit current given by Equation (17)
is calculated using the maximum ΔVACL(TH) and minimum
RSENSE value.
ISHORT −CIRCUIT(MAX) =
∆VACL(TH,MAX)
48mV
=
RSENSE(MIN)
RSENSE(MIN)
(17)
Select the FILTER capacitor, C3, based on the slowest
expected charging rate; otherwise, FILTER might time-out
before the load capacitor is fully charged. A value for C3
is calculated based on the maximum time it takes the load
capacitor, CLOAD, to charge to its maximum value of load
supply (VIN(MAX)). That time is given by:
tCHARGE(LOAD) =
C LOAD • VIN(MAX)
IINRUSH(MIN)
(18)
Rearranging Equation (2) for the circuit breaker response
time, the FILTER capacitor, C3, is given by:
C3 =
(tCHARGE(LOAD) – 20µs)• 60µA
1.253V
(19)
Returning to Equation (2), the circuit breaker response time
is calculated with a chosen C3 and used in conjunction
with VIN(MAX) and ISHORT-CIRCUIT(MAX) to check the SOA
curves of a prospective MOSFET.
As a numerical design example for the Typical Application,
consider VIN(MAX) = 1.8V + 5%, maximum operating load
current = 5A, CLOAD = 1000µF. Equation (12) gives RSENSE
= 4.3mΩ. Choose RSENSE = 4mΩ ± 1% tolerance. From
Equations (14) and (16), ITRIP(MIN) = 5.3A (> ILOAD(MAX)
= 5A) and IINRUSH(MIN) = 7.9A respectively. Equation (19)
gives C3 = 10nF. To account for errors in C3, FILTER current
(60µA) and FILTER threshold (1.253V), the calculated value
should be multiplied by 1.5, giving the nearest standard
value of C3 = 18nF.
If a short-circuit occurs, a current of up to ISHORTCIRCUIT(MAX) = 12.1A will flow through the MOSFET for
400µs as dictated by C3 = 18nF in Equation (2). The
MOSFET must be selected based on this criterion and
checked against the SOA curve.
VCC Supply RC Network
The LTC4216 has two separate pins, VCC and SENSEP, for
supply input and sensing:
1. VCC pin for powering the internal circuitry.
2. SENSEP pin, together with the SENSEN pin, for sensing the current flowing from the load supply through the
external sense resistor and N-channel MOSFET to the
output load.
In most hot swap devices, VCC and SENSEP are one
common pin, providing the device’s supply and external
MOSFET’s current sensing. However, supply dips due to
output-shorts can potentially trigger the device into an
undervoltage lockout condition, causing the device to
disable and its internal latches to reset.
As bypass capacitors are not allowed on the powered
supply side of the external MOSFET switch residing on
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APPLICATIO S I FOR ATIO
the plug-in boards, the LTC4216 provides two separate
pins for bias supply input and load supply sensing. With
this configuration, an RC network, RY and CY, shown in
Figure 13, can be used with the VCC pin to ride out supply
glitches during output-shorts or adjacent board shorts.
The RC network shown has a time constant of 7µs and
this is good enough for the supply to ride out most supply
glitches, preventing the device from entering an undervoltage lockout condition unnecessarily or losing supply
temporarily. When VCC and SENSEP pins are connected
together, the RY value should be chosen such that VCC pin
voltage is lower than SENSEP by 70mV; otherwise, part of
VCC pin current will be diverted through SENSEP pin.
This unique scheme of separating the device’s supply input
and sensing also provides the flexibility of operating the
load supply from ground to its supply rail with a minimum
bias supply voltage of 2.3V. For proper operation, the load
supply is required to be equal to or less than the bias supply voltage (maximum 6V).
Supply Transients Protection
There are two methods used in most applications to
eliminate supply transients:
1. Transient voltage suppressor to clip the transient to
a safe level.
2. Snubber (series RC) network.
For applications with load supply voltages of 3.3V or
higher, the ringing and overshoot during hot-swapping or output-shorts can easily exceed the absolute
maximum rating of the LTC4216. To minimize the risk,
a transient voltage suppressor and snubber network
are highly recommended at the SENSEP pin. For applications with load supply voltages of 2.5V or below,
usually a snubber network is adequate to reduce the
supply ringing.
Figure 13 shows the connections of the supply transient protection devices, Z1, RX and CX, around the
LTC4216. The RC network, RY and CY, at the VCC pin
also serve as a snubber circuit for the load supply (VIN).
On the PCB layout, these transient protection devices
should be mounted very close to the LTC4216’s load
supply rail using short lead lengths to minimize lead
inductance.
RSENSE
VIN
5V
M1
VOUT
5V
RY
22Ω
RX
10Ω
R4
VCC
SENSEP SENSEN GATE
FB
R3
LTC4216**
Z1
CX
0.1µF
+
GND
CY
0.33µF
TIMER
C1
FILTER
C2
SS
CLOAD
C3
GND
**ADDITIONAL DETAILS
OMITTED FOR CLARITY
Z1: SMAJ6.0A
4216 F13
Figure 13. Connecting Transient Protection
Devices to the LTC4216’s Load Supply Rail
Staggered Pins Connections
The LTC4216 can be used on either the backplane side of
the connector or a printed circuit board, and examples for
both are shown in Figure 14 and 15. Printed circuit board
edge connectors with staggered pins are recommended as
the insertion and removal of circuit boards will sequence
the pin connections. Supplies (VCC and SENSEP) and
ground connections on the printed circuit board should
be wired to the long pins or blades of the edge connector.
Control signal (ON) and status signals (⎯R⎯E⎯S⎯E⎯T and ⎯F⎯A⎯U⎯L⎯T)
passing through the edge connector should be wired to
short pins or blades.
Backplane and PCB Connection Sensing
The LTC4216’s ON pin can be used in various ways to
detect whether the printed circuit board is seated properly
in the backplane connector before the LTC4216 begins a
start-up cycle.
An example is shown in Figure 14, in which the LTC4216
is mounted on the PCB and the R1/R2 resistive divider
is connected to the ON pin. On the edge connector, R2
is wired to a short pin. Before the connectors are mated,
the ON pin is held low by R1, keeping the LTC4216 in an
off state. When the connectors are mated, the resistive
divider is connected to the load supply (VIN) and the ON
pin voltage rises above 0.8V, turning the LTC4216 on.
4216f
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An example with LTC4216 mounted on the backplane is
shown in Figure 15. In this case, the NPN transistor, Q1,
and two resistors, R7 and R8, form the PCB connection
sensing circuit with the ON pin. With the PCB out of the
backplane connector, Q1 base is tied to load supply through
R7, turning Q1 on and pulling the LTC4216’s ON pin low.
The base of Q1 is also wired to the backplane connector
pin. When the PCB is inserted into the backplane, Q1 base
is grounded through a short pin connection on the PCB.
This turns off Q1 and the LTC4216’s ON pin is allowed to
pull high to the load supply through R8, turning it on.
circuit. M2 is held on by its gate, pulling high through
R8 to the load supply until the PCB is mated firmly to
the backplane connector. A low logic-level for both the
⎯ N
⎯ /RST and O
⎯ N
⎯ /OFF signals turns M2 and M3 off, allowing
O
the ON pin to be pulled high and turning LTC4216 on. A
high logic-level for the ⎯O⎯N/OFF signal turns off the device
and pulls the GATE low. The device is reset by pulling the
⎯O⎯N/RST signal high.
5V Hot Swap Application
Figure 17 shows a hot swap application circuit with VCC
and SENSEP pins connected together to a 5V load supply
(VIN). The resistive divider, R1/R2, sets the undervoltage
threshold for the load supply and allows the system to
start up only after the supply voltage rises above 4V. The
resistive divider, R3/R4, monitors VOUT and signals the
In the previous examples, the PCB connection sensing
circuits are not wired with interrupt capability from the
system controller. As shown in Figure 16, adding logiclevel discrete N-channel MOSFETs, M2 and M3, and a
couple of resistors allow interrupt control to the sensing
BACKPLANE PCB EDGE
CONNECTOR CONNECTOR
(FEMALE)
(MALE)
VCC
3.3V
LONG
VIN
1.5V
LONG
RX
10Ω
CX
100nF
CY
330nF
11
2
R2
3.3k
1%
LONG
M1
Si4864DY
8
VCC SENSEP SENSEN GATE
SHORT
GND
RSENSE
0.004Ω
RY
22Ω
R1
C4
20k 10nF
1%
10
9
FB
R3
10k
1%
LTC4216
ON
FAULT
TIMER
FILTER
SS
4
PCB CONNECTION
SENSING
7
5
C1
10nF
GND RESET
3
C2
10nF
R4
13k
1%
+
R6
10k
VOUT
1.5V
5A
CLOAD
4700µF
R5
10k
µP
LOGIC
12
FAULT
1
RESET
6
C3
68nF
4216 F14
Figure 14. Single Channel 1.5V Hot Swap Controller
RY
22Ω
VIN
3.3V
Z1
CX
100nF
RX
10Ω
PCB
CONNECTION
SENSING
R7
10k
R8
10k
CY
330nF
RSENSE
0.004Ω
M1
Si4864DY
LONG
+
R6
10k
11
10
9
8
VCC SENSEP SENSEN GATE
2
ON
Q1
FAULT
GND
SHORT
4
SS
FILTER
5
C1
10nF
3
C2
4.7nF
CLOAD
1000µF
FAULT
R5
10k
RESET
TIMER
LONG
12
LTC4216
6
Z1: SMAJ6.0A
Q1: MMBT3904
BACKPLANE PCB EDGE
CONNECTOR CONNECTOR
(FEMALE)
(MALE)
C3
33nF
FB
1
SHORT
7
SHORT
R3
10k
1%
SHORT
VOUT
3.3V
5A
R4
39.2k
1%
RESET
R9
100k
4216 F15
Figure 15. Hot Swap Controller on Backplane with Staggered Pin Connections
4216f
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APPLICATIO S I FOR ATIO
BACKPLANE PCB EDGE
CONNECTOR CONNECTOR
(FEMALE)
(MALE)
LONG
VCC
5V
CY
330nF
RY
22Ω
RSENSE
0.004Ω
LONG
VIN
3.3V
SHORT
CX
RX
100nF
10Ω
R8
10k
Z1
R3
20k 1%
2
LONG
GND
11
10
9
8
VCC SENSEP SENSEN GATE
ON
FB
7
R4
10k
1%
LTC4216
FAULT
R1
M3 5.62k
1%
SHORT
ON/OFF
+
R5
39.2k
1%
R2
M2
4.42k
1%
SHORT
ON/RST
M1
Si4864DY
4
5
C1
10nF
PCB CONNECTION SENSING
GND RESET
FILTER
SS
TIMER
3
C2
4.7nF
6
R7
10k
VOUT
3.3V
5A
CLOAD
1000µF
R6
10k
µP
LOGIC
12
FAULT
1
RESET
Z1: SMAJ6.0A
M2, M3: 2N7002K
C3
33nF
4216 F16
Figure 16. PCB Connection Sensing with ON/OFF Control
VIN
5V
BACKPLANE PCB EDGE
CONNECTOR CONNECTOR
(FEMALE)
(MALE)
LONG
RY
22Ω
Z1
SHORT
RX
10Ω
CX
100nF
R2
80.6k
1%
M1
Si4864DY
CZ
RZ
10nF
100Ω
CY
330nF
11
10
9
8
VCC SENSEP SENSEN GATE
2
4
FAULT
SS
FILTER
5
C1
10nF
LONG
FB
GND RESET
3
C2
4.7nF
+
R4
64.9k
1%
7
R3
10k
1%
LTC4216
ON
R1
20k
1% TIMER
GND
RSENSE
0.004Ω
12
1
R6
10k
R5
10k
CLOAD
470µF
VOUT
5V
5A
µP
LOGIC
FAULT
RESET
6
C3
22nF
Z1: SMAJ6.0A
4216 F17
Figure 17. 5V Hot Swap Application
⎯ ⎯E⎯S⎯E⎯T high when VOUT rises above 4.5V. Transient voltR
age suppressor, Z1, and snubber network, RX and CX,
connected at SENSEP pin are highly recommended to
protect the 5V supply system from ringing and voltage
spikes during a fault condition. The RC network, RY and
CY, connected at the VCC pin, allows the LTC4216 bias
supply to ride out supply glitches during a fault condition
or adjacent board shorts.
Auto-Retry after a Fault
As shown in Figure 18, the LTC4216 can be configured to
automatically retry after a fault condition by connecting
both the ⎯F⎯A⎯U⎯L⎯T and ON pins together with an RC network.
The network has a pull-up resistor, RAUTO, tied to the load
supply (VIN) and an external capacitor, CAUTO, connected
to ground. The auto-retry circuit will attempt to restart
the LTC4216 after a circuit breaker trip, as shown in the
timing diagram of Figure 19. In addition to the cooling
cycle provided by the TIMER period during auto-retry
sequence, the RC time constant for the ON pin voltage to
reach 0.8V provides additional turn-off time to prevent
the external MOSFET from overheating. The auto-retry
duty cycle is given by:
Duty Cycle ≈
tSS + tFILTER • 100%
tOFF + tTIMER + tSS + tFILTER
(20)
where
tTIMER = TIMER period as given by Equation (1);
tOFF = time taken to charge the capacitor, CAUTO, from
⎯F⎯A⎯U⎯L⎯T VOL to VON(TH) threshold (0.8V). As there is an
internal 5µA current source pull-up at the ⎯F⎯A⎯U⎯L⎯T pin, it
4216f
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APPLICATIO S I FOR ATIO
complicates the equation for tOFF. This is approximately
given by:
tOFF ≈
RAUTO • C AUTO •(VON(TH) − VOL )
(VIN – VON(TH) ) + RAUTO • 5µA
For the component values shown, the external RC time
constant is set at 0.2 second, tTIMER = 62ms, tOFF = 25ms
at VIN = 5V, tSS = 1.6ms, tFILTER = 480µs and the auto-retry
duty cycle is 2.3%. The auto-retry duty cycle can be further
reduced by increasing both the tTIMER delay and the RC
delay. As an example, increasing the TIMER capacitor, C1,
value from 100nF to 330nF, and RAUTO value from 200k
to 470k reduces the duty cycle to 0.8%.
(21)
tFILTER = circuit breaker response time as given by Equation
(2); tSS = approximated time taken to charge the soft-start
capacitor, C2, from 0V to its final value (1.65V) by 10µA
current source only.
BACKPLANE PCB EDGE
CONNECTOR CONNECTOR
(FEMALE)
(MALE)
LONG
VIN
5V
Z1
R5
10k
RAUTO
200k
RX
10Ω
CX
100nF
RY
22Ω
CY
330nF
12
2
CAUTO
1µF
FB
RESET
ON
GND
6
FILTER
SS
TIMER
4
5
3
C1
C2
C3
100nF
4.7nF
22nF
+
VOUT
5V
CLOAD 5A
470µF
7
R3
10k
1%
LTC4216
FAULT
LONG
GND
R4
64.9k
1%
11
10
9
8
VCC SENSEP SENSEN GATE
1
SHORT
RESET
M1
Si4864DY
RSENSE
0.004Ω
4216 F18
Z1: SMAJ6.0A
Figure 18. Auto-Retry Application
FILTER RAMPS UP WHEN
(VSENSEP–VSENSEN) >25mV
OUTPUT IN ANALOG CURRENT LIMIT
CHECK FOR GATE, FILTER,
TIMER, SS < 0.2V AND FAULT HIGH
1
ON/FAULT PULLED LOW
DEVICE RESET
1ST TIMING CYCLE RESTART
ELECTRONIC CIRCUIT
BREAKER ARMED
CHECK FOR GATE, FILTER,
TIMER, SS < 0.2V
2
3
4
5
6
789
10
11 12
13
14
SENSEP
0.8V
0.8V
0.4V
ON/FAULT
VOL
10µA
1µA
SS
10µA
GATE
REGULATING
TRACKS SS RAMP
(VGATE – VOUT) > VGS(TH)
GATE
40mV
25mV
SENSEP–SENSEN
VTMR(TH)
TIMER
VTMR(TH)
2µA
2µA
VFILT(TH)
FILTER
2.4µA
60µA
tOFF
tTIMER
tFILTER
tSS
tRST(ONLO)
tTIMER
4216 F19
tOFF
Figure 19. Auto-Retry Timing
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PACKAGE DESCRIPTIO
DE/UE Package
12-Lead Plastic DFN (4mm × 3mm)
(Reference LTC DWG # 05-08-1695)
NOTE:
1. DRAWING PROPOSED TO BE A VARIATION OF VERSION
(WGED) IN JEDEC PACKAGE OUTLINE M0-229
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE
DO NOT INCLUDE MOLD FLASH. MOLD FLASH, IF PRESENT,
SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
0.65 ±0.05
3.50 ±0.05
1.70 ±0.05
2.20 ±0.05 (2 SIDES)
PACKAGE OUTLINE
0.25 ± 0.05
3.30 ±0.05
(2 SIDES)
0.50
BSC
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
4.00 ±0.10
(2 SIDES)
7
0.38 ± 0.10
R = 0.115
TYP
12
R = 0.20
TYP
3.00 ±0.10
(2 SIDES)
PIN 1
TOP MARK
(NOTE 6)
1.70 ± 0.10
(2 SIDES)
PIN 1
NOTCH
(UE12/DE12) DFN 0603
6
0.25 ± 0.05
0.75 ±0.05
0.200 REF
1
3.30 ±0.10
(2 SIDES)
0.00 – 0.05
0.50
BSC
BOTTOM VIEW—EXPOSED PAD
MS Package
10-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1661)
3.00 ± 0.102
(.118 ± .004)
(NOTE 3)
0.889 ± 0.127
(.035 ± .005)
5.23
(.206)
MIN
10 9 8 7 6
3.20 – 3.45
(.126 – .136)
0.254
(.010)
0.50
0.305 ± 0.038
(.0197)
(.0120 ± .0015)
BSC
TYP
RECOMMENDED SOLDER PAD LAYOUT
3.00 ± 0.102
(.118 ± .004)
(NOTE 4)
4.90 ± 0.152
(.193 ± .006)
DETAIL “A”
0.497 ± 0.076
(.0196 ± .003)
REF
0° – 6° TYP
GAUGE PLANE
1 2 3 4 5
0.53 ± 0.152
(.021 ± .006)
DETAIL “A”
0.86
(.034)
REF
1.10
(.043)
MAX
0.18
(.007)
NOTE:
1. DIMENSIONS IN MILLIMETER/(INCH)
2. DRAWING NOT TO SCALE
3. DIMENSION DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR GATE BURRS.
MOLD FLASH, PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
4. DIMENSION DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSIONS.
INTERLEAD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
5. LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE 0.102mm (.004") MAX
SEATING
PLANE
0.17 – 0.27
(.007 – .011)
TYP
0.50
(.0197)
BSC
0.127 ± 0.076
(.005 ± .003)
MSOP (MS) 0603
4216f
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.
23
LTC4216
U
TYPICAL APPLICATIO
VIN
5V
BACKPLANE PCB EDGE
CONNECTOR CONNECTOR
(FEMALE)
(MALE)
LONG
Z1
RSENSE
0.01Ω
RX
10Ω
CX
100nF
R5
10k
CY
330nF
M1
Si9426DY
R6
10Ω
RY
22Ω
VCC SENSEP SENSEN GATE
SHORT
RESET
SHORT
RESET
C4
22nF
FB
LTC4216
R2
10k
R4
64.9k
1%
+
VOUT
5V
CLOAD 2A
470µF
R3
10k
1%
ON
FILTER
TIMER
C1
10nF
GND
C3
68nF
LONG
GND
Z1: SMAJ6.0A
4216 F20
Figure 20. LTC4216CMS with Gate Capacitor for Slew Rate Control
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTC1421
LTC1422
LTC1642
LTC1645
LTC1647-1/LTC1647-2/
LTC1647-3
LTC4210
LTC4211
Dual Channels, Hot Swap Controller
Single Channel, Hot Swap Controller
Single Channel, Hot Swap Controller
Dual Channel, Hot Swap Controller
Dual Channel, Hot Swap Controller
Operates from 3V to 12V, Supports -12V, SSOP-24
Operates from 2.7V to 12V, SO-8
Operates from 3V to 16.5V, Overvoltage Protection up to 33V, SSOP-16
Operates from 3V to 12V, Power Sequencing, SO-8 or SO-14
Operates from 2.7V to 16.5V, SO-8 or SSOP-16
Single Channel, Hot Swap Controller
Single Channel, Hot Swap Controller
LTC4212
LTC4214
LT4220
Single Channel, Hot Swap Controller
Negative Voltage, Hot Swap Controller
Positive and Negative Voltage,
Dual Channels, Hot Swap Controller
Dual Hot Swap Controller/Sequencer
Triple Channels, Hot Swap Controller
Operates from 2.7V to 16.5V, Active Current Limiting, SOT23-6
Operates from 2.5V to 16.5V, Multifunction Current Control,
MSOP-8 or MSOP-10
Operates from 2.5V to 16.5V, Power-Up Timeout, MSOP-10
Operates from –6V to –16V, MSOP-10
Operates from ±2.7V to ±16.5V, SSOP-16
LTC4221
LTC4230
Operates from 1V to 13.5V, Multifunction Current Control, SSOP-16
Operates from 1.7V to 16.5V, Multifunction Current Control, SSOP-20
4216f
24
Linear Technology Corporation
LT/TP 0205 1K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 FAX: (408) 434-0507
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© LINEAR TECHNOLOGY CORPORATION 2005