ONSEMI NCP370MUAITXG

NCP370
Positive and Negative
Overvoltage Protection
with Internal Low RON
N-MOSFETs and Reverse
Charge Control Pin
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The NCP370 is an overvoltage, overcurrent and reverse control
device. Two main modes are available by setting logic pins. First mode
is Direct Mode from Wall−Adapter to the system. In this mode the
system is both positive and negative over−voltage protected up to
+28 V and down to −28 V. The wall adapter (or AC/DC charger) is
disconnected from the system if the input voltage exceeds the
overvoltage (OVLO) or undervoltage (UVLO) thresholds. At power
up, the Vout turns on 30 ms after the Vin exceeds the undervoltage
threshold.
The second mode (see Tables 1 & 2), called the Reverse Mode,
allows an external accessory to be powered by the system battery or
boost converter. Here the external accessory would be connected to the
device input (bottom connector of system) and the device battery
would be at the device output. In this case overcurrent protection is
activated to prevent accessory faults and battery discharge. Thanks to
the NCP370 using an internal NMOS, the system cost and the PCB
area of the application board are minimized.
The NCP370 provides a negative going flag (FLAG) output which
alerts the system that a fault has occurred.
In addition, the device has ESD−protected input (15 kV Air) when
bypassed with a 1 mF or larger capacitor.
Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Overvoltage Protection Up to 28 V
Negative Voltage Protection Down to −28 V
Reverse Charge Control: REV
Direct Charge Control: DIR
Overcurrent Protection
Thermal Shutdown
On−chip Low RDS(on) NMOS Transistors: Typical 130 mW
Overvoltage Lockout (OVLO)
Undervoltage Lockout (UVLO)
Soft−Start
Alert FLAG Output
Compliance to IEC61000−4−2 (Level 4)
8 kV (Contact)
15 kV (Air)
ESD Ratings: Machine Model = B
Human Body Model = 2
12 Lead TLLGA 3x3 mm Package
This is a Pb−Free Device
© Semiconductor Components Industries, LLC, 2008
December, 2008 − Rev. 2
1
MARKING
DIAGRAM
NCAI
370
ALYWG
G
1
12 PIN LLGA
MU SUFFIX
CASE 513AK
A
= Assembly Location
L
= Wafer Lot
Y
= Year
W
= Work Week
G
= Pb−Free Package
(Note: Microdot may be in either location)
IN
1
12
NC
IN
2
11
OUT
GND
3
10
FLAG
RES
4
RES
RES
NCP370
9
DIR
5
8
REV
6
7
Ilim
(Top View)
ORDERING INFORMATION
See detailed ordering and shipping information in the package
dimensions section on page 10 of this data sheet.
Typical Applications
•
•
•
•
•
Cell Phones
Camera Phones
Digital Still Cameras
Personal Digital Applications
MP3 Players
Publication Order Number:
NCP370/D
NCP370
10k
Charger
Wall Adapter
1mF
1
2
3
4
5
6
NCP370
12
IN
NC 11
IN
OUT 10
GND FLAG 9
RES
DIR 8
RES
REV 7
RES
Ilim
FLAG
DIR
REV
System
FLAG
4.7mF
Rlimit
LI+BATTERY
DIR
REV
GND
Figure 1. Typical Application Circuit
FUNCTIONAL BLOCK DIAGRAM
INPUT
OUTPUT
Gate Driver and Reverse OCP
Logic
REV
Ilim
VREF
Charge
Pump
EN
Block
UVLO
OVLO
Control
Logic
and
Timer
FLAG
Thermal
Shutdown
DIR
Figure 2. Functional Block Diagram
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2
GND
NCP370
PIN FUNCTION DESCRIPTION
Pin
Name
Type
Description
1, 2
IN
POWER
Input voltage pins. These pins are connected to the power supply. A 1 mF low ESR ceramic capacitor, or
larger, must be connected between these pins and GND. The two IN pins must be hardwired to common
supply.
3
GND
POWER
Main Ground
4
RES
INPUT
Reserved pin. This pin must be connected to GND.
5
RES
INPUT
Reserved pin. This pin must be connected to GND.
6
RES
INPUT
Reserved pin. This pin must be connected to GND.
7
Ilim
OUTPUT
Current Limit Pin. This pin provides the reference, based on the internal band−gap voltage reference, to
limit the over current, across internal N−MOSFETs, from battery to external accessory. A 1% tolerance,
or better, resistor shall be used to get the highest accuracy of the overcurrent limit.
8
REV
INPUT
Reverse Charge Control Pin. In combination with DIR, the internal N−MOSFETs are turned on if Battery
is applied on the OUT pin (See Tables 1 & 2). In reverse mode, the internal overcurrent protection is
activated. When reverse mode is disabled, the NCP370 current consumption, into OUT pin, is drastically
decreased to limit battery discharge.
9
DIR
INPUT
Direct Mode Pin. In combination with REV, the internal N−MOSFETs are turned on if a wall adapter
AC−DC is applied on the IN pins (See Tables 1 & 2). The device enters in shutdown mode when this pin
is tied to a high level and the REV pin is tied to high. In this case the output is disconnected from input.
The state of this pin does not have an impact on the fault detect of the FLAG pin.
10
FLAG
OUTPUT
Fault Indication Pin. This pin allows an external system to detect fault condition. The pin goes low when
input voltage exceeds OVLO threshold or drops below UVLO threshold, charge current from battery to
accessory exceeds current limit or internal temperature exceeds thermal shutdown limit. Since the pin is
open drain functionality, an external pull up resistor to VBat must be added (10 kW minimum value).
11
OUT
OUTPUT
Output Voltage Pin. This pin follows IN pins when “no input fault” is detected. The output is disconnected
from the VIN power supply when the input voltage is under the UVLO threshold or above OVLO threshold
or thermal shutdown limit is exceeded.In Reverse Mode, the device is supplied across OUT pin.
12
NC
NC
13
PAD1
POWER
Not Connected
The PAD1 is used to dissipate the internal MOSFET thermal energy and must be soldered to an isolated
PCB area. The area mustn’t be connected to any other potential than complete isolated one. See PCB
recommendations on page 9.
MAXIMUM RATINGS
Rating
Symbol
Value
Unit
Vminin
−30
V
Vmin
−0.3
V
Maximum Voltage (IN to GND)
Vmaxin
30
V
Maximum Voltage (OUT to GND)
Vmaxout
10
V
Vmax
7
V
RqJA
200
°C/W
Minimum Voltage (IN to GND)
Minimum Voltage (All others to GND)
Maximum Voltage (All others to GND)
Thermal Resistance, Junction−to−Air, (Note 1)
Operating Ambient Temperature Range
TA
−40 to +85
°C
TSTG
−65 to +150
°C
TJ
150
°C
ESD Withstand Voltage (IEC 61000−4−2)
Human Body Model (HBM), Model = 2, (Note 2)
Machine Model (MM) Model = B, (Note 3)
Vesd
15kV air, 8kV contact
2000V
200V
kV
V
V
Moisture Sensitivity
MSL
Level 1
Storage Temperature Range
Junction Operating Temperature
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. The RqJA is highly dependent on the PCB heat sink area (connected to PAD1). See PCB recommendation paragraph.
2. Human Body Model, 100 pF discharged through a 1.5 kW resistor following specification JESD22/A114.
3. Machine Model, 200 pF discharged through all pins following specification JESD22/A115.
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3
NCP370
ELECTRICAL CHARACTERISTICS (Vin = 5 V, Minimum/Maximum limits at −40°C < TA < +85°C unless otherwise noted. Typical
values are at TA = +25°C)
Symbols
Conditions
Min
Vin
Disable, Direct and Enhance Modes, Vout = 0 V
−28
Vinmin
Disable, Direct and Enhance Modes, Vout = 4.25V
−24
Vout
Reverse Mode
2.5
Undervoltage Lockout Threshold
UVLO
Vin falls below UVLO Threshold
(Disable, Direct and Enhance Modes)
2.6
Undervoltage Lockout Hysteresis
UVLOhyst
Vin rises above UVLO Threshold + UVLOhyst
Over voltage Lockout Threshold
NCP370MUAITXG
OVLO
Overvoltage Lockout Hysteresis
Over System Voltage Lockout
Characteristics
Input Voltage Range
Input Voltage
Output Voltage Range
Overvoltage Lockout Hysteresis
Vin to Vout Resistance
Vout to Vin Resistance
Input Standby Current
Input Supply Quiescent Current
Typ
Max
Unit
28
V
V
5.5
V
2.7
2.8
V
45
60
75
mV
Vin rises above OVLO threshold
(Disable and Direct Modes)
6.3
6.6
6.9
V
OVLOhyst
Vin falls below to OVLO − OVLOhyst
60
80
100
mV
OVLO00
Vin rises above OVLO00 Threshold Enhanced
Mode @ 25°C
7.9
8.27
8.6
V
OVLO00hyst
Vin falls below to OVLO00 − OVLO00hyst @ 25°C
80
100
145
mV
RDS(on)
Vin = 5 V, Direct Mode, Load Connected to Vout
Vin = 5 V, Direct Mode,
Load Connected to Vout @ 25°C
130
220
mW
130
200
Vout = 5 V, Reverse Mode, Accessory
Connected to Vin
Vout = 5 V, Reverse Mode, Accessory
Connected to Vin @ 25°C
130
220
130
200
No Load. Disable Mode, Vin connected
90
150
mA
RDS(on)
IddSTD
mW
IddIN
No Load. Direct Mode
200
280
mA
IddSTDOUT
Rin = 10 kW, Vout = 5.5 V, Disable Mode
0.02
1.0
mA
Reverse Mode current
IddREV
No Accessory, Vout = 4.2 V, Reverse Mode
200
315
mA
Minimum DC Current
ICHG
Output Load, Vin = 5.5 V, Direct
1.3
IREV
Accessory, Vout = 5.5 V, Reverse Modes
1.3
Overcurrent Threshold
IOCP
Vout = 4.2 V, Load on Vin, Reverse Mode, RILIM
= 0 W, 1 A/1 ms
1.35
Overcurrent Response
Iacc
Direct Accessory Short, Reverse Mode,
Vout = 4.2 V, Ilim = 1.6 A
7.0
Volflag
1.2 V < Vin < UVLO
Sink 50 mA on FLAG Pin
30
Output Standby Current
FLAG Output Low Voltage
FLAG Leakage Current
FLAGleak
DIR Voltage High
VihDIR
DIR Voltage Low
VilDIR
DIR Leakage Current
DIRleak
REV Voltage High
VihREV
REV Voltage Low
VilREV
REV Leakage Current
Thermal Shutdown Temperature
Thermal Shutdown Hysteresis
REVleak
A
1.75
2.10
%
400
Vin > OVLO, Sink 1 mA on FLAG Pin
400
Ireverse > Ilim, Sink 1 mA on FLAG Pin
400
FLAG Level = 5.5 V
1.0
V
0.55
200
1.0
V
nA
1.2
V
0.55
Vin or Vout connected
Vin and Vout disconnected
mV
nA
1.2
Vin or Vout connected
Vin and Vout disconnected
A
V
200
1.0
nA
TSD
150
°C
TSDHYST
30
°C
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4
NCP370
Characteristics
Symbols
Conditions
Min
Typ
Max
Unit
ton
From Vin > UVLO to Vout w 0.3 V
20
30
40
ms
tstart
From Vout > 0.3 V to FLAG = 1.2 V
20
30
40
ms
toff
From Vin > OVLO to Vout v 0.3 V
Vin Increasing from 5 V to 8 V at 3 V/ms
1.5
5.0
ms
Alert Delay
tstop
From Vin > OVLO to FLAG v 0.4 V See Figure
3 and 9 Vin Increasing from 5 V to 8 V at 3 V/ms
1.5
ms
Disable Time
tdis
REV = 1.2 V, From DIR = 0.4 V to 1.2 V to Vout
v 0.3 V
2.5
ms
tonREV
Vout w 2.5 V, From REV = 1.2 to 0.55 to
Vin w 0.3 V, Reverse Mode
0.6
1.2
1.8
ms
tstartREV
From Vin w 0.3 V FLAG = 1.2 V, Reverse Mode
0.6
1.2
1.8
ms
Rearming Reverse Delay
tRRD
Vout > 2.5 V, Rin = 1 W, Reverse Mode
20
30
40
ms
Over Current Regulation Time
tREG
Vout > 2.6, Vin > 0.3 V, Reverse Mode
0.5
1.2
1.8
ms
OCP Delay Time
tOCP
From Ireverse > Ilim, 1 A/1 ms
5
ms
tREVDIS
From REV = 0.55 V to 1.2 V, to Vin < 0.3 V.
Vout = 5 V
200
ms
TIMINGS
DIRECT MODE
Start Up Delay
FLAG Going Up Delay
Turn Off Delay
REVERSE MODE
Reverse Start Up Delay
Reverse FLAG Going Up Delay
Reverse Disable Time
NOTE:
Electrical parameters are guaranteed by correlation across the full range of temperature.
TYPICAL OPERATING CHARACTERISTICS
Operation
Overvoltage Lockout (OVLO)
The NCP370 provides overvoltage protection for positive
and negative voltages, up to 28 V or down to −28 V on
IN pins. At powerup, with DIR pin = low, REV = high, the
output rises 30 ms after the input rises above the UVLO. The
NCP370 provides a FLAG output, which alerts the system
that a fault has occurred. The FLAG signal rises 30 ms after
the output signal rises.
A Reverse Mode is available when an accessory is
connected on IN pins and the internal battery is applied on
the OUT pin, allowing the accessory to be powered. In this
mode, no supply must be connected on IN pins and REV pin
must be tied to low level. The NCP370 provides overcurrent
protection for the battery from current faults in the
accessory.
To protect connected systems on Vout pin from
overvoltage, the device has a built−in overvoltage lock out
(OVLO) circuit. During overvoltage condition, the output is
disabled as long as the input voltage exceeds OVLO.
Additional OVLO thresholds can be manufactured
(Please contact your ON Semiconductor representative for
availability).
FLAG output will be low since Vin is higher than OVLO.
This circuit has a 80 mV hysteresis to provide noise
immunity to transient conditions.
Oversystem Voltage Lockout (OVLO00)
A second overvoltage comparator is available for
supplying the sytem (output) by the Wall Adaptor (input) by
setting DIR = low and REV = low. The RDS(on) will be
higher during this mode allowing to handle few 10 mA.
This additional comparator allows to put higher input
voltage (OVLO = 8.27 V typical) on the NCP370 during test
production sequence (I.E: One Time Programming of the
cell phone, PDA). This parameter is 25°C guaranteed only.
Undervoltage Lockout (UVLO)
To ensure proper turn−on operation from AC/DC (or Wall
adapter charging) under any conditions, the device has a
built−in undervoltage lock out (UVLO) circuit. During
positive going slope on Vin, the output remains disconnected
from input until Vin voltage is above UVLO. The FLAG
output will be low as long as Vin has not reached UVLO
threshold. This circuit has a 60 mV hysteresis to provide
noise immunity to transient conditions.
In Reverse Mode (REV pin v 0.55 V, DIR w 1.2 V),
UVLO and OVLO comparators are inactivated.
FLAG Output
The NCP370 provides a FLAG output which alerts that a
fault has occurred. As soon as a fault state is detected by the
NCP370 (see Figure 3), the FLAG pin output goes low,
alerting the micro−controller to take appropriate action.
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5
NCP370
The FLAG pin goes low as soon the input voltage exceeds
the OVLO threshold or falls below the UVLO threshold.
When the Vin level recovers normal condition, FLAG goes
high after a time delay, tstart (see Figure 3), following the Vout
response. The FLAG pin is an open drain output and
therefore a pull up resistor (typically 1 MW, minimum
10 kW) must be connected to Battery. The FLAG level will
always reflect Vin status, even if the device is turned off (DIR
= 0).
Vin
OVLO
UVLO
Vout
FLAG
DIR
tdis
REV
> 1.2 V
ton
tstart
toff
tstop
ton
tstart
Figure 3. FLAG Pin in AC/DC Charging Mode
overvoltage condition, overcurrent condition or thermal
shutdown condition.
During over thermal condition (T°J>T°SD), output is
disconnected from input, and FLAG pin goes low.
In Reverse Mode, FLAG pin remains available, allowing
the micro−controller to appropriately process the
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6
NCP370
Vin
tonrev
Vout
Battery
Output
FLAG
DIR
REV
micro−controller
micro−controller
External Accessory ID = 1
Figure 4. FLAG status in Reverse Mode
Table 1. FLAG TABLE
DIR
REV
IN
OUT
FLAG
Status
Pass Element (Dual NMOS FET)
0
0
1.5 < Vin < UVLO or
Vin > OVLOoo
Hiz
Low
Open
0
0
UVLO < Vin < OVLOoo
= Vin−DROPOUT
High
Close
0
1
1.5 < Vin < UVLO or
Vin > OVLO
Hiz
Low
Open
0
1
UVLO < Vin < OVLO
= Vin−DROPOUT
High
Close
1
0
= Vout−DROPOUT
Vout > 2.5 V
High
Close
1
1
1.5 < Vin < UVLO or
Vin > OVLO
Hiz
Low
Open
1
1
UVLO < Vin < OVLO
Hiz
High
Open
DIR Input
Table 2. TABLE SELECTION OF CHARGE MODES
To enable Direct Charge operation (Direct Mode), the
DIR pin shall be forced to low and REV to high. A high level
on the DIR pin disconnects OUT pin from IN pin. DIR does
not over−ride an OVLO or UVLO fault (FLAG status is still
available).
DIR
REV
Mode
0
0
Enhance Mode
0
1
Direct Mode
1
0
Reverse Mode
1
1
Disable Mode
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7
NCP370
Negative Voltage and Reverse Current.
By adding external resistors in series from Ilim to GND,
the OCP value is lowered. See below table:
Typical Current clamp table:
The device protects the downstream side from negative
voltage occurring on the IN pin, down to −28 V. When a
negative voltage occurs, the output is disconnected from the
IN pins.
Table 3. OVERCURRENT THRESHOLD SELECTION
Reverse Mode
In Reverse Mode, an external accessory plugged into the
bottom connector can be powered by the internal battery of
the system.
To access to the reverse mode, DIR pin must be tied high
(> 1.2) and REV must be tied high to low (< 0.55 V).
In this case, the core of the NCP370 will be supplied by the
battery, with a 2.5 V minimum voltage and 5.5 V maximum
voltage.
In this reverse state, both OCP and thermal modes are
available.
OCP
RLIMIT
(A)
(kW)
1.6
0
1.0
14
0.5
70
During an overcurrent event, the N−MOSFETs turn off
and FLAG output goes low, allowing the micro−controller
to process the fault event and then disable reverse charge
path.
At power up (accessory is plugged on input pins), the
current is limited up to Ilim for 1.2 ms (typical), to allow
capacitor charge and limit inrush current. If the Ilim
threshold is exceeded over 1.2 ms, the device enters
OCP burst mode until the overcurrent event disappears.
After 1 ms following the plug in of the accessory, the OCP
mode is engaged. See Figure 5.
Overcurrent Protection (OCP)
This device integrates the reverse over current protection
function, from battery to external accessory.
That means the current across the internal NMOS is
limited when the value, set by the external Rlimit resistor,
exceeds IOCP.
An internal resistor is placed in series with the Ilim pin
allowing a maximum OCP value when Ilim pin is directly
connected to GND.
Vout
Vin
tonREV
tstartREV
FLAG
tREG
IREV
Ilim
REV
tRRD
ID
Drive Current in Accessory
DIR
Figure 5. Overcurrent Protection Sequence
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8
Accessory ID
Detection
NCP370
Thermal Shutdown protection
PCB Recommendations
In case of internal overheating, the integrated thermal
shutdown protection turns off the internal MOSFETs in
order to instantaneously decrease the device temperature.
The thermal threshold has been set at 150°C FLAG then
goes low to inform the MCU.
As the thermal hysteresis is 30°C, the MOSFETs will turn
on as soon the device temperature falls below 120°C.
If the fault event is still present, the temperature increase
engages the thermal shutdown again until the fault event
disappears.
Since the NCP370 integrates the 1. 3A N−MOSFETs,
PCB rules must be respected to properly evacuate the heat
out of the silicon.
From an applications standpoint, PAD1 of the NCP370
package should be connected to an isolated PCB area to
increase the heat transfer if necessary.
In any case, PAD1 should be not connected to any other
potential or GND other than the isolated extra copper
surface.
To assist in the design of the transfer plane connected to
PAD1, Figure 6 shows the copper area required with respect
to RqJA.
MAXIMUM qTA (°C/W)
250
2.5
Power Curve with
PCB cu thk 2 oz
200
150
2
Power Curve with
PCB cu thk 1 oz
100
1
qJA Curve with
PCB cu thk 2 oz
50
0
1.5
0
100
200
qJA Curve with
PCB cu thk 1 oz
300
400
500
0.5
600
0
700
COPPER HEAT SPREAD AREA (mm2)
Figure 6. Copper heat Spread Area
ESD Tests
The NCP370 conforms to the IEC61000−4−2, level 4 on
the Input pin. A 1 mF (I.E Murata GRM188R61E105KA12D)
must be placed close to the IN pins. If the IEC61000−4−2 is
not a requirement, a 100 nF/25 V must be placed between IN
and GND.
The above configuration supports 15 kV (Air) and 8 kV
(Contact) at the input per IEC61000−4−2 (level 4).
Please refer to Figure 7 for the IEC61000−4−2
electrostatic discharge waveform.
Figure 7. Ipeak = f(t)/IEC61000−4−2
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NCP370
RDS(on) and Dropout
As example: Rload = 8 W, Vin= 5 V. RDS(on) = 155 mW. Iout
= 800 mA.
Vout = 4.905 V
NMOS Losses = RDS(on) x Iout2 = 0.155 x 0.82 = 0.0992 W
The NCP370 includes two internal low RDS(on)
N−MOSFETs to protect the system, connected on OUT pin,
from overvoltage, negative voltage and reverse current
protection. During normal operation, the RDS(on)
characteristics of the N−MOSFETs give rise to low losses on
Vout pin.
DEMO BOARD
Figure 8. Evaluation Board Schematic
ORDERING INFORMATION
Device
NCP370MUAITXG
Marking
Package
Shipping†
NCAI
370
LLGA12
(Pb−Free)
3000 / Tape & Reel
†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.
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10
NCP370
PACKAGE DIMENSIONS
LLGA12 3x3, 0.5P
CASE 513AK−01
ISSUE O
PIN ONE
REFERENCE
2X
0.15 C
2X
ÇÇÇ
ÇÇÇ
ÇÇÇ
0.15 C
NOTES:
1. DIMENSIONING AND TOLERANCING PER
ASME Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETERS.
3. DIMENSION b APPLIES TO PLATED
TERMINAL AND IS MEASURED BETWEEN
0.15 AND 0.30 MM FROM TERMINAL TIP.
4. COPLANARITY APPLIES TO THE EXPOSED
PAD AS WELL AS THE TERMINALS.
A B
D
E
DIM
A
A1
b
D
D2
E
E2
e
K
L
TOP VIEW
0.10 C
A
12X
0.08 C
MILLIMETERS
MIN
MAX
0.50
0.60
0.00
0.05
0.20
0.30
3.00 BSC
2.60
2.80
3.00 BSC
1.90
2.10
0.50 BSC
0.20
−−−
0.25
0.35
SOLDERING FOOTPRINT*
A1
SIDE VIEW
C
SEATING
PLANE
3.30
D2
1
6
e
12X
0.50
1
0.50
PITCH
0.43
2.75
12X
K
E2
11X
0.30
12X
L
12
7
12X
b
BOTTOM VIEW
2.05
0.10 C A B
0.05 C
DIMENSIONS: MILLIMETERS
NOTE 3
*For additional information on our Pb−Free strategy and soldering
details, please download the ON Semiconductor Soldering and
Mounting Techniques Reference Manual, SOLDERRM/D.
The products described herein (NCP370), may be covered by one or more U.S. patents. There may be other patents pending.
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
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