Analogic AAT3663-8.4-1 1a linear li-ion battery charger for single and dual cell application Datasheet

PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
General Description
Features
The AAT3663 BatteryManager™ is a member of
AnalogicTech’s Total Power Management IC™ family.
This device is an integrated single/dual cell Lithium-Ion
(Li-Ion) / polymer battery charger IC designed to operate from USB ports or an AC adapter inputs up to an
input voltage of 13.2V.
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AAT3663 precisely regulates battery charge voltage and
current for 4.2V and 8.4V Li-Ion battery cells. The battery charging current is user programmed up to 1A by an
external resistor.
Battery charge state is continuously monitored for fault
conditions. A Digital Thermal Loop Control maintains the
maximum possible battery charging current for the optimum set of input to output power dissipation and ambient
temperature conditions. In the event of an over-current,
over-voltage, short-circuit, or over-temperature fault condition, the device will automatically shut down, thus protecting the charger and the battery under charge.
4.0V ~ 13.2V Input Voltage Range
Compatible with USB or AC Adapter Sources
Programmable Fast Charge Current from 100mA to 1A
Programmable Charge Termination Current
Digital Thermal Loop Charge Reduction
Less Than 0.4μA Battery Leakage Current
Programming Charge Timer
Battery Temperature Sensing
Battery Temp Sense Open Circuit Detection
Automatic Recharge Sequencing
Automatic Trickle Charge for Battery Pre-Conditioning
Automatic Charge Termination Shutdown/Sleep Mode
Less than 1μA Shutdown Current
Over-Voltage and Over-Current Protection
Power On Reset and Soft Start
3x3mm 14-pin TDFN Package
Applications
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Two status monitor output pins are provided to indicate
the battery charge status by directly driving external
LEDs. Additionally, an open-drain power-source detection output (ADPP#) is provided to report presence of an
input power supply
Digital Still Cameras
Global Positioning Systems (GPS)
Point Of Service (POS) Terminals
Portable DVD Players
Portable Media Players (PMP)
Two Way Radios
The AAT3663 is available in a thermally enhanced,
space-saving, 14-pin 3x3 mm TDFN package and is
specified for operation over the -40°C to +85°C temperature range.
Typical Application
ON/OFF
EN BATS
VIN
IN
BATT+
BAT
10μF
AAT3663
BATT-TEMP
STAT1
TS
STAT2
TERM
ISET
ADPP#
GND
Battery
Pack
CT
CT
3663.2008.01.1.2
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RSET
R TERM
1
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Pin Description
Pin #
Symbol
Type
1
EN
I
2
CT
I
3
ISET
I
4
5
GND
TS
I/O
I/O
6
BATS
I
7
8, 9
BAT
IN
O
I
10
STAT1
O
11
STAT2
O
12
ADPP#
O
13
TERM
I
14
N/C
Function
Enable pin, Active high with internal pull-down. If not used, pull high to the IN pin to continuously
enable the charger IC when input power is applied.
Charge timer programming pin. A 0.1μF ceramic capacitor should be connected between this pin
and GND. Connect directly to GND to disable the timer function.
Charge current programming pin. Connect a resistor between this pin and GND to program the constant fast charge current.
IC ground connection. Connect this pin to power ground.
Battery temperature sense input. Connect the Li-Ion battery pack NTC resistor terminal to this pin.
Battery voltage sense pin. Connect this pin directly to the positive battery terminal. If this function
is not used, connect to the BAT pin directly.
Battery charge output pin. Connect to the positive battery terminal.
Power supply input pin. Connect the input USB port or Adapter power source to this pin
Charge status pin, open-drain output. Connect the STAT1 LED with a series ballast resistor between
IN and this pin.
Charge status pin, open-drain output. Connect the STAT2 LED with a series ballast resistor between
IN and this pin.
Input supply power-good status pin, open-drain output. Connect the ADPP# status LED with a series
ballast resistor between IN and this pin.
Charge termination current programming input pin. Connect a resistor between this pin and GND
to program the charge termination current. When TERM is open, the termination current is 10%
(default sertting) of the set maximum charge current.
No connection.
Pin Configuration
TDFN33-14
(Top View)
EN
CT
ISET
GND
TS
BATS
BAT
2
1
14
2
13
3
12
4
11
5
10
6
9
7
8
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N/C
TERM
ADPP#
STAT2
STAT1
IN
IN
3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Absolute Maximum Ratings1
Symbol
VIN
VN
VN
TJ
TLEAD
Description
IN Continuous Voltage
STAT1, STAT2, ADPP#, EN, BAT, BATS
TS, CT, TERM, ISET
Operating Junction Temperature Range
Maximum Soldering Temperature (at Leads)
Value
Units
-0.3 to 14
-0.3 to VIN + 0.3
-0.3 to 5.5
-40 to 150
300
V
V
V
°C
°C
Value
Units
50
2
°C/W
W
Thermal Information2
Symbol
θJA
PD
Description
Maximum Thermal Resistance (TDFN3x3)
Maximum Power Dissipation
AAT3663 Feature Options
Product
Number of Battery Cells
Battery Temperature Sense
AAT3663-4.2-1
AAT3663-4.2-2
AAT3663-8.4-1
AAT3663-8.4-2
Single
Single
Dual
Dual
For Use With Any NTC Thermistor
For Use With 10kΩ NTC Thermistor
For Use With Any NTC Thermistor
For Use With 10kΩ NTC Thermistor
1. Stresses above those listed in Absolute Maximum Ratings may cause permanent damage to the device. Functional operation at conditions other than the operating conditions
specified is not implied. Only one Absolute Maximum rating should be applied at any one time.
2. Mounted on a FR4 board.
3663.2008.01.1.2
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3
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Electrical Characteristics
VIN = 5V, TA = -40 to +85°C; Unless otherwise noted, typical values are at TA = 25°C.
Symbol
Description
Operation
Input Voltage Range
VIN
Under Voltage Lockout Threshold
VUVLO
UVLO Hysteresis
Adapter Present Indicator Threshold
VADPP_TH
Voltage, VIN – VBAT
IOP
Operating Current
ISHUTDOWN Shutdown Current
ILEAKAGE
Leakage Current from BAT Pin
ENLEAKAGE EN Pin Leakage
Voltage Regulation
VBAT_EOC
ΔVBAT_EOC/
VBAT_EOC
End of Charge Voltage Regulation
Preconditioning Voltage Threshold
VRCH
Battery Recharge Voltage Threshold
Current Regulation
Charge Current Programmable Range
ICC_RANGE
Constant-Current Mode Charge
ICH_CC
Current
VISET
ISET Pin Voltage
KISET
Charge Current Set Factor: ICH_CC/ISET
VTERM
TERM Pin Voltage
Trickle-Charge Current
ICH_TERM
Charge Termination Current Threshold
Charging Devices
RDS(ON)
Charging Transistor ON Resistance
Logic Control / Protection
Input High Threshold
VEN
Input Low Threshold
Output Low Voltage
VSTAT
STAT Pin Current Sink Capability
ISTAT
4
Rising Edge
Min
Typ
Max
Units
13.2
4
V
V
mV
50
100
mV
0.35
0.4
0.4
0.6
1
1
2
mA
μA
μA
μA
4.2
8.4
4.242
8.484
4.0
3
150
VIN > VUVLO
Charge Current = 100mA
VBAT = 4.25V, EN = GND
VBAT = 4V, IN = Open
VEN = 5V
AAT3663-4.2
AAT3663-8.4
4.158
8.316
End of Charge Voltage Accuracy
VMIN
ICH_TRK
Conditions
0.5
AAT3663-4.2
AAT3663-8.4
AAT3663-4.2
AAT3663-8.4
RISET = 1.74KΩ (for 1A), VBAT = 3.6V
RISET = 17.8KΩ (for 0.1A), VBAT = 3.6V
2.5
5.0
100
900
80
Constant Current Mode, VBAT = 3.6V
RTERM = 40kΩ
TERM pin open
RTERM = 13.3 kΩ, ICH_CC ≥ 800mA
5
5
8
VIN = 5V
2.6
5.2
VBAT_EOC - 0.1
VBAT_EOC - 0.2
1000
100
2
900
0.6
10
10
10
330
%
2.7
5.4
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V
V
1000
1100
120
mA
mA
V
15
15
12
V
% ICH_CC
% ICH_CC
% ICH_CC
500
mΩ
1.6
STAT Pin Sinks 4mA
V
0.4
0.4
8
V
V
mA
3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Electrical Characteristics
VIN = 5V, TA = -40 to +85°C; Unless otherwise noted, typical values are at TA = 25°C.
Symbol
Description
Conditions
Logic Control / Protection
Output Low Voltage
VADDP#
IADPP#
ADDP# Current Sink Capability
Over-Voltage Protection Threshold
VOCP
TK
TC
TV
ITS
Over-Current Protection Threshold
Trickle Charging Time-Out
Trickle and Constant Current Mode Time-Out
Constant Voltage Mode Time-Out
Current Source from TS Pin
TS1
TS Hot Temperature Fault
TS2
TS Cold Temperature Fault
VTS1
High Temperature Threshold
VTS2
Low Temperature Threshold
TSHDN
3663.2008.01.1.2
AAT3663-4.2
AAT3663-8.4
CT = 100nF, VIN = 5V
CT = 100nF, VIN = 5V
CT = 100nF, VIN = 5V
AAT3663-2 Only
Threshold, AAT3663-2 Only
Hysteresis, AAT3663-2 Only
Threshold, AAT3663-2 Only
Hysteresis, AAT3663-2 Only
Threshold, AAT3663-1 Only
Hysteresis, AAT3663-1 Only
Threshold, AAT3663-1 Only
Hysteresis, AAT3663-1 Only
Digital Thermal Loop Entering Threshold
Digital Thermal Loop Exiting Threshold
Digital Thermal Loop Regulation
Over-Temperature Shutdown
Typ
ADPP# Pin Sinks 4mA
VOVP
TLOOP_IN
TLOOP_OUT
TREG
Min
Threshold
Hysteresis
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71
316
2.30
29.1
58.2
4.4
8.8
105
TC/8
3
3
75
331
25
2.39
25
30
2
60
2
115
85
100
140
15
Max
Units
0.4
8
V
mA
V
79
346
2.48
30.9
61.8
%VCS
Hour
Hour
Hour
μA
mV
V
mV
%VIN
%VIN
°C
°C
°C
°C
5
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Typical Characteristics—General
Constant Charging Current
vs. Set Resistor Values
Operating Current (µA)
2000
1800
1600
1400
Constant Current Mode
1200
1000
800
600
400
200
Preconditioning Mode
0
1
10
100
Constant Charge Current (mA)
Operating Current vs ISET Resistor
10000
1000
100
10
1
1
10
RSET (kΩ
Ω)
Temperature Sense Output Current
vs. Temperature
Shutdown Current vs. Input Voltage
2.40
80
Shutdown Current (µA)
79
78
77
ITS (µA)
100
RSET (kΩ
Ω)
76
75
74
73
72
71
70
2.10
85°C
1.80
25°C
1.50
1.20
0.90
-40°C
0.60
0.30
0.00
-40
-15
10
35
60
85
4
5
6
7
Temperature (°C)
8
9
10
11
12
13
14
Input Voltage (V)
Charging Transistor On Resistance
vs. Input Voltage
CT Pin Capacitance vs. Counter Timeout
600
1.0
0.9
Capacitance (µF)
500
RDS(ON) (mΩ
Ω)
85°C
400
300
200
100
-40°C
25°C
0.8
0.7
0.5
0.4
Preconditioning + Constant
Current Timeout or Constant
Voltage Timeout
0.3
0.2
0.1
0
0.0
4.0
4.4
4.8
5.2
5.6
6.0
6.4
6.8
7.2
7.6
8.0
8.4
Input Voltage (V)
6
Preconditioning Timeout
0.6
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
Timeout (h)
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3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
31.0
Temperature Sense Too Hot
Threshold (%)
Temperature Sense Too Cold Threshold Voltage
vs. Temperature
Temperature Sense Too Cold
Threshold (%)
Temperature Sense Too Hot Threshold Voltage
vs. Temperature
30.8
30.6
30.4
30.2
30.0
29.8
29.6
29.4
29.2
29.0
-40
-15
10
35
60
85
61.0
60.8
60.6
60.4
60.2
60.0
59.8
59.6
59.4
59.2
59.0
-40
-15
10
Temperature (°C)
Input High Threshold vs. Input Voltage
60
85
Input Low Threshold vs. Input Voltage
1.30
1.3
1.20
1.2
1.1
VEN(L) (V)
1.10
VEN(H) (V)
35
Temperature (°C)
-40°C
1.00
0.90
0.80
1.0
-40°C
0.9
0.8
25°C
0.70
0.7
85°C
0.60
85°C
25°C
0.6
4
5
6
7
8
9
10
11
12
13
14
Input Voltage (V)
4
5
6
7
8
9
10
11
12
13
14
Input Voltage (V)
Termination Current to Constant Current
Ratio (%) vs. Termination Resistance
50
ICH_TERM/ICH_CC (%)
45
40
35
30
25
20
15
10
5
0
0
10
20
30
40
50
60
RTERM (kΩ
Ω)
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PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Typical Characteristics—Single Cell 4.2V
End of Charge Voltage Accuracy vs. Input Voltage
End of Charge Voltage vs. Temperature
0.100
4.220
0.075
4.215
Battery Voltage (V)
End of Charge
Voltage Accuracy (%)
(VBAT_EOC = 4.2V)
0.050
0.025
0.000
-0.025
-0.050
4.210
4.205
4.200
4.195
4.190
4.185
-0.075
4.180
-0.100
4
5
6
7
8
9
10
11
12
13
-40
14
-15
Input Voltage (V)
60
85
(VIN = 5V; RSET = 8.87kΩ
Ω)
4.120
4.14
4.115
4.13
4.110
4.105
4.100
4.095
4.090
4.12
4.11
4.10
4.09
4.08
4.07
4.085
4.06
4.080
4
5
6
7
8
9
10
11
12
13
-40
14
-15
10
35
60
85
Temperature (ºC)
Input Voltage (V)
Charging Current vs. Battery Voltage
Charging Current vs. Battery Voltage
(RSET = 8.87KΩ
Ω)
1200
240
VIN = 12V
210
VIN = 13.2V
RSET = 1.78KΩ
1000
180
VIN = 5V
150
VIN = 7.5V
VIN = 9.5V
ICH (mA)
Charging Current (mA)
35
Recharge Voltage vs. Temperature
Battery Voltage (V)
Battery Voltage (V)
Recharge Threshold Voltage vs. Input Voltage
120
90
800
RSET = 3.57KΩ
600
RSET = 2.21KΩ
400
60
200
30
RSET = 8.87KΩ
0
2.3
2.5
2.7
2.9
3.1
3.3
3.5
3.7
3.9
4.1
4.3
Battery Voltage (V)
8
10
Temperature (°C)
0
2.5
2.7
2.9
3.1
3.3
3.5
3.7
3.9
4.1
4.3
Battery Voltage (V)
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3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Typical Characteristics—Single Cell 4.2V
Preconditioning Threshold Voltage vs. Temperature
2.70
2.70
2.68
2.68
Battery Voltage (V)
Battery Voltage (V)
Preconditioning Threshold Voltage vs. Input Voltage
2.66
2.64
2.62
2.60
2.58
2.56
2.54
2.66
2.64
2.62
2.60
2.58
2.56
2.54
2.52
2.52
2.50
2.50
4
5
6
7
8
9
10
11
12
13
14
-40
-15
10
Input Voltage (V)
60
85
Temperature (°C)
Preconditioning Charge Current
vs. Input Voltage
Constant Charge Current vs. Input Voltage
(RSET = 8.87KΩ
Ω)
120
240
Charge Current (mA)
RSET = 1.78kΩ
100
ICH_TRK (mA)
35
RSET = 2.21kΩ
80
60
RSET = 3.57kΩ
40
RSET = 8.87kΩ
20
230
220
210
200
VBAT = 3.3V
190
VBAT = 3.5V
VBAT = 3.9V
180
VBAT = 4.1V
170
160
0
4
5
6
7
8
9
10
11
12
13
14
5
6
7
8
9
10
11
12
13
14
Input Voltage (V)
Input Voltage (V)
3663.2008.01.1.2
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PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Typical Characteristics—Dual Cell 8.4V
End of Charge Voltage Accuracy vs. Input Voltage
End of Charge Voltage vs. Temperature
(VIN = 10V; RSET = 8.87kΩ
Ω)
0.12
8.44
0.09
8.43
Battery Voltage (V)
End of Charge Voltage Accuracy (%)
(VBAT_EOC = 8.4V)
0.06
0.03
0.00
-0.03
-0.06
-0.09
-0.12
9.0
8.42
8.41
8.40
8.39
8.38
8.37
9.6
10.2
10.8
11.4
12.0
12.6
8.36
-40
13.2
-15
Input Voltage (V)
End of Charge Voltage vs. Input Voltage
8.220
8.415
8.215
Battery Voltage (V)
Battery Voltage (V)
8.420
8.410
8.405
8.400
8.395
8.390
8.385
9.6
10.2
10.8
11.4
12.0
12.6
8.205
8.200
8.195
8.190
8.180
8
13.2
9
10
11
12
13
14
Input Voltage (V)
(VIN = 10V; RSET = 8.87KΩ
Ω)
Constant Charging Current vs. Battery Voltage
(RSET = 8.87KΩ
Ω)
8.28
Charging Current (mA)
240
8.26
Battery Voltage (V)
85
8.185
Recharge Threshold Voltage vs. Temperature
8.24
8.22
8.20
8.18
8.16
8.14
-15
10
35
60
85
210
180
150
120
90
VIN = 10V
VIN = 11V
VIN = 12V
VIN = 13.2V
60
30
0
4.9
Temperature (°C)
10
60
8.210
Input Voltage (V)
8.12
-40
35
Recharge Threshold Voltage vs. Input Voltage
(RSET = 8.87kΩ
Ω)
8.380
9.0
10
Temperature (°C)
5.3
5.7
6.1
6.5
6.9
7.3
7.7
8.1
8.5
Battery Voltage (V)
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3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Typical Characteristics—Dual Cell 8.4V
Constant Charging Current vs. Battery Voltage
Preconditioning Threshold Voltage vs. Input Voltage
5.220
1200
5.215
Battery Voltage (V)
1000
ICH (mA)
RSET = 1.78KΩ
800
RSET = 2.21KΩ
600
RSET = 3.57KΩ
400
200
5.200
5.195
5.190
5.185
RSET = 8.87KΩ
0
4.9
5.210
5.205
5.180
5.3
5.7
6.1
6.5
6.9
7.3
7.7
8.1
8.5
8
9
Battery Voltage (V)
12
13
14
Constant Charge Current vs. Input Voltage
(RSET = 8.87KΩ
Ω)
5.24
240
5.23
230
Charge Current (mA)
Battery Voltage (V)
11
Input Voltage (V)
Preconditioning Threshold Voltage vs. Temperature
5.22
5.21
5.20
5.19
5.18
5.17
5.16
-40
10
220
210
200
190
VBAT = 7V
180
VBAT = 6.6V
VBAT = 8.2V
170
160
-15
10
35
60
85
9
10
11
12
13
14
Input Voltage (V)
Temperature (°C)
3663.2008.01.1.2
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PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Functional Block Diagram
Reverse Blocking
IN
BAT
CV/
Precharge
Current
Compare
Constant
Current
TERM
ADPP#
UVLO
Charge
Control
ISET
BATS
Over-Temp
Protect
Power
Detection
Charge
Status
Thermal
Loop
STAT 1
STAT 2
EN
75μA
AAT3663-2 Only
Watchdog
Timer
TS
CT
Window Comparator
GND
Functional Description
The AAT3663 is a high performance battery charger
designed to charge single/dual cell Lithium-Ion or
Lithium-Polymer batteries with up to 1000mA of current
from an external power source. It is a highly integrated
stand-alone charging solution, with the least external
components required for complete functionality.
The AAT3663 precisely regulates end of charge battery
voltage and current for single cell 4.2V and dual cell 8.4V
lithium-ion/polymer battery with a programmable constant current range from 100mA to 1A for fast charging
applications. The system has a default charge termination current set to 10 percent of the programmed fast
charge constant. The charge termination current may
also be user programmed by an external resistor.
During battery charging, the device temperature will rise.
In some cases with adapter (ADP) charging, the power
dissipation in the charge regulation pass device may
cause the junction temperature to rise and approach the
internal thermal shutdown threshold. Excessive power
dissipation is caused by the high input adapter voltage
versus the low output battery cell voltage difference at a
given constant charge current. In the event of an internal
12
over-temperature condition caused by excessive ambient
operating temperature or excessive power dissipation
conditions, the AAT3663 enables a digitally controlled
thermal loop system that will reduce the charging current
to prevent thermal shutdown. The digital thermal loop
will maintain the maximum possible battery charging
current for a given set of input to output power dissipation and ambient temperature conditions.
The digital thermal loop control is dynamic in the sense
that it will continue to adjust the battery charging current
as operating conditions change. The digital thermal loop
will reset and resume normal operation when the power
dissipation or over-temperature conditions are removed.
In the event of an over-voltage, over-current or overtemperature false condition beyond the limits of the
digital thermal loop system, the device will automatically shut down, thus protecting the charging device,
control system, and the battery under charge.
AAT3663 provides two status monitor pins, STAT1 and
STAT2. These pins are open drain MOSFET switches
intended to directly drive external LEDs to indicate the
battery charging state. A third status pin is prided to
indicate the presence of power on the input supply pin.
www.analogictech.com
3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
This open drain MOSFET switch may be used to either
power a display LED or to alert a system microcontroller
for the presence on input power.
Battery Charging Operation
Figure 1 illustrates the entire battery charging profile
and operation, which consists of three phases:
1.
2.
3.
Preconditioning (Trickle) Charge
Constant Current Charge
Constant Voltage Charge
Constant Current Charging
Trickle charging continues until the battery voltage
reaches the VMIN threshold. At this point, the AAT3663
begins constant-current fast charging. The current level
for this mode is programmed using a single resistor from
the ISET pin to ground. Programmed current can be set
at a minimum 100mA up to a maximum 1A.
Constant Voltage Charging
When power is initially applied or when a battery pack is
connected to the BAT pin, battery charging commences
after the AAT3663 checks several conditions in order to
maintain a safe charging environment. The input supply
must be above the minimum operating voltage (UVLO)
and the enable pin must be high (internally pulled
down). When the battery is connected to the BAT pin the
AAT3663 checks the condition of the battery and determines which charging mode to apply.
Battery Preconditioning
If the battery voltage is below VMIN, the AAT3663 begins
battery trickle charging by charging at 10% of the programmed constant-current. For example, if the programmed current is 500mA, then the trickle charge
current is 50mA. Trickle charging is a recommended
safety precaution for a deeply discharged cell and maximizes the charge cycle life of the battery. In addition,
charger IC power dissipation for the internal series pass
MOSFET is minimized when the input-output voltage differential is at its highest. This in turn allows the charging operation to commence over wider thermal and input
to output voltage differential conditions.
Preconditioning
Trickle Charge
Phase
Constant current charging continues until such time that
the battery voltage reaches the voltage regulation point
VBAT_REG. When the battery voltage reaches VBAT_REG, the
AAT3663 will transition to the constant-voltage mode.
The regulation voltage is factory programmed to a nominal 4.2V for the AAT3663-4.2 option and to 8.4V for the
AAT3663-8.4 option. Under default conditions with the
TERM pin not connected (open circuit), constant voltage
charging will continue until the charge current has
reduced to 10% of the programmed current. Placing a
resistor between the TERM pin and ground allows the
user to program a desired termination current.
After the charge cycle is complete, the AAT3663 turns
off the series pass device and automatically goes into a
power saving sleep mode. During this time the series
pass device will block current in both directions therefore preventing the battery discharging through the IC.
The AAT3663 will remain in sleep mode, until either the
battery terminal voltage drops below the VRCH threshold,
the charger EN pin is recycled or the charging power
source is reconnected. In all cases the AAT3663 will
monitor all battery parameters and resume charging in
the appropriate mode.
Constant Current
Charge Phase
Constant Voltage
Charge Phase
Charge Complete Voltage
I = Max CC
Regulated Current
Constant Current Mode
Voltage Threshold
Trickle Charge and
Termination Threshold
I = CC / 10
Figure 1: Current and Voltage Profile During Charging Phases.
3663.2008.01.1.2
www.analogictech.com
13
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
System Operation Flow Chart
ADP
Voltage
Power
Input
S
Voltage
ADP > VADPP
VIN>VUVLO
Power
On
Sleep
Sleep
Reset
Mode
Mode
No
Yes
Enable
Power
Select
EN=HIGH
No
FAULT
Shut
ShutDown
Down
STAT1=Off
Mode
STAT2=Off
Mode
Yes
Yes
Fault
Fault
Condition Monitoring
Power
Select
OV, OT,
V TS1<TS<VTS 2
No
Yes
Shut
Shut
Down
Down
Shut
Down
Mode
Mode
Mode
Expire
VBAT <VMIN or
Power Select
<V
BAT_REG or
IBAT >ITERM
No
Charger
Shut
Down
ShutTimer
Down
Control
Mode
Mode
Preconditioning
Test
V
VMIN >V
>V
BAT
MIN
Yes
Preconditioning
Shut
ShutDown
Down
Set
(Trickle
Charge)
Mode
Mode
BAT
No
No
Recharge
Test
VRCH >V BAT
Yes
Current Phase Test
VIN > VBAT_EOC
Yes
Constant
Shut Current
Down
Shut Down
Charge
Mode
Mode
Mode
VCH>VBAT
No
Device
Temp
. No
Device
Temp.
Monitor
Monitor
TTJ >115°C
J >110° C
Yes
Thermal Loop
Shut
Down
Shut
Down
Current
Reduction
In C.C.
Mode
Mode
Mode
Voltage Phase Test
IBAT >ITERM
IBAT> MI IN
Yes
Constant
Shut
Down
ShutVoltage
Down
Charge
Mode
Mode
Mode
Mode
No
Charge
Charge
Charge
Completed
Completed
Completed
14
www.analogictech.com
3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Application Information
vide feedback to the BATS pin from the BAT connection
with a voltage sensing accuracy loss of 1mV or less.
Adapter or USB Power Input
Constant current charge levels up to 1A may be programmed by the user when powered from a sufficient
input power source. The AAT3663 will operate over an
input voltage range from 4.0V to 13.2V. The low input
voltage capability of the AAT3663 permits charging single cell Li-Ion/Poly batteries from USB ports and lower
voltage input power sources. The high 13.2V input rating
of this device allows for the use of a wide range of input
power sources for both single and dual cell Li-Ion/Poly
applications.
Adapter Input Charge
Inhibit and Resume
The AAT3663 has an under-voltage lockout (UVLO) and
power on reset feature so that if the input supply to the
IN pin drops below the UVLO threshold, the charger will
suspend charging and shut down. When power is reapplied to the IN pin or the UVLO condition recovers, the
system charge control will assess the state of charge on
the battery cell and will automatically resume charging in
the appropriate mode for the condition of the battery.
Enable (EN)
EN is a logic input (active high) to enable the charger,
this function is internally pulled down to ground. When
the device is initially enabled or if the EN pin is cycled low
and then re-enabled, the charge control circuit will automatically reset and resume charging functions with the
appropriate charging mode based on the battery charge
state and measured battery voltage on the BATS pin.
Programming Charge Current
The constant current mode charge level is user programmed with a set resistor (RSET) connected between the
ISET pin and ground. The accuracy of the constant charge
current, as well as the preconditioning trickle charge current, is dominated by the tolerance of the set resistor
used. For this reason, a 1% tolerance metal film resistor
is recommended for the set resistor function. The constant charge current levels from 100mA to 1A may be set
by selecting the appropriate resistor value from Table 1.
Constant Charging
Current (mA)
Set Resistor
Value (kΩ)
100
200
300
400
500
600
700
800
900
1000
17.8
8.87
5.9
4.42
3.57
2.94
2.55
2.21
1.96
1.78
Battery Connection and
Battery Voltage Sensing
Battery Connection
A single or dual cell Li-Ion/Polymer battery should be
connected between the BAT pin and ground.
Battery Voltage Sensing
The BATS pin is provided to employ an accurate voltage
sensing capability to measure the positive terminal voltage at the battery cell being charged. This function
reduces measured battery cell voltage error between the
battery terminal and the charge control IC. The AAT3663
charge control circuit will base charging mode states
upon the voltage sensed at the BATS pin. The BATS pin
must be connected to the battery terminal for correct
operation. If the battery voltage sense function is not
needed, the BATS pin should be terminated directly to
the BAT pin. If there is concern of the battery sense
function inadvertently becoming an open circuit, the
BATS pin may be terminated to the BAT pin using a 10kΩ
resistor. Under normal operation, the connection to the
battery terminal will be close to 0Ω; if the BATS connection becomes an open circuit, the 10kΩ resistor will pro-
3663.2008.01.1.2
Table 1: RSET Values.
If the desired charge current level is not listed in Table
1, the RSET resistor value can be found in Figure 2 and
calculated by the following equation:
RSET = K ·
⎛VISET⎞
⎝ ICC ⎠
Where:
K = KI_SET = 900
VISET = 2V
ICC = Fast charge constant current
www.analogictech.com
15
PRODUCT DATASHEET
AAT3663
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
50
10000
45
ICH_TERM/ICH_CC (%)
CC Mode Charge Current (mA)
BatteryManagerTM
1000
100
10
40
35
30
25
20
15
10
5
0
1
1
10
100
0
10
20
40
50
60
RTERM (kΩ
Ω)
RSET (kΩ
Ω)
Figure 2: Constant Charging Current vs. RSET
Resistor Values.
Programmable Charge
Termination Current
Figure 3: Charge Termination Current (% Value of
the Programmed Fast Charge Current) vs. RTERM
Resistance.
Battery Charge Status Indication
The AAT3663 is designed with a default charge termination current set to 10 percent of the programmed fast
charge constant current level. The charge termination
current (ICH_TERM) may also be user programmed to a
level other than 10% of the set fast charge current by
connecting a set resistor (RTERM) between the TERM pin
and ground.
When the charge current under the constant voltage
charging mode drops to the charge termination threshold the device halts charging and goes into a sleep
mode. The charger will remain in the sleep mode until
the battery voltage as sensed by the BATS pin decreases
to a level below the battery recharge voltage threshold
(VRCH).
Charge termination current levels based on a
percentage of the programmed fast charge current are
shown in Figure 3.
If the desired charge termination current set resistor
(RTERM) value is not shown in Figure 3, the value may be
determined by the following equation:
ICH_TERM =
30
15µA · RTERM
· ICH_CC
2V
Where:
ICH_TERM = Charge termination current level
ICH_CC = Programmed fast charge constant current level
RTERM = TERM resistor value
The AAT3663 indicates the status of the battery under
charge using three status LED driver outputs. These
three LEDs can indicate simple functions such as input
power present, no battery charge activity, battery charging, charge complete and charge fault.
Status Indicator Display
System charging status may be displayed using one or
two LEDs in conjunction with the STAT1 and STAT2 pins
on the AAT3663. These two pins are simple open drain
N-channel MOSFET switches to connect the status LED
cathodes to ground. It is not necessary to use both display LEDs if a user simply wants to have a single LED to
show “charging” or “not charging”. This can be accomplished by just using the STAT1 pin and a single LED.
Using two LEDs and both STAT pins simply gives the user
more information for the various charging states. Refer
to Table 2 for LED display definitions.
Event Description
STAT1
STAT2
Charge enabled without battery
Flash
Flash1
Battery charging
Charging completed
Fault
ON
OFF
OFF
OFF
ON
OFF
1
Table 2: LED Status Indicator Truth Table.
1. Flashing rate depends on output capacitance.
16
www.analogictech.com
3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
The LED anodes should be connected to the charger
power source input (IN pin).
factor of 0.28. The initial thermal loop current can be
estimated by the following equation:
Input Power Present Indicator
ITLOOP = ICH_CC · 0.28
The ADDP# pin provides an additional open drain
N-channel MOSFET switch to indicate the presence of
power applied to the charger input (IN pin). This function may either be used to control an addition status LED
to give a visual indication when input power is applied.
This open drain output may also be pulled high via a pull
up resistor to provide an active low signal to a system
microcontroller to indicate the presence of applied input
power.
Status Display LED Biasing
The LED should be biased with as little current as necessary to create reasonable illumination; therefore, a ballast resistor should be placed between the LED cathode
and the STAT pin. LED current consumption will add to
the overall thermal power budget for the device package, hence it is good to keep the LED drive current to a
minimum. 2mA should be sufficient to drive most lowcost green or red LEDs. It is not recommended to exceed
8mA for driving an individual status LED.
The required ballast resistor values can be estimated
using the following formula:
RBALLAST =
(VIN - VF(LED))
ILED
(5.0V - 2.0V)
= 1.5kΩ
2mA
Note: Red LED forward voltage (VF) is typically 2.0V @
2mA.
Digital Thermal Loop Control
Due to the integrated nature of the linear charging control pass device for the adapter mode, a special thermal
loop control system has been employed to maximize
charging current under all operation conditions. The
thermal management system measures the internal circuit die temperature and reduces the fast charge current
when the device exceeds a preset internal temperature
control threshold. Once the thermal loop control becomes
active, the fast charge current is initially reduced by a
3663.2008.01.1.2
Protection Circuitry
Programmable Timer Function
The AAT3663 contains a watchdog timing circuit to shut
down charging functions in the event of a defective battery cell not accepting a charge over a preset period of
time. Typically, a 0.1μF ceramic capacitor is connected
between the CT pin and ground. When a 0.1μF ceramic
capacitor is used, the device will time out a shutdown
condition if the trickle charge mode exceeds 25 minutes
and a combined trickle charge plus constant current
mode of 3 hours. When the device transitions to the
constant voltage mode, the timing counter is reset and
will time out after an additional 3 hours if the charge
current does not drop to the charge termination level.
The AAT3663 has a battery fault detector, which, when
used in conjunction with a 0.1μF capacitor on the CT pin,
outputs a 1Hz signal with 50% duty cycle at the STAT1
pin in the event of a timeout while in the trickle charge
mode.
Example:
RBALLAST =
The thermal loop control re-evaluates the circuit die temperature every 1.5 seconds and adjusts the fast charge
current back up in small steps to the full fast charge current level or until an equilibrium current is discovered
and maximized for the given ambient temperature condition. The thermal loop controls the system charge level;
therefore, the AAT3663 will always provide the highest
level of constant current in the fast charge mode possible
for any given ambient temperature condition.
Mode
Time
Trickle Charge (TC) Time Out
Trickle Charge (TC) + Constant Current (CC)
Mode Time Out
Constant Voltage (CV) Mode Time Out
25 minutes
3 hours
3 hours
Table 3: Summary for a 0.1μF Ceramic Capacitor
Used for the Timing Capacitor.
The CT pin is driven by a constant current source and
will provide a linear response to increases in the timing
capacitor value. Thus, if the timing capacitor were to be
doubled from the nominal 0.1μF value, the timeout periods would be doubled. If the programmable watchdog
www.analogictech.com
17
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
timer function is not needed, it can be disabled by terminating the CT pin to ground. The CT pin should not be
left floating or unterminated, as this will cause errors in
the internal timing control circuit. The constant current
provided to charge the timing capacitor is very small,
and this pin is susceptible to noise and changes in capacitance value. Therefore, the timing capacitor should be
physically located on the printed circuit board layout as
close as possible to the CT pin. Since the accuracy of the
internal timer is dominated by the capacitance value, a
10% tolerance or better ceramic capacitor is recommended. Ceramic capacitor materials, such as X7R and
X5R types, are a good choice for this application.
Over-Voltage Protection
An over-voltage event is defined as a condition where
the voltage on the BAT pin exceeds the maximum battery charge voltage and is set by the overvoltage protection threshold (VOVP). If an over-voltage condition occurs,
the AAT3663 charge control will shut down the device
until the voltage on the BAT pin drops below VOVP. The
AAT3663 will resume normal charging operation after
the overvoltage condition is removed. During an overvoltage event, the STAT LEDs will report a system fault.
Over-Temperature Shutdown
The AAT3663 has a thermal protection control circuit
which will shut down charging functions once the internal
die temperature exceeds the over-temperature shutdown threshold. Once the internal die temperature falls
below the hysteresis, normal operation will resume the
previous charging state.
Battery Temperature Fault Monitoring
There are two AAT3663 temperature sense options, The
AAT3663-1 and AAT3663-2.
The AAT3663-1 option
allows of the use of any NTC resistor. For ease of use, the
AAT3663-2 option is factory set to function with typical
10kΩ NTC resistors and eliminates the need for a resistor
divider pull up to the input power source.
Regardless of the AAT3663 option selected, the internal
system control checks battery temperature before starting the charge cycle and continues to monitor the battery temperature during all stages of the charging cycle.
This is accomplished by monitoring the voltage at the TS
pin. In general, the system is intended for use with
negative temperature coefficient thermistors (NTC)
18
which are typically integrated into the battery package.
The voltage on the TS pin resulting from the resistive
load and applied current, should stay within a window
bounded by the TS1 and TS2 specification thresholds.
Refer to the Electrical Characteristics table for the TS1
and TS2 limits for a selected AAT3663 option. If the battery becomes too hot during charge cycle due to an
internal fault or excessive charge current, the NTC
thermistor will heat up and reduce in value. This in turn
will pull the TS pin voltage below than the TS1 threshold,
and indicate a battery cell temperature fault. The charging process will then be suspended until the over-temperature condition is removed, at which time charging
will resume. Conversely, if the battery under charge is
exposed to extreme cold ambient temperature condition,
the NTC thermistor may increase in value and push the
voltage on the TS pin above the TS2 threshold. In such
a case, the charge cycle will be suspended and will not
resume until the cold fault condition is removed. Both
TS1 and TS2 temperature fault conditions will be report
by the STAT1 and STAT2 LEDs.
AAT3663-1 Option
the AAT3663-1 option utilizes an internal battery temperature sensing system comprised of two comparators
which establish a voltage window for safe operation. The
thresholds for the TS operating window are bounded by
the TS1 and TS2 specifications. Referring to the electrical characteristics table in this datasheet, the TS1
threshold = 0.30 · VIN and the TS2 threshold = 0.6 · VIN.
Refer to Figure 4 for external resistor and NTC thermistor connections.
If the use of the battery temperature sense function is
not required, it may be disabled by terminating the TS
pin to IN and ground using a 10kΩ resistor divider network. If circuit power dissipation is a concern, the two
terminating resistor values may be increased to 100kΩ.
AAT3663-2 Option
Most of the commonly used NTC thermistors in Li-Ion/
Polymer battery packs are approximately 10kΩ at room
temperature (25°C). The AAT3663-2 TS pin has been
specifically designed to source 75μA of current to the
10kΩ NTC thermistor. The applied constant current
source and fixed internal TS1 and TS2 voltage thresholds
eliminate the need for a resistor divider on the TS pin.
Simply connect the 10kΩ NTC resistor between the TS
pin and ground. If the TS function is not needed for the
AAT3663-2, it may be left open (not connected).
www.analogictech.com
3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
VIN
IN
RT
AAT3663-4.2-1 or AAT3663-8.4-1
0.6xV IN
Battery Cold Fault
TS
Battery
Pack
Battery Hot Fault
RNTC
T
0.30xVIN
Figure 4: External Resistor and NTC Thermistor Application Circuit.
Thermal Considerations
2.50
The AAT3663 is offered in a 3x3mm TDFN package which
can provide up to 2.0W of power dissipation when it is
properly bonded to a printed circuit board and has a
maximum thermal resistance of 50°C/W. Many considerations should be taken into account when designing the
printed circuit board layout, as well as the placement of
the charger IC package in proximity to other heat generating devices in a given application. The ambient temperature around the charger IC will also have an effect on
the thermal limits of the battery charging operation. The
maximum limits that can be expected for a given ambient
condition can be estimated by the following discussion.
First, the maximum power dissipation for a given situation should be calculated:
PD(MAX) =
PD(MAX) (W)
2.00
1.50
1.00
0.50
0.00
0
=
=
=
=
75
100
Figure 5: Maximum Power Dissipation Before
Entering Thermal Loop.
Next, the power dissipation can be calculated by the following equation:
(TJ - TA)
θJA
(PD(MAX) - VIN · IOP)
VIN - VBAT
(TJ - TA) - V · I
IN
OP
θJA
ICH(MAX) =
VIN - VBAT
ICH(MAX) =
Maximum Power Dissipation (W)
Package Thermal Resistance (°C/W)
Thermal Loop Entering Threshold (ºC) [115ºC]
Ambient Temperature (°C)
Figure 5 shows the relationship between maximum
power dissipation and ambient temperature of AAT3663
Where:
PD
VIN
VBAT
ICH
IOP
3663.2008.01.1.2
50
TA (°C)
Where:
PD(MAX)
θJA
TJ
TA
25
=
=
=
=
Total Power Dissipation by the Device
Input Voltage
Battery Voltage as Seen at the BAT Pin
Constant Charge Current Programmed for the
Application
= Quiescent Current Consumed by the Charger IC
for Normal Operation [0.5mA]
www.analogictech.com
19
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
By substitution, we can derive the maximum charge current before reaching the thermal limit condition which
will activate digital thermal loop operation. The maximum charge current is the key factor when designing
battery charger applications.
In general, the worst case condition is when the greatest
input to output voltage drop occurs across the charger
IC. Specifically when battery voltage is charged up just
above the preconditioning voltage threshold and the
charger enters into the constant current fast charging
mode. Under this condition, the device will suffer the
maximum possible power dissipation since both the voltage difference across the device and the charge current
will be at their respective maximums. Figure 6 shows
the safe fast charge current operating region for different ambient temperatures. Exceeding these limits will
drive the charge control into digital thermal loop operation. When under digital thermal loop operation, the
device will remain active and continue to charge the battery at a reduced current level for the given ambient
condition.
1000
ICC(MAX) (mA)
800
TA = 85°C TA = 60°C
TA = 45°C
600
TA = 25°C
400
Input Capacitor
In general, it is a good design practice to place a decoupling capacitor between the IN pin and ground. An input
capacitor in the range of 1μF to 22μF is recommended.
If the source supply is unregulated, it may be necessary
to increase the capacitance to keep the input voltage
above the under-voltage lockout threshold during device
enable and when battery charging is initiated. If the
AAT3663’s input is to be used in a system with an external power supply source, such as a typical AC-to-DC wall
adapter, then a CIN capacitor in the range of 10μF should
be used. A larger input capacitor in this application will
minimize switching or power transient effects when the
power supply is “hot plugged” in.
Output Capacitor
The AAT3663 only requires a 1μF ceramic capacitor on
the BAT pin to maintain circuit stability. This value should
be increased to 10μF or more if the battery connection is
made any distance from the charger output. If the
AAT3663 is to be used in applications where the battery
can be removed from the charger, such as desktop
charging cradles, an output capacitor 10μF or greater is
recommended to reduce the effect of the charger cycling
on and off when no battery is present.
Printed Circuit Board
Layout Considerations
200
0
4
5
6
7
8
9
10
11
12
13
VIN (V)
Figure 6: Maximum Charging Current Before the
Digital Thermal Loop Becomes Active.
20
Capacitor Selection
For the best results, it is recommended to physically place
the battery pack as close as possible to the AAT3663 BAT
pin. To minimize voltage drops on the PCB, keep the high
current carrying traces adequately wide. For maximum
power dissipation of the AAT3663 3x3mm 14-pin TDFN
package, the metal substrate should be solder bonded to
the board. It is also recommended to maximize the substrate contact to the PCB ground plane layer to further
increase local heat dissipation. Refer to the AAT3663
evaluation board for a good layout example.
www.analogictech.com
3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Figure 7: AAT3663 Evaluation Board
Top (Component) Side Layout.
Figure 8: AAT3663 Evaluation Board
Bottom Side Layout.
JP1
ENABLE
JP4
VIN
Green
Red
Red
LED D3 LED D2 LED D1
1
R4 2k
R5 2k
VIN
R6 2k
4V - 13.2V
12
STAT1
STAT2
4
GND
IN
IN
GND
JP3
5
TS
JP2
ADPP#
10
9
TS
EN
11
8
C1
10μF
R7
(see note)
U1
TDFN33-14 AAT3663
EP
TERM
13
BATS
6
BAT
ISET
7
CT
2
BAT
3
C3
0.1μF
R2
R1
10k
1.74k
R3
10k
C2
10μF
GND
C1 1206 X7R 10μF 16V GRM31CR71C106KAC7L
C2 0805 X7R 10μF 10V GRM21BR71A106KE51L
Note: R2 = 10k is set the termination current, 7.5% from the constant charging current
R7 = 10k (for -1 option) R7 = open (for -2 option)
Figure 9: AAT3663 Evaluation Board Schematic Diagram.
3663.2008.01.1.2
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PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Ordering Information
Battery Cell
Voltage Option
Battery Temperature Sense
Package
Marking1
Part Number (Tape and Reel)2
Single Cell (4.2V)
Single Cell (4.2V)
Dual Cell (8.4V)
Dual Cell (8.4V)
For Use With Any NTC Thermistor
For Use With 10kΩ NTC Thermistor
For Use With Any NTC Thermistor
For Use With 10kΩ NTC Thermistor
TDFN33-14
TDFN33-14
TDFN33-14
TDFN33-14
1XXYY
ZZXYY
1YXYY
1ZXYY
AAT3663IWO-4.2-1-T1
AAT3663IWO-4.2-2-T1
AAT3663IWO-8.4-1-T1
AAT3663IWO-8.4-2-T1
All AnalogicTech products are offered in Pb-free packaging. The term “Pb-free” means semiconductor
products that are in compliance with current RoHS standards, including the requirement that lead not exceed
0.1% by weight in homogeneous materials. For more information, please visit our website at
http://www.analogictech.com/about/quality.aspx.
1. XYY = assembly and date code.
2. Sample stock is generally held on part numbers listed in BOLD.
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3663.2008.01.1.2
PRODUCT DATASHEET
AAT3663
BatteryManagerTM
1A Linear Li-Ion Battery Charger for Single and Dual Cell Applications
Package Information
TDFN33-14
Detail "A"
3.000 ± 0.050
2.500 ± 0.050
Index Area
3.000 ± 0.050
1.650 ± 0.050
Top View
Bottom View
+ 0.100
- 0.000
Pin 1 Indicator
(Optional)
0.180 ± 0.050
Side View
0.400 BSC
0.000
0.203 REF
0.750 ± 0.050
0.425 ± 0.050
Detail "A"
All dimensions in millimeters.
1. The leadless package family, which includes QFN, TQFN, DFN, TDFN and STDFN, has exposed copper (unplated) at the end of the lead terminals due to the manufacturing
process. A solder fillet at the exposed copper edge cannot be guaranteed and is not required to ensure a proper bottom solder connection.
Advanced Analogic Technologies, Inc.
3230 Scott Boulevard, Santa Clara, CA 95054
Phone (408) 737-4600
Fax (408) 737-4611
© Advanced Analogic Technologies, Inc.
AnalogicTech cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in an AnalogicTech product. No circuit patent licenses, copyrights, mask work rights, or other intellectual
property rights are implied. AnalogicTech reserves the right to make changes to their products or specifications or to discontinue any product or service without notice. Except as provided in AnalogicTech’s terms and
conditions of sale, AnalogicTech assumes no liability whatsoever, and AnalogicTech disclaims any express or implied warranty relating to the sale and/or use of AnalogicTech products including liability or warranties
relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. In order to minimize risks associated with the customer’s applications, adequate
design and operating safeguards must be provided by the customer to minimize inherent or procedural hazards. Testing and other quality control techniques are utilized to the extent AnalogicTech deems necessary to
support this warranty. Specific testing of all parameters of each device is not necessarily performed. AnalogicTech and the AnalogicTech logo are trademarks of Advanced Analogic Technologies Incorporated. All other
brand and product names appearing in this document are registered trademarks or trademarks of their respective holders.
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