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ADP3820AR-4.1 |ADP3820AR41ADN/a2avai±1% Precision, Single Cell Li-Ion Battery Charger
ADP3820AR-4.2 |ADP3820AR42ADIN/a4avai±1% Precision, Single Cell Li-Ion Battery Charger
ADP3820ART-4.2RL7 |ADP3820ART42RL7ADN/a1566avai±1% Precision, Single Cell Li-Ion Battery Charger
ADP3820ART-4.2-RL7 |ADP3820ART42RL7ADN/a8800avai±1% Precision, Single Cell Li-Ion Battery Charger
ADP3820ART-4.2-RL7 |ADP3820ART42RL7ADIN/a9000avai±1% Precision, Single Cell Li-Ion Battery Charger
ADP3820ART-4.2-RL7 |ADP3820ART42RL7ANYCAPN/a3219avai±1% Precision, Single Cell Li-Ion Battery Charger
ADP3820ARTZ-4.2-RL7 |ADP3820ARTZ42RL7ADN/a2400avai±1% Precision, Single Cell Li-Ion Battery Charger


ADP3820ART-4.2-RL7 ,±1% Precision, Single Cell Li-Ion Battery ChargerAPPLICATIONSVOUTLi-Ion Battery ChargersDesktop ComputersHand-Held InstrumentsADP3820Cellular Teleph ..
ADP3820ART-4.2-RL7 ,±1% Precision, Single Cell Li-Ion Battery ChargerSPECIFICATIONS IN OUT AParameter Conditions Symbol Min Typ Max UnitsINPUT VOLTAGE V 4.5 15 VINOUTPU ..
ADP3820ART-4.2-RL7 ,±1% Precision, Single Cell Li-Ion Battery ChargerGENERAL DESCRIPTIONRThe ADP3820 is a precision single cell Li-Ion battery chargeSI = 1AO50mV NDP602 ..
ADP3820ARTZ-4.2-RL7 ,±1% Precision, Single Cell Li-Ion Battery Chargerfeatures of this device include foldback currentlimit, overload recovery, and a gate-to-source volt ..
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ADP3820AR-4.1-ADP3820AR-4.2-ADP3820ART-4.2RL7-ADP3820ART-4.2-RL7-ADP3820ARTZ-4.2-RL7
±1% Precision, Single Cell Li-Ion Battery Charger
REV.A
Lithium-Ion
Battery Charger
FUNCTIONAL BLOCK DIAGRAM
VIN
GATE
VOUT
GND
FEATURES

61% Total Accuracy
630 mA Typical Quiescent Current
Shutdown Current: 1 mA (Typical)
Stable with 10 mF Load Capacitor
4.5 V to 15 V Input Operating Range
Integrated Reverse Leakage Protection
6-Lead SOT-23-6 and 8-Lead SO-8 Packages
Programmable Charge Current
–208C to +858C Ambient Temperature Range
Internal Gate-to-Source Protective Clamp
APPLICATIONS
Li-Ion Battery Chargers
Desktop Computers
Hand-Held Instruments
Cellular Telephones
Battery Operated Devices
GENERAL DESCRIPTION

The ADP3820 is a precision single cell Li-Ion battery charge
controller that can be used with an external Power PMOS de-
vice to form a two-chip, low cost, low dropout linear battery
charger. It is available in two voltage options to accommodate
Li-Ion batteries with coke or graphite anodes. The ADP3820’s
high accuracy (–1%) low shutdown current (1 mA) and easy
charge current programming make this device especially attrac-
tive as a battery charge controller.
Charge current can be set by an external resistor. For example,
50 mW of resistance can be used to set the charge current to
1 A. Additional features of this device include foldback current
limit, overload recovery, and a gate-to-source voltage clamp to
protect the external MOSFET. The proprietary circuit also
minimizes the reverse leakage current from the battery if the
input voltage of the charger is disconnected. This feature elimi-
nates the need for an external serial blocking diode.
The ADP3820 operates with a wide input voltage range from
4.5 V to 15 V. It is specified over the industrial temperature
range of –20°C to +85°C and is available in the ultrasmall
6-lead surface mount SOT-23-6 and 8-lead SOIC packages.
Figure 1.Li-Ion Charger Application Circuit
ADP3820–SPECIFICATIONS1
QUIESCENT CURRENT
LINE REGULATION
SD INPUT VOLTAGE
NOTESAll limits at temperature extremes are guaranteed via correlation using standard Statistical Quality Control (SQC).Provided gate-to-source clamp voltage is not exceeded.
Specifications subject to change without notice.
CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the ADP3820 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
ABSOLUTE MAXIMUM RATINGS*

Input Voltage, VIN ␣ . . . . . . . . . . . . . . . . . . . . . . . . . . . .120 V
Enable Input Voltage . . . . . . . . . . . . . . .0.3 V to (VIN + 0.3 V)
Operating Ambient Temperature Range . . . . –20°C to +85°C
Storage Temperature Range . . . . . . . . . . . .–65°C to +150°CJA, SO-8 Package . . . . . . . . . . . . . . . . . . . . . . . . 150°C/WJA, SOT-23-6 Package . . . . . . . . . . . . . . . . . . . . 230°C/W
Lead Temperature (Soldering, 10 sec) . . . . . . . . . . . .+300°CVapor Phase (60 sec) . . . . . . . . . . . . . . . . . . . . . . . .+215°CInfrared (15 sec) . . . . . . . . . . . . . . . . . . . . . . . . . . .+220°C
ESD Rating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2 kV
*This is a stress rating only; operation beyond these limits can cause the device
to be permanently damaged.
ORDERING GUIDE

*SOT = Surface Mount Package. SO = Small Outline.
Contact the factory for availability of other output voltage options.
(VIN = [VOUT + 1 V] TA = –208C to +858C, unless otherwise noted)
PIN FUNCTION DESCRIPTIONS
PIN CONFIGURATIONS
SO-8 RT-6 (SOT-23-6)
NC = NO CONNECT
GATE
VIN
GND
VOUT
GND
VOUT
VIN
GATE
ADP3820
–Typical Performance Characteristics
ILOAD – mA
OUTPUT VOLTAGE – V
4.095

Figure 2.VOUT vs. ILOAD (VIN = 5.1 V)*

OUTPUT VOLTAGE – V
INPUT VOLTAGE – V

Figure 3.VOUT vs. VIN (ILOAD = 1 A)*

OUTPUT VOLTAGE – V
INPUT VOLTAGE – V

Figure 4.VOUT vs. VIN (ILOAD = 10 mA)*
INPUT VOLTAGE – V
GND
– mA
ILOAD = 10mA

Figure 5.IGND vs. VIN (ILOAD = 10 mA)*

INPUT VOLTAGE – V
GND
– mA13
0.750

Figure 6.IGND vs. VIN (ILOAD = 1 A)*

ILOAD – mA
GND
– mA
0.600

Figure 7.IGND vs. ILOAD (VIN = 5.1 V)*
TEMPERATURE – 8C
IGND
– mA204060
0.600

Figure 8.Quiescent Current vs. Temperature*

INPUT VOLTAGE – V123454321
OUTPUT VOLTAGE – V
3.5

Figure 9.Power-Up/Power-Down*
OUTPUT
VOLTAGE – V
INPUT
VOLTAGE – V

Figure 10.Line Transient Response (10 mF Output Cap)*

TEMPERATURE – 8C
OUTPUT VOLTAGE – V204060
4.070

Figure 11.VOUT vs. Temperature, VIN = 5.1 V, ILOAD = 10 mA*

FREQUENCY – Hz
–100101M
PSRR – dB
1001k10k100k
10M

Figure 12.Ripple Rejection*

ILOAD – mA
OUTPUT VOLTAGE – V6080100120
1.000

Figure 13.Current Limit Foldback*
ADP3820
APPLICATION INFORMATION

The ADP3820 is very easy to use. A P-channel power MOS-
FET and a small capacitor on the output is all that is needed to
form an inexpensive Li-Ion battery charger. The advantage of
using the ADP3820 controller is that it can directly drive a
PMOS FET to provide a regulated output current until the
battery is charged. When the specified battery voltage is reached,
the charge current is reduced and the ADP3820 maintains the
maximum specified battery voltage accurately.
When fully charged, the circuit in Figure 1 works like a well
known linear regulator, holding the output voltage within the
specified accuracy as needed by single cell Li-Ion batteries. The
output is sensed by the VOUT pin. When charging a discharged
battery, the circuit maintains a set charging current determined
by the current sense resistor until the battery is fully charged,
then reduces it to a trickle charge to keep the battery at the
specified voltage. The voltage drop across the RS current sense
resistor is sensed by the IS input of the ADP3820. At minimum
battery voltage or at shorted battery, the circuit reduces this
current (foldback) to limit the dissipation of the FET (see Fig-
ure 13). Both the VIN input and VOUT sense pins of the IC need
to be bypassed by a suitable bypass capacitor.
A 6 V gate-to-source voltage clamp is provided by the ADP3820
to protect the MOSFET gates at higher source voltages. The
ADP3820 also has a TTL SD input, which may be connected to
the input voltage to enable the IC. Pulling it to low or to
ground will disable the FET-drive.
Design Approach

Due to the lower efficiency of Linear Regulator Charging, the
most important factor is the thermal design and cost, which is
the direct function of the input voltage, output current and
thermal impedance between the MOSFET and the ambient
cooling air. The worse-case situation is when the battery is
shorted since the MOSFET has to dissipate the maximum power.
A tradeoff must be made between the charge current, cost and
thermal requirements of the charger. Higher current requires a
larger FET with more effective heat dissipation leading to a
more expensive design. Lowering the charge current reduces
cost by lowering the size of the FET, possibly allowing a smaller
package such as SOT-23-6. The following designs consider both
options. Furthermore, each design is evaluated under two input
source voltage conditions.
Regarding input voltage, there are two options:The input voltage is preregulated, e.g., 5 V – 10%The input voltage is not a preregulated source, e.g., a wall
plug-in transformer with a rectifier and capacitive filter.
Higher Current Option
A. Preregulated Input Voltage (5 V 6 10%)

For the circuit shown in Figure 1, the required qJA thermal
impedance can be calculated as follows: if the FET data sheet
allows a max FET junction temperature of TJMAX = 150°C, then
at 50°C ambient and at convection cooling, the maximum al-
lowed DT junction temperature rise is thus, TJMAX – TAMAX =
150°C – 50°C = 100°C.
The maximum current for a shorted or discharged battery is
ADP3820. This k factor between VO of 0 V to about 2.5 V is:
k ~ 0.65.JA = DT/(IO · k · VIN) = 100/(1 · 0.65 · 5) = 30.7°C/W
This thermal impedance can be realized using the transistor
shown in Figure 1 when surface mounted to a 40 · 40 mm
double-sided PCB with many vias around the tab of the surface-
mounted FET to the backplane of the PCB. Alternatively, a
TO-220 packaged FET mounted to a heatsink could be used.
The q or thermal impedance of a suitable heatsink is calculated
below: < (qJA – qJC) = 30.7 – 2 = +28.7°C/W
Where the qJC, or junction-to-case thermal impedance of the
FET can be read from the FET data sheet. A low cost such
heatsink is type PF430 made by Thermalloy, with a q =
+25.3°C/W.
The current sense resistor for this application can be simply
calculated:
RS = VS /IO = 0.05/1 = 50 mW
Where VS is specified on the data sheet as current limit threshold
voltage at 40 mV–75 mV. For battery charging applications, it
is adequate to use the typical 50 mV midvalue.
B. Nonpreregulated Input Voltage

If the input voltage source is, for example, a rectified and
capacitor-filtered secondary voltage of a small wall plug-in
transformer, the heatsinking requirement is more demanding.
The VINMIN should be specified 5 V, but at the lowest line volt-
age and full load current. The required thermal impedance can
be calculated the same way as above, but here we have to use
the maximum output rectified voltage, which can be substan-
tially higher than 5 V, depending on transformer regulation and
line voltage variation. For example, if VINMAX is 10 VJA = DT/(IO · k · VINMAX) = 100/(1 · 0.65 · 10) = +15.3°C/W
The q suitable heatsink thermal impedance: < qJA – qJC = 15.3 – 2 = 13.3°C/W
A low cost heatsink is Type 6030B made by Thermalloy, with a = +12.5°C/W.
Lower Current Option
A. Preregulated Input Voltage (5 V 6 10%)

If lower charging current is allowed, the qJA value can be increased,
and the system cost decreased. The lower cost is assured by
using an inexpensive MOSFET with, for example, a NDT452P
in a SOT-23-6 package mounted on a small 40 · 40 mm area
on double-sided PCB. This provides a convection cooled ther-
mal impedance of qJA = +55°C/W, presuming many vias are
used around the FET to the backplane. Allowing a maximum
FET junction temperature of +150°C, at +50°C ambient, and
at convection cooling the maximum allowed heat rise is thus
150°C–50°C = 100°C.
The maximum foldback current allowed:
IFB = DT/(q · VIN) = 100/(55 · 5) = 0.33 A
Thus the full charging current:
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