ONSEMI NIS5102QP2HT1G

NIS5102
High Side
SMART HotPlugE IC/Inrush
Limiter/Circuit Breaker
The NIS5102 is a controller/FET IC that saves design time and
reduces the number of components required for a complete hot swap
application. It is designed for +12 V applications.
This chip includes a time delay for sequencing applications. It has a
dual function OVLO pin that allows multiple units to be ganged
together for simultaneous turn−on and shutdown, allowing units to be
operated in parallel. It allows for user selectable undervoltage and
overvoltage lockout levels. Its unique current limit circuit allows for
adjustable current limit levels with no external power resistor. An
internal temperature limiting circuit greatly increases the reliability of
this device.
Features
•
•
•
•
•
•
•
•
•
•
Integrated Power Device
Power Device Thermally Protected
No External Current Shunt Required
Simultaneous Shutdown and Startup for Parallel Operation
Enable/Timer Pin
Power Good
9.0 to 18 V Input Range
10 mW
Main/Mirror MOSFET Current Ratio 1000:1
Pb−Free Packages are Available
Typical Applications
• High Availability Systems
• Electronic Circuit Breaker
• 12 V Distributed Architecture
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Î
Î
Î
ÎÎ
MARKING
DIAGRAM
1
5102QPxH
AWLYWWG
9x9 MM, 12 PIN PLLP
CASE 488AB
x
A
WL
Y
WW
G
= 1 or 2
= Assembly Location
= Wafer Lot
= Year
= Work Week
= Pb−Free
PIN CONNECTIONS
12
1
2
11
10
13
3
9
4
8
5
7
6
(Bottom View)
ORDERING INFORMATION
Device
NIS5102QP1HT1
(Latchoff)
Package
Shipping †
9x9 mm 1500/Tape & Reel
12 Pin PLLP
NIS5102QP1HT1G 12 Pin PLLP 1500/Tape & Reel
(Latchoff)
(Pb−Free)
NIS5102QP2HT1
(Auto−Retry)
9x9 mm 1500/Tape & Reel
12 Pin PLLP
NIS5102QP2HT1G 12 Pin PLLP 1500/Tape & Reel
(Auto−Retry)
(Pb−Free)
†For information on tape and reel specifications,
including part orientation and tape sizes, please
refer to our Tape and Reel Packaging Specifications
Brochure, BRD8011/D.
© Semiconductor Components Industries, LLC, 2006
October, 2006 − Rev. 5
1
Publication Order Number:
NIS5102/D
NIS5102
VCC
13
Voltage
Regulator
Ccharge
5
Charge
Pump
Current
Limit
Thermal
Shutdown
10, 11, 12
Source
Undervoltage
Lockout
2
UVLO
6 Current Limit
7 Power Good
Common
Shutdown
1
OVLO
Overvoltage
Shutdown
Power
Good
Enable/
Timer
4 GND
3
Enable/Timer
Figure 1. Block Diagram
PIN FUNCTION DESCRIPTION
Pin
Function
Description
1
OVLO
The overvoltage shutdown point is programmed by a resistor from this pin to the VCC supply. When
tied together with other devices, this pin also communicates a shutdown state due to undervoltage
and overtemperature reasons. All devices connected will simultaneously shutdown. Startup for this
condition may be simultaneous or sequenced.
2
UVLO
A resistor from VCC to the UVLO pin adjusts the voltage at which the device will turn on.
3
Enable/Timer
4
Ground
Negative input voltage to the device. This is used as the internal reference for the IC.
5
Ccharge
An external capacitor is required from this pin to the source pin. This is the storage capacitor for the
internal charge pump. A small internal capacitor is included for noise filtering.
6
ILIMIT
7
Power Good
8, 9
No Connection
10, 11, 12
Source
13
VCC
A high level signal on this pin allows the device to begin operation. Connection of a capacitor will
delay turn on for timing purposes. A low input signal inhibits the operation, and communicates to any
other paralleled devices (via the OVLO pin) to shutdown. This signal can also be used to reset the
thermal latch.
A resistor (RLIMIT) tied from this pin to the source pin sets the current limit level.
A high impedance signal on this pin indicates that the power device is conducting.
−
Source of power FET, which is also the switching node for the load.
Positive input voltage to the device.
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NIS5102
MAXIMUM RATINGS (TA = 25°C unless otherwise noted)
Rating
Symbol
Value
Unit
Input Voltage, Operating, Steady−State (Input + to Input −)
Vin
−0.3 to 18
V
Input Voltage, Operating, Transient (Input + to Input −), 1 second
Vin
−0.3 to 25
V
Drain Voltage, Operating, Steady−State (Drain to Input −)
VDD
−0.3 to 18
V
Drain Voltage, Operating, Transient (Drain to Input −), 1 second
VDD
−0.3 to 25
V
Drain Current, Peak
IDpk
20
A
IDavg
10
A
Vmax7
20
V
76.5
41.2
°C/W
°C/W
3.2
°C/W
Continuous Current (TA = 25°C, 0.5
in2
pad)
Voltage on Power Good Pin (Pin 7)
Thermal Resistance, Junction−to−Air
0.5 in2 Copper
1 in2 Copper
QJA
Thermal Resistance, Junction−to−Lead
QJL
Power Dissipation (TA = 25°C, 0.5
in2
Pmax
1.4
W
Operating Temperature Range (Note 1)
pad)
TJ
−40 to 175
°C
Non−Operating Temperature Range
TJ
−55 to 175
°C
Lead Temperature, Soldering (10 Sec)
TL
235
°C
Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the
Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect
device reliability.
1. Actual maximum junction temperature is limited by an internal protection circuit and will not reach the absolute maximum temperature as
specified.
ELECTRICAL CHARACTERISTICS (VCC = 12 V, RLIMIT = 36 W, CCharge = 100 pF, TJ = 25°C unless otherwise noted.)
Characteristic
Symbol
Min
Typ
Max
Unit
Tdly
−
2.0
−
ms
POWER FET
Delay Time (Enable High to IS = 100 mA)
Charging Time (IS = 100 mA to IS = 5.0 A, RLIMIT = 36 W)
tchg
−
1.0
−
ms
ON Resistance (VCC = 12 V, IS = 5.0 A) (Note 2)
RDSon
−
10
13
mW
Zero Gate Voltage Drain Current
(VDS = 12 Vdc, VGS = 0 Vdc)
IDSS1
−
−
10
mA
Zero Gate Voltage Drain Current
(VDS = 18 Vdc, VGS = 0 Vdc)
IDSS2
−
−
100
mA
−
−
−
−
pF
Shutdown Temperature (Note 3)
TSD
125
135
145
°C
Hysteresis (Note 3)
Thyst
−
40
−
°C
Von
10.05
11.15
12.30
V
Vhyst
0.45
0.62
0.75
V
Output Capacitance (VDS = 12 Vdc, VGS = 0 Vdc, f = 10 kHz)
THERMAL LIMIT
OVER/UNDERVOLTAGE
UVLO Turn−on (Input + Increasing, RextUVLO = 620 k)
UVLO Hysteresis (Input + Decreasing, RextUVLO = 620 k)
OVLO Turn−off (Input + Increasing, RextUVLO = 620 k)
Voff
14.0
16.4
19.0
V
Vhyst
0.6
0.78
1.0
V
Device Fan−out (Minimum External Resistor Value = 2.0 kW (Note 3)
Nfan
−
−
4.0
Devices
Shutdown Voltage Threshold (OVLO Pin)
VSD
0.6
0.8
−
V
Shutdown State Output Voltage (Isink = 2.0 mA)
Vlow
−
0.3
0.4
V
OVLO Hysteresis (Input + Decreasing, RextUVLO = 620 k)
PARALLEL SHUTDOWN (Alternate Function on OVLO Pin)
2. Pulse Test: Pulse width 300 ms, duty cycle 2%.
3. Verified by design.
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NIS5102
ELECTRICAL CHARACTERISTICS (continued) (VCC = 12 V, RLIMIT = 36 W, CCharge = 100 pF, TJ = 25°C unless otherwise noted.)
Characteristic
Symbol
Min
Typ
Max
Unit
Current Limit (Short Circuit, RLIMIT = 36 W)
ILIM1
3.8
4.8
5.8
A
Current Limit (Overload, RLIMIT = 36 W) (Note 3)
ILIM2
7.0
7.8
8.6
A
VENon
2.2
−
−
V
CURRENT LIMIT
ENABLE/TIMER
Enable Voltage (Turn−On)
Enable Voltage (Turn−Off)
VENoff
−
−
1.6
V
Charging Current (Into External Capacitor)
ICharge
65
77
88
mA
tdelay
−
2.2
−
ms
VCcharge
−
−
18
26
−
−
V
V
−
−
−
−
−
Low Z State Output Voltage (ISink = 2 mA)
Vpin7
−
230
300
mV
Leakage Current (Vpin7 = 12 V, High Z State)
ILeak
−
2.0
10
mA
tpwrgood
−
15
−
ms
IBias
−
1.3
2.0
mA
IBias
−
400
700
mA
Vccmin
−
8.5
9.0
V
Turn−on Delay (Time from Enable High to Isource = 100 mA)
CHARGE PUMP
CCharge (Voltage on Pin 5 with Respect to Ground)
VCC = 18 Vdc
POWER GOOD
Power Good → High Z Signal when FET is Fully Enhanced
Power Good Delay
(Time from Power FET is Fully Enhanced to Power Good FET Changing State)
TOTAL DEVICE
Bias Current (Operational, VCC = 12 V)
Bias Current (Non−operational, VCC = 7 V))
Minimum Operating Voltage
Output Current
Source Voltage
Enable/Timer
Threshold
Input
Figure 2. Timing Diagram for External Enabled Delay
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NIS5102
TYPICAL PERFORMANCE CURVES
(TA = 25°C unless otherwise noted)
14
19
Turn−off
18
Turn−on
12
17
OVLO TRIP POINT (V)
UVLO TRIP POINT (V)
13
11
Turn−off
10
16
Turn−on
15
14
13
12
11
9
10
8
200
300
400
500
600
700
800
900
9
100
1000
200
300
400
RUVLO (kW)
500
600
700
800
900 1000
ROVLO (kW)
Figure 3. UVLO Adjustment
Figure 4. OVLO Adjustment
100
10
Vin = 12 V
Rext_ILimit = 100 W
Overload
1
di/dt (A/ms)
ILimit (A)
10
Short Circuit
1
0.1
0.1
10
100
1000
0.01
10
LOAD CAPACITANCE (mF)
Figure 6. Load Capacitance vs. Output di/dt
16
14
12
85
75
RDS(on), (mW)
CASE TEMPERATURE, °C
10000
RILmit (W)
Device Reaching
Thermal Shutdown
95
1/4 sq in copper area
65
1 sq in copper area
2 sq in copper area
10
8
6
45
4
35
2
25
1000
Figure 5. Current Limit Adjustment
105
55
100
1.0
3.0
5.0
7.0
9.0
11
13
0
−40 −25 −10
CONTINUOUS CURRENT, A
5
20
35
50
65
80
95 110 125
TJ, JUNCTION TEMPERATURE, (°C)
Figure 7. Continuous Current vs. Case Temperature
(Test performed on a double−sided copper board, 1 oz)
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Figure 8. Typical RDS(on) vs. Junction
Temperature
NIS5102
TYPICAL APPLICATION CIRCUITS AND OPERATION WAVEFORMS
(TA = 25°C unless otherwise noted)
VCC
ROVLO
+
Power Good
Source
OVLO
RUVLO
RLIMIT
C
UVLO
Current
Limit
+
En/Timer
Gnd
DC−DC
Converter
Ccharge
Ccharge
Cdelay
Figure 9. Typical Applications Circuit
Input Voltage
Power Good
Delay
Input Voltage
Input Voltage
Output Voltage
Output Voltage
Power
Good
GND
Output Current
Output Current
Turn on
Delay
Figure 10. Turn−on Waveforms for 3300 mF Load
Capacitors
Device Reaching
Thermal Limit
Figure 11. Turn−on Waveforms for Shorted
Output, Latchoff Device
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NIS5102
TYPICAL APPLICATION CIRCUITS AND OPERATION WAVEFORMS (continued)
(TA = 25°C unless otherwise noted)
Input
InputVoltage
Voltage
Power
PowerGood
Good
Output Voltage
Output
Voltage
Output
OutputCurrent
Current
Device Reaching
Device
Reaching
Thermal Limit
Thermal
Limit
Figure 12. Turn−On Waveforms for Shorted Output,
Auto−Retry Device
Input
InputVoltage
Voltage
Overvoltage
Overvoltage
condition
Condition
Output Voltage
Output Voltage
Power Good
Power Good
Output
OutputCurrent
Current
Figure 13. Device Response During an Overvoltage
Condition
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NIS5102
Ccharge
Ccharge
ROVLO
Power Good
Source
Ccharge
Ccharge
Power Good
Source
OVLO
OVLO
RUVLO
RLIMIT
+
En/Timer Current
Limit
Gnd
RLIMIT
RUVLO
UVLO
+
VCC
UVLO
DC−DC
Converter
+
VCC
ROVLO
En/Timer Current
Limit
Gnd
Cdelay2
Cdelay1
Figure 14. Turn−on Sequencing Using Power Good Signal
Ccharge
Ccharge
VCC
RUVLO
Ccharge
VCC
Power Good
Power Good
Source
Source
UVLO
ROVLO
UVLO
RLIMIT
OVLO
+
En/Timer
RLIMIT
OVLO
Current
Limit
En/Timer
Gnd
Current
Limit
Gnd
+
RUVLO
Cdelay
Figure 15. Parallel Operation / Simultaneous Turn−on and Shutdown
Input Voltage
Output Voltage
Iout, Device1
Iout, Device2
Figure 16. Turn−on Waveforms for Parallel Operation
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DC−DC
Converter
DC−DC
Converter
NIS5102
OPERATING DESCRIPTION
Operation
The NIS5102 has a variety of shutdown and protection
features that make this part extremely versatile as well as
rugged. For the unit to operate, the input voltage must be
within the operating range of the part which is set by the
UVLO and OVLO bias resistors. The enable must also be
high for operation. Current and thermal limit circuits
constantly monitor the operation and will protect the unit if
either of these parameters exceeds its preset limit.
An additional shutdown method, is the use of the OVLO
pin, which can be tied in parallel. This allows multiple units
to be either operated in parallel, and will shutdown and turn
on simultaneously for any fault other than an overvoltage, or
it allows these hot plug devices to control independent loads,
and shutdown and turn on simultaneously.
reach the current limit threshold, or is shutdown due to an
overvoltage, undervoltage or thermal fault. Both the UVLO
and OVLO circuits incorporate hysteresis to assure clean
turn−on and turn−offs with no chatter. The thermal latching
circuit will require the input power to be recycled to resume
operation after a fault. The current limit is always active, so
any transient or overload will always be limited.
Circuit Description
Enable/Timer
The enable/timer pin can function either as a direct enable
pin, or as a time delay. In the enable mode, an open collector
device is connected to this pin. When the device is in its low
impedance mode, this pin is low and the operation of the chip
is disabled. If a time delay is required, a capacitor is added
to this pin. Figure 17 shows the equivalent circuit for the
enable.
Faults
Once the load capacitance is charged, the SENSEFETt
will become fully enhanced as long as the current does not
80 mA
Enable/
Timer
2.2 V
+
−
Enabled
NIS5102
Figure 17. Enable/Timer Circuit
of the internal charge pump. Once the VGS of the power
SENSEFET reaches around 90% of the internal charge
pump output voltage, the power good will change its state
from low impedance to high impedance but only after the
power good delay has elapsed. Figure 10 shows the power
good behavior during the startup of the NIS5102 device, an
external pullup resistor from power good to VCC was used.
The power good will change its state from high impedance
to low impedance in the event of any fault condition such as
short circuit and overvoltage.
If a capacitor is added without an open collector device,
the turn on will be delayed from the time at which the UVLO
voltage is reached. If an open collector device is also used,
the delay will start from the time that it goes into its high
impedance state. The capacitor is charged by an internal
current source.
There is an inherent delay in the turn on of the hot plug
device, due to the method of gate drive used. The gate of the
power FET is charged through a high impedance resistor,
and from the time that the gate starts charging until the time
that it reaches its threshold voltage, there will be no
conduction. Once the gate reaches its threshold voltage, the
output current will begin a controlled ramp up phase.
This delay will be added to any timing delay due to the
enable/timer circuit.
Undervoltage Lockout
The UVLO circuit holds the chip off when the input
voltage is less than the turn−on limit. It includes internal
hysteresis to assure clean on/off switching. An internal
divider sets the turn−on voltage level at 16 V. This voltage
can be reduced by adding an external resistor from the
UVLO pin to the VCC pin. The equivalent circuit is shown
in Figure 18.
Power Good
The power good circuit monitors the VGS voltage of the
power SENSEFET and compares it with the output voltage
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NIS5102
VCC
RUVLO
400 k
Source
UVLO
VGS(th) = 1.15 V
40 k
3k
Ground
Figure 18. Equivalent Undervoltage Lockout Circuit
The theoretical equation for the UVLO turn−on voltage is:
RUVLO (KW) +
ground. This will create a low pass filter with a cutoff
frequency of f. The required capacitance on this pin is:
400 Vin * 460
17.5 * Vin
CUVLO +
The UVLO trip point voltage calculated through the
theoretical formula may show small variations with respect
to Figure 3, therefore it is recommended to use the formulas
gotten from the UVLO characterization, which are shown
below:
1
R
· 400 K
2p · f ƪ43 K ) ǒR UVLO)400 KǓƫ
UVLO
Overvoltage Lockout and Parallel Shutdown
The overvoltage lockout (OVLO) is a dual function pin.
This pin will normally be biased somewhere between
ground and the input voltage, due to an internal voltage
divider which sets the turn−off voltage level at 22 V. This
voltage level can be reduced by adding an external resistor
from the OVLO pin to the VCC pin. When the input voltage
reaches the programmed trip point, operation of the device
is inhibited.
Figure 19 shows the equivalent circuit.
RUVLO (kW) + e [(UVLO ) 14.647)ń3.9858]; for TJ + 25°C
where “UVLO” is the desired undervoltage lockout value,
and RUVLO is the programming resistor from the UVLO pin
to the VCC pin.
To reduce nuisance tripping due to transients and noise
spikes, a capacitor may be added from the UVLO pin to
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NIS5102
VCC
ROVLO
300 k
Source
OVLO
7V
200 k
2M
Ground
Figure 19. Equivalent Overvoltage Lockout Circuit
Temperature Limit
The theoretical equation for the OVLO turn−on voltage is:
ROVLO (KW) +
The temperature limit circuit senses the temperature of the
Power FET and removes the gate drive if the maximum level
is exceeded. For the auto−retry device, there is a nominal
hysteresis of 40°C for this circuit. After a thermal shutdown,
the device will automatically restart when the temperature
drops to a safe level as determined by the hysteresis. The
latching thermal circuit can be reset either by recycling the
input power, or by toggling the enable signal.
300 Vin * 2100
21.8 * Vin
The OVLO trip point voltage calculated through the
theoretical formula may show small variations with respect
to Figure 4, therefore it is recommended to use the formulas
gotten from the OVLO characterization, which are shown
below:
ROVLO (kW) + e [(OVLO ) 5.2)ń3.46]; for TJ + 25°C
Current Limit
where “OVLO” is the desired overvoltage lockout value,
and ROVLO is the programming resistor from the OVLO pin
to the VCC pin.
To reduce nuisance tripping due to transients and noise
spikes, a capacitor may be added from the OVLO pin to
ground. This will create a low pass filter with a cutoff
frequency of f. The required capacitance on this pin is:
COVLO +
An external resistor from the current limit pin to the source
pins set the level at which the device will limit the current.
The plot of resistance vs. current limit includes two curves,
one for short circuit and one for overload.
A short circuit condition is one in which the SENSEFET
is not fully enhanced, and is therefore in a high impedance
mode of operation. In this case there are many hundreds of
millivolts across the drain to source pins of the SENSEFET.
This occurs when the output sees a very low impedance short
as well as when the capacitor is charging at turn on. In both
cases there are several volts or more across the FET.
An overload condition is one in which the SENSEFET is
still fully enhanced and the drain to source voltage is the
product of the drain current and the on resistance of the FET.
The sense voltage out of the SENSEFET has a different
relation to the drain current in these two conditions. The
difference in current limit levels for these two cases is called
DI, where:
[1 ) (8.83 E−6 · ROVLO)]
2p · f · ROVLO
This pin is also used as a common shutdown pin. In this
mode, if this pin is pulled to ground, it will shutdown the chip
and all chips connected to its OVLO pin.
The OVLO pin has an internal switch to ground that will
pull it low, whenever the device is disabled due to any fault
other than an Overvoltage condition. An enable pin
shutdown is not considered a fault and will not cause a
common shutdown. This feature allows multiple units to
turn on and off simultaneously by tying the OVLO pins
together in parallel. This can be used for operating several
hot plug devices in parallel, or for use with separate loads,
when all devices need to startup and shutdown
simultaneously.
DI + VrefńRDSon
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NIS5102
For this equation, Vref is the reference voltage of the
current limit circuit, and RDSon is the on resistance of the
SENSEFET. For more information on this, see application
note AND8140/D, “SMART HotPlugt Current Limit
Function”.
This inherent property of the SENSEFET allows for
simple dual level current limiting, in which a short circuit
condition will see a lower level of limiting than will an
overload. This operation will exist in start up as well as under
normal operation, so the device will be able to differentiate
between a short and an overload.
As with all SMART HotPlug devices, the current limit will
never shutdown the device. Only the thermal limit will stop
the flow of current to the load. Once the current is stopped due
to the thermal limit, it will remain off until input power is
recycled for the latching version, or it will continuously retry
to start again if it is the auto−retry version.
The ILimit graph shown in Figure 5 was generated from
the data of the ILimit characterization, the formula for the
short circuit curve is:
ǒ
where “ILimit” is the desired short circuit ILimit value, and
RILimit is the programming resistor from the ILimit pin to the
source pin.
Turn−on Surge
During the turn−on event, there is a large amount of
energy dissipated due to the linear operation of the power
device. The energy rating is the amount of energy that the
device can absorb before the thermal limit circuit will shut
the unit down. This is very important specially for the latch
off device as it determines the maximum load capacitance
that the device can charge before the thermal limit shuts the
device down. The calculation of this is not very simple as it
depends on several factors such as the input voltage (Vin),
load capacitance (CL), current limit settings (ILimit) and
device’s thermal transient response, therefore, it is
recommended to do lab evaluations for these purposes.
Figure 20 shows the device’s thermal transient response for
minimum pad.
Ǔ1.02 for TJ + 25°C
RILimit (W) + 152.86
ILimit
100
Min Pad
THETA J(t) (°C/W)
1−in Pad
10
1
0.1
0.00001
0.0001
0.001
0.01
0.1
1
TIME (seconds)
Figure 20. Thermal Transient Response
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10
100
1000
NIS5102
PACKAGE DIMENSIONS
PLLP−12, 9x9 mm
CASE 488AB−01
ISSUE C
NOTES:
1. DIMENSIONS AND TOLERANCING PER
ASME Y14.5M, 1994.
2. DIMENSIONS IN MILLIMETERS.
3. COPLANARITY APPLIES TO THE LEAD,
DIMENSION B, AND EXPOSED PAD.
0.10 C
0.08 C
A
B
D
PIN ONE
LOCATION
Î
Î
Î
Î
E
4X
0.15 C
SEATING
PLANE
C
DIM
A
A1
A3
b
D
E
e
D2
E2
K
L
(A3)
A1
A
TOP VIEW
STYLE 1:
PIN 1. OVLO
2. UVLO
3. ENABLE/TIMER
4. GND
5. CCHARGE
6. CURRENT LIMIT
7. POWER GOOD
8. N/C
9. N/C
10. SOURCE
11. SOURCE
12. SOURCE
SIDE VIEW
D2
10 X
12 X K
12 X L
e
E2
e/2
12 X
b
0.10
M
C A B
0.05
M
C
BOTTOM VIEW
MILLIMETERS
MIN
MAX
1.750
1.950
0.000
0.050
0.254 REF
0.400
0.600
9.000 BSC
9.000 BSC
1.270 BSC
5.400
5.600
7.400
7.600
0.850 REF
0.850
0.950
SOLDERING FOOTPRINT*
9.305
5.652
12 X
1.054
12 X
0.551
7.652
1.270 PITCH
Dimensions in mm
*For additional information on our Pb−Free strategy and soldering
details, please download the ON Semiconductor Soldering and
Mounting Techniques Reference Manual, SOLDERRM/D.
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NIS5102
The product described herein (NIS5102), may be covered by one or more of the following U.S. patents: 6,781,502; 6,865,063; 7,099,135. There may be other
patents pending. SMART HotPlug and SENSEFET are trademarks of Semiconductor Components Industries, LLC.
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice
to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.
“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All
operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights
nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications
intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should
Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates,
and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death
associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal
Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.
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ON Semiconductor Website: www.onsemi.com
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NIS5102/D