EUTECH EUP8202

EUP8202-4.2/8.4
Switch Mode Li-Ion/Polymer
Battery Charger
DESCRIPTION
FEATURES
The EUP8202 is a constant current, constant voltage
Li-Ion battery charger controller that uses a current mode
PWM step-down (buck) switching architecture. With a
500kHz switching frequency, the EUP8202 provides a
small, simple and efficient solution to fast charge one
(4.2V) or two (8.4V) cell lithium-ion batteries.
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Wide Input Supply Voltage Range:
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4.7V to 20V – 4.2 Version
8.9V to 20V – 8.4 Version
500kHz Switching Frequency
End-of-Charge Current Detection Output
3 Hour Charge Termination Timer
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±1% Charge Voltage Accuracy
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±10% Charge Current Accuracy
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Low 10µA Reverse Battery Drain Current
Automatic Battery Recharge
Automatic Trickle Charging of Low Voltage
Batteries
Automatic Sleep Mode for Low Power
Consumption
Battery Temperature Sensing
Stable with Ceramic Output Capacitor
8-Lead SOP and 10-Lead TDFN Packages
RoHS Compliant and 100% Lead (Pb)-Free
The EUP8202 charges the battery in three phases:
conditioning, constant current, and constant voltage. An
external sense resistor sets the charge current with ±10%
accuracy. An internal resistor divider and precision
reference set the final float voltage to 4.2V per cell with ±
1% accuracy. An internal comparator detects the near
end-of-charge condition while an internal timer sets the
total charge time and terminates the charge cycle. The
EUP8202 automatically re-starts the charge if the battery
voltage falls below an internal threshold, 4.05V per cell.
The EUP8202 also automatically enters sleep mode when
DC supplies are removed.
The EUP8202 is available in the 8-lead SOP and 10-lead
TDFN packages.
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APPLICATIONS
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Small Notebook Computer
Portable DVD
Handheld Instruments
Typical Operating Performance
Efficiency vs Input voltage
Efficiency vs Input voltage
100
100
(Curves include input diode)
95
90
90
EFFICIENCY(%)
EFFICIENCY(%)
(Curves include input diode)
95
85
80
75
70
EUP8202-8.4
VBAT=7.0V
VBAT=8.0V
65
85
80
75
70
EUP8202-4.2
VBAT=3.8V
VBAT=4.0V
65
60
60
8
10
12
14
16
18
20
5
Input Voltage (V)
DS8202 Ver 1.1 Nov.2007
10
15
Input Voltage (V)
1
20
EUP8202-4.2/8.4
Typical Application Circuit
Figure 1. 2A Single/Dual Cells Li-Ion Battery Charger
Figure 2. 1.5A Single/Dual Cells Li-Ion Battery Charger
DS8202 Ver 1.1 Nov.2007
2
EUP8202-4.2/8.4
Block Diagram
Figure 3.
DS8202 Ver 1.1 Nov.2007
3
EUP8202-4.2/8.4
Pin Configurations
Package Type
Pin Configurations
Package Type
TDFN-10
Pin Configurations
SOP-8
Pin Description
PIN
TDFN-10
SOP-8
DESCRIPTION
Compensation, Soft-Start and Shutdown Control Pin. Charging begins when the
COMP pin reaches 850mV. The recommended compensation components are a
2.2µF (or larger) capacitor and a 0.5k series resistor. A 100µA current into the
compensation capacitor also sets the soft-start slew rate. Pulling the COMP pin
below 280mV will shut down the charger.
COMP
1
1
VCC
2
2
GATE
3
3
PGND
4
-
SGND
5
-
GND
-
4
CHRG
6
5
BAT
7
6
SENSE
8
7
NTC
9
8
NC
10
-
DS8202 Ver 1.1 Nov.2007
Positive Supply Voltage Input.
Gate Drive Output. Driver Output for the external P-Channel MOSFET. The
voltage at this pin is internally clamped to 8V below VCC, allowing a low
voltage MOSFET with gate-to-source breakdown voltage of 8V or less to be
used.
IC Ground.
Charge Status Output.
Battery Sense Input. A bypass capacitor of 22µF is required to minimize ripple
voltage. When VBAT is within 250mV of VCC, the EUP8202 is forced into sleep
mode, dropping ICC to 10µA.
Current Amplifier Sense Input. A sense resistor, RSENSE, must be connected
between the SENSE and BAT pins. The maximum charge current is equal to
100mV/RSENSE.
NTC (Negative Temperature Coefficient) Thermistor Input. With an external
10kΩ NTC thermistor to ground, this pin senses the temperature of the battery
pack and stops the charger when the temperature is out of range. To disable the
temperature qualification function, ground the NTC pin.
No Connect.
4
EUP8202-4.2/8.4
Ordering Information
Order Number
Package Type
EUP8202-42JIR1
TDFN-10
EUP8202-84JIR1
TDFN-10
EUP8202-42DIR1
SOP-8
EUP8202-84DIR1
SOP-8
Marking
xxxxx
P8202
1N
xxxxx
P8202
1P
xxxxx
P8202
1N
xxxxx
P8202
1P
EUP8202- □□ □ □ □ □
Lead Free Code
1: Lead Free 0: Lead
Packing
R: Tape & Reel
Operating temperature range
I: Industry Standard
Package Type
J: TDFN
D:SOP
Output Voltage Option
DS8202 Ver 1.1 Nov.2007
5
Operating Temperature range
-40 °C to 85°C
-40 °C to 85°C
-40 °C to 85°C
-40 °C to 85°C
EUP8202-4.2/8.4
Absolute Maximum Ratings
„
Supply Voltage (Vcc) ----------------------------------------------------------------------------------22V
GATE ----------------------------------------------------------------------------------------- (Vcc-8V) to Vcc
BAT, SENSE ------------------------------------------------------------------------------------- -0.3V to 14V
„
CHRG ,NTC -----------------------------------------------------------------------------------------
„
Operating Temperature Range ---------------------------------------------------------------- -40℃ to 85℃
Storage Temperature Range ------------------------------------------------------------------ -65℃ to 125℃
Lead Temperature (Soldering, 10sec) -------------------------------------------------------------------- 260℃
„
„
„
„
-0.3V to 8V
Electrical Characteristics (TA = 25℃, VCC = 10V, unless otherwise noted.)
Symbol
Parameter
Conditions
EUP8202-4.2
Min. Typ. Max.
Unit
DC Characteristics
VCC
ICC
VCC Supply Voltage
VCC Supply Current
4.7
20
V
Current Mode
1.5
5
mA
Shutdown Mode
1.5
5
mA
Sleep Mode
10
20
µA
4.158
4.2
4.242
V
VBAT(FLT) Battery Regulated Float Voltage 5V≦ VCC ≦ 20V 0℃≦ TA ≦85℃
VSNS(CHG) Constant Current Sense Voltage
3V≦ VBAT ≦ 4V 0℃≦ TA ≦85℃
90
100
110
mV
VSNS(TRKL) Trickle Current Sense Voltage
Trickle Charge Threshold
VTRKL
Voltage
VCC Undervoltage Lockout
VUV
Threshold Voltage
VCC Undervoltage Lockout
∆VUV
Hysteresis Voltage
Manual shutdown Threshold
VMSD
Voltage
Automatic shutdown Threshold
VASD
Voltage
ICOMP
COMP Pin Output Current
VBAT = 1V
8
15
22
mV
VBAT = Rising
2.75
2.9
3.05
V
VCC = Rising
3.9
4.2
4.5
V
ICHRG
CHRG Pin Weak Pull-Down
Current
REOC
CHRG Pin Output Low
Voltage
End-of-Charge Ratio
tTIMER
Charge time Accuracy
VCHRG
INTC
200
COMP Pin Falling
280
450
mV
VCC - VBAT
250
mV
VCOMP = 1.2V
100
µA
VCHRG = 1V
15
ICHRG = 1mA
VSNS(EOC) /VSNS(CHG)
NTC Pin Output Current
VNTC = 0.85V
VNTC-HOT
NTC Pin Thershold Voltage
(Hot)
VNTC = Falling
VNTC-COLD
NTC Pin Thershold Voltage
(Cold)
VNTC = Rising
DS8202 Ver 1.1 Nov.2007
150
mV
10
25
35
µA
20
50
mV
25
32
%
10
%
0℃≦ TA ≦50℃
75
85
95
µA
-40℃≦ TA ≦85℃
70
85
100
µA
340
360
380
mV
Hysteresis
5
2.35
Hysteresis
2.4
100
6
mV
2.45
V
mV
EUP8202-4.2/8.4
Electrical Characteristics (TA = 25℃, VCC = 10V, unless otherwise noted.)
Symbol
Parameter
Conditions
Recharge Battery Voltage Offset
VBAT(FULLCHARGD) –VRECHRG, VBAT
∆VRECHRG from Full Charged Battery
Falling
Voltage
ILEAK
CHRG Pin Leakage Current
EUP8202-4.2
Unit
Min. Typ. Max.
100
150
VCHRG= 8V, Charging Stops
200
mV
1
µA
550
kHz
100
%
Oscillator
fOSC
Switching Frequency
DC
Maximum Duty Cycle
450
500
Gate Drive
tr
Rise Time
CGATE =2000pF, 10% to 90%
20
ns
tf
Fall Time
CGATE =2000pF, 10% to 90%
50
ns
Output Clamp Voltage
VCC -VGATE ,
VCC≧9V
∆VGATE
-40℃≦ TA ≦85℃
∆VGATEHI Output High Voltage
∆VGATEHI= VCC -VGATE , VCC≧7V
∆VGATELO Output Low Voltage
∆VGATELO= VCC -VGATE , VCC≧7V
8
V
0.3
V
4.5
V
Electrical Characteristics (TA = 25℃, VCC = 12V, unless otherwise noted.)
Symbol
Parameter
Conditions
EUP8202-8.4
Min. Typ. Max.
Unit
DC Characteristics
VCC
ICC
VCC Supply Voltage
VCC Supply Current
8.9
1.5
5
mA
Shutdown Mode
1.5
5
mA
Sleep Mode
10
20
µA
8.316
8.4
8.484
V
90
100
110
mV
8
15
22
mV
4.7
5
5.3
V
7.5
8.5
V
6V≦ VBAT ≦ 8V 0℃≦ TA ≦85℃
VSNS(TRKL) Trickle Current Sense Voltage
VBAT = 1V
Trickle Charge Threshold
VTRKL
VBAT = Rising
Voltage
VCC Undervoltage Lockout
VCC = Rising
VUV
Threshold Voltage
VCC Undervoltage Lockout
∆VUV
Hysteresis Voltage
Manual shutdown Threshold
VMSD
COMP Pin Falling
Voltage
Automatic shutdown Threshold
VASD
VCC - VBAT
Voltage
ICOMP
COMP Pin Output Current
VCOMP = 1.2V
ICHRG
CHRG Pin Weak Pull-Down
Current
DS8202 Ver 1.1 Nov.2007
V
Current Mode
VBAT(FLT) Battery Regulated Float Voltage 9V≦ VCC ≦ 20V 0℃≦ TA ≦85℃
VSNS(CHG) Constant Current Sense Voltage
20
VCHRG = 1V
500
150
15
7
280
mV
450
mV
250
mV
100
µA
25
35
µA
EUP8202-4.2/8.4
Electrical Characteristics (TA = 25℃, VCC = 12V, unless otherwise noted.)
Symbol
Parameter
REOC
CHRG Pin Output Low
Voltage
End-of-Charge Ratio
tTIMER
Charge time Accuracy
VCHRG
INTC
Conditions
ICHRG = 1mA
VSNS(EOC) /VSNS(CHG)
NTC Pin Output Current
VNTC = 0.85V
VNTC-HOT
NTC Pin Thershold Voltage
(Hot)
VNTC = Falling
VNTC-COLD
NTC Pin Thershold Voltage
(Cold)
VNTC = Rising
CHRG Pin Leakage Current
5
20
50
mV
15
25
%
10
%
0℃≦ TA ≦50℃
75
85
95
µA
-40℃≦ TA ≦85℃
70
85
100
µA
340
360
380
mV
Hysteresis
5
2.35
Hysteresis
2.4
mV
2.45
100
Recharge Battery Voltage Offset
VBAT(FULLCHARGD) –VRECHRG, VBAT
∆VRECHRG from Full Charged Battery
Falling
Voltage
ILEAK
EUP8202-8.4
Unit
Min. Typ. Max.
200
300
VCHRG= 8V, Charging Stops
V
mV
400
mV
1
µA
550
kHz
100
%
Oscillator
fOSC
Switching Frequency
DC
Maximum Duty Cycle
450
500
Gate Drive
tr
Rise Time
CGATE =2000pF, 10% to 90%
20
ns
tf
Fall Time
CGATE =2000pF, 10% to 90%
50
ns
Output Clamp Voltage
VCC-VGATE ,
VCC≧9V
∆VGATE
40℃≦ TA ≦85℃
∆VGATEHI Output High Voltage
∆VGATEHI= VCC -VGATE , VCC≧7V
∆VGATELO Output Low Voltage
∆VGATELO= VCC -VGATE , VCC≧7V
DS8202 Ver 1.1 Nov.2007
8
4.5
8
V
0.3
V
V
EUP8202-4.2/8.4
Typical Operating Characteristics
Oscillator Frequency vs Temperature
Supply Current vs Vcc
2.0
(Current mode)
540
1.8
520
fosc(kHz)
Icc(mA)
1.6
1.4
500
480
1.2
460
1.0
5
10
15
-40
20
-20
0
20
40
60
80
100
120
TEMPERATURE(°C)
Vcc (V)
Undervoltage Lockout Threshold vs Temperature
Supply Current vs Temperature
4.0
9
3.5
8
3.0
7
Vuv(V)
Icc(mA)
2.5
2.0
6
EUP8202-4.2
EUP8202-8.4
5
1.5
4
1.0
3
0.5
-40
-20
0
20
40
60
80
100
-40
120
Oscillator Frequency vs Vcc
540
fosc(kHz)
520
500
480
460
5
10
15
20
Vcc (V)
DS8202 Ver 1.1 Nov.2007
-20
0
20
40
60
TEMPERATURE(°C)
TEMPERATURE(°C)
9
80
100
120
EUP8202-4.2/8.4
Typical Operating Characteristics (continued)
CHRG Pin Weak Pull-Down Current vs Vcc
CHRG Pin Output Low Voltage vs Vcc
28
30
VCHRG=8V
Iload=1mA
25
ICHRG(µV)
VCHRG(mV)
26
20
24
15
22
10
5
10
15
5
20
10
20
Recharge Voltage Offset from Full Charged
Voltage vs Vcc
CHRG Pin Output Low Voltage vs Temperature
25
160
Iload=1mA
EUP8202-4.2
20
155
VRECHARGE(mV)
V CH R G (m V )
15
Vcc (V)
Vcc (V)
15
10
5
150
145
140
-40
-20
0
20
40
60
80
100
120
5
10
15
20
Vcc (V)
TEMPERATURE(°C)
Recharge Voltage Offset from Full Charged
Voltage vs Vcc
CHRG Pin Weak Pull-Down Current vs Temperature
32
320
VCHRG=8V
EUP8202-8.4
315
30
VRECHARGE(mV)
310
ICHRG(µV)
28
26
24
305
300
295
290
285
22
280
-40
-20
0
20
40
60
80
100
120
5
DS8202 Ver 1.1 Nov.2007
10
15
Vcc (V)
TEMPERATURE(°C)
10
20
EUP8202-4.2/8.4
Typical Operating Characteristics (continued)
COMP Pin Output Current vs Vcc
Current Mode Sense Voltage vs Vcc
104
102
VCOMP=1.2V
VBAT=4.0V
EUP8202-4.2
102
ICOMP(µV)
VSNS(mV)
100
98
96
100
98
96
94
94
5
10
15
5
20
10
15
20
Vcc (V)
Vcc (V)
COMP Pin Output Current vs Temperature
Current Mode Sense Voltage vs Vcc
120
106
VCOMP=1.2V
VBAT=8V
EUP8202-8.4
118
116
104
ICOMP(µA)
VSNS(mV)
114
102
112
110
108
106
100
104
102
98
5
10
15
-40
20
Current Mode Sense Voltage vs Temperature
104
103
102
VSNS(mV)
101
100
99
98
97
96
-40
-20
0
20
40
60
80
100
120
TEMPERATURE(°C)
DS8202 Ver 1.1 Nov.2007
-20
0
20
40
60
TEMPERATURE(°C)
Vcc (V)
11
80
100
120
EUP8202-4.2/8.4
Typical Operating Characteristics (continued)
Trickle Charge Voltage vs Vcc
Trickle Charge Voltage vs Temperature
5.2
3.00
EUP8202-8.4
EUP8202-4.2
5.1
VTRKL(V)
VTRKL(V)
2.95
2.90
5.0
4.9
2.85
4.8
2.80
-40
-20
0
20
40
60
80
100
5
120
10
15
20
Vcc (V)
TEMPERATURE(°C)
Trickle Charge Sense Voltage vs Temperature
Trickle Charge Voltage vs Vcc
20
3.0
VBAT=2.5V
EUP8202-4.2
EUP8202-4.2
18
VSNS(mV)
VTRKL(V)
16
2.9
14
12
10
8
2.8
5
10
15
-40
20
0
20
40
60
80
100
120
Trickle Charge Sense Voltage vs Vcc
Trickle Charge Voltage vs Temperature
25
5.2
VBAT=2.5V
EUP8202-4.2V
EUP8202-8.4
20
VSNS(mV)
5.1
VTRKL(V)
-20
TEMPERATURE(°C)
Vcc (V)
5.0
15
10
4.9
5
4.8
-40
-20
0
20
40
60
80
100
5
120
DS8202 Ver 1.1 Nov.2007
10
15
Vcc (V)
TEMPERATURE(°C)
12
20
EUP8202-4.2/8.4
Typical Operating Characteristics (continued)
End-of-Charge Ratio vs Temperature
Trickle Charge Sense Voltage vs Temperature
22
20
EUP8202-8.4
VBAT=4V
EUP8202-8.4
18
20
16
REOC(%)
VSNS(mV)
18
14
16
12
14
10
12
8
-40
-20
0
20
40
60
80
100
-40
120
-20
0
20
40
60
80
100
120
TEMPERATURE(°C)
TEMPERATURE(°C)
End-of-Charge Ratio vs Vcc
Trickle Charge Sense Voltage vs Vcc
25
EUP8202-4.2
VBAT=4V
EUP8202-8.4V
28
20
REOC(%)
VSNS(mV)
26
15
24
10
22
5
5
10
15
5
20
10
20
End-of-Charge Ratio vs Vcc
End-of-Charge Ratio vs Temperature
22
30
EUP8202-8.4
EUP8202-4.2
28
20
REOC(%)
26
REOC(%)
15
Vcc (V)
Vcc (V)
24
18
16
22
14
20
-40
-20
0
20
40
60
80
100
5
120
DS8202 Ver 1.1 Nov.2007
10
15
Vcc (V)
TEMPERATURE(°C)
13
20
EUP8202-4.2/8.4
Typical Operating Characteristics (continued)
NTC Pin Output Current vs Temperature
NTC Pin Output Current vs Vcc
94
88
VNTC=0V
VNTC=0V
92
88
INTC(µV)
INTC(µV)
90
86
86
84
82
80
-40
-20
0
20
40
60
80
100
84
120
5
DS8202 Ver 1.1 Nov.2007
10
15
Vcc (V)
TEMPERATURE(°C)
14
20
EUP8202-4.2/8.4
Application Information
Figure 4. Operational Flow Chart
DS8202 Ver 1.1 Nov.2007
15
EUP8202-4.2/8.4
OPERATION
The EUP8202 is a constant current, constant voltage
Li-Ion battery charger controller that uses a current mode
PWM step-down (buck) switching architecture. The
charge current is set by an external sense resistor (RSENSE)
across the SENSE and BAT pins. The final battery float
voltage is internally set to 4.2V per cell. For batteries like
lithium-ion that require accurate final float voltage, the
internal 2.4V reference, voltage amplifier and the resistor
divider provide regulation with ±1% accuracy.
and the CHRG pin is forced high impedance. To restart
the charge cycle, remove and reapply the input voltage or
momentarily shut the charger down. Also, a new charge
cycle will begin if the battery voltage drops below the
recharge threshold voltage of 4.05V per cell.
When the input voltage is present, the charger can be shut
down (ICC =1.5mA) by pulling the COMP pin low. When
the input voltage is not present, the charger goes into
sleep mode, dropping ICC to 10µA. This will greatly
reduce the current drain on the battery and increase the
standby time.
A 10kΩ NTC (negative temperature coefficient)
thermistor can be connected from the NTC pin to ground
for battery temperature qualification. The charge cycle is
suspended when the temperature is outside of the 0°C to
50°C window.
APPLICATIONS INFORMATION
Figure 5.Typical Charge Profile
A charge cycle begins when the voltage at the VCC pin
rises above the UVLO level and is 250mV or more
greater than the battery voltage. At the beginning of the
charge cycle, if the battery voltage is less than the trickle
charge threshold, 2.9V for the 4.2 version and 5V for the
8.4 version, the charger goes into trickle charge mode.
The trickle charge current is internally set to 15% of the
full-scale current. If the battery voltage stays low for 30
minutes, the battery is considered faulty and the charge
cycle is terminated.
When the battery voltage exceeds the trickle charge
threshold, the charger goes into the full-scale constant
current charge mode. In constant current mode, the
charge current is set by the external sense resistor RSENSE
and an internal 100mV reference;
VSNS(CHG)
100mV
=
R SENSE
R SENSE
When the battery voltage approaches the programmed
float voltage, the charge current will start to decrease.
When the current drops to 25% (4.2 version) or 15% (8.4
version) of the full-scale charge current, an internal
comparator turns off the internal pull-down N-channel
MOSFET at the CHRG pin, and connects a weak
current source to ground to indicate a near end-of-charge
condition.
An internal 3 hour timer determines the total charge time.
After a time out occurs, the charge cycle is terminated
I CHG =
DS8202 Ver 1.1 Nov.2007
16
Undervoltage Lockout (UVLO)
An undervoltage lockout circuit monitors the input
voltage and keeps the charger off until VCC rises above
the UVLO threshold (4.2V for the 4.2 version, 7.5V for
the 8.4 version) and at least 250mV above the battery
voltage. To prevent oscillation around the threshold
voltage, the UVLO circuit has 200mV per cell of built-in
hysteresis. When specifying minimum input voltage
requirements, the voltage drop across the input blocking
diode must be added to the minimum VCC supply voltage
specification.
Trickle Charge and Defective Battery Detection
At the beginning of a charge cycle, if the battery voltage
is below the trickle charge threshold, the charger goes
into trickle charge mode with the charge current reduced
to 15% of the full-scale current. If the low-battery
voltage persists for 30 minutes, the battery is considered
defective, the charge cycle is terminated and the CHRG
pin is forced high impedance.
I TRKL =
VSNS(TRKL)
15mV
=
R SENSE
R SENSE
Shutdown
The EUP8202 can be shut down by pulling the COMP
pin to ground which pulls the GATE pin high turning off
the external P-channel MOSFET. When the COMP pin is
released, the internal timer is reset and a new charge
cycle starts. In shutdown, the output of the CHRG pin
is high impedance and the quiescent current remains at
1.5mA. Removing the input power supply will put the
charger into sleep mode. If the voltage at the VCC pin
drops below (VBAT + 250mV) or below the UVLO level,
the EUP8202 goes into a low current (ICC = 10µA) sleep
mode, reducing the battery drain current.
EUP8202-4.2/8.4
CHRG Status Output Pin
When a charge cycle starts, the CHRG pin is pulled to
ground by an internal N-channel MOSFET which is
capable of driving an LED. When the charge current
drops below the End-of-Charge threshold for more than
120µs, the N-channel MOSFET turns off and a weak
25µA current source to ground is connected to the
CHRG pin. This weak 25µA pull-down remains until
the timer ends the charge cycle, or the charger is in
manual shutdown or sleep mode.
Table1: CHRG Status Pin Summary
CHARGE STATE
CHRG Pin
Trickle Charge in Process
Strong On
Constant Current Charge in Process
Strong On
Constant Voltage Charge in Process
Strong On
Charge Suspend (Temperature)
Strong On
(remains the
same)
Timer Fault
Hi-Z
Sleep / Shutdown
Hi-Z
End of Charge
Weak On
Battery Disconnected
Weak On
After a time out occurs (charge cycle ends), the pin will
become high impedance. By using two different value
resistors, a microprocessor can detect three states from
this pin (charging, end-of-charge and charging stopped)
see Figure 6.
Figure 6. Microprocessor Interface
To detect the charge mode, force the digital output pin,
OUT, high and measure the voltage at the CHRG pin.
The N-channel MOSFET will pull the pin low even with
a 2k pull-up resistor. Once the charge current drops
below the End-of-Charge threshold, the N-channel
MOSFET is turned off and a 25µA current source is
connected to the CHRG pin. The IN pin will then be
pulled high by the 2k resistor connected to OUT. Now
force the OUT pin into a high impedance state, the
current source will pull the pin low through the 390k
resistor. When the internal timer has expired, the CHRG
DS8202 Ver 1.1 Nov.2007
17
pin changes to a high impedance state and the 390k
resistor will then pull the pin high to indicate charging
has stopped.
Gate Drive
The EUP8202gate driver can provide high transient
currents to drive the external pass transistor. The rise and
fall times are typically 20ns and 50ns respectively when
driving a 2000pF load, which is typical for a P-channel
MOSFET with RDS(ON) in the range of 50mΩ.
A voltage clamp is added to limit the gate drive to 8V
below VCC. For example, if VCC is 10V then the GATE
output will pull down to 2V max. This allows low
voltage P-channel MOSFETs with superior RDS(ON) to be
used as the pass transistor thus increasing efficiency.
Stability
Both the current loop and the voltage loop share a
common, high impedance, compensation node (COMP
pin). A series capacitor and resistor on this pin
compensates both loops. The resistor is included to
provide a zero in the loop response and boost the phase
margin. The compensation capacitor also provides a
soft-start function for the charger. Upon start-up, then
ramp at a rate set by the internal 100µA pullup current
source and the external capacitor. Battery charge current
starts ramping up when the COMP pin voltage reaches
0.85V and full current is achieved with the COMP pin at
1.3V. With a 2.2µF capacitor, time to reach full charge
current is about 10ms. Capacitance can be increased if a
longer start-up time is needed.
Automatic Battery Recharge
After the 3 hour charge cycle is completed and both the
battery and the input power supply (wall adapter) are still
connected, a new charge cycle will begin if the battery
voltage drops below 4.05V per cell due to self-discharge
or external loading. This will keep the battery capacity at
more than 80% at all times without manually restarting
the charge cycle.
Battery Temperature Detection
A negative temperature coefficient (NTC) thermistor
located close to the battery pack can be used to monitor
battery temperature and will not allow charging unless
the battery temperature is within an acceptable range.
Connect a 10kΩ thermistor from the NTC pin to ground.
If the temperature rises to 50°C, the resistance of the
NTC will be approximately 4.2kΩ. With the 85µA
pull-up current source, the Hot temperature voltage
threshold is 360mV. For Cold temperature, the voltage
threshold is set at 2.4V which is equal to 0°C (RNTC ≅
28kΩ) with 85µA of pull-up current. If the temperature is
outside the window, the GATE pin will be pulled up to
VCC and the timer frozen while the output status at the
CHRG pin remains the same. The charge cycle begins
or resumes once the temperature is within the acceptable
EUP8202-4.2/8.4
range. Short the NTC pin to ground to disable the
temperature qualification feature. However the user may
modify these thresholds by adding two external resistor.
See figure 8.
for filtering and has the necessary RMS current rating.
Switching ripple current splits between the battery and
the output capacitor depending on the ESR of the output
capacitor and the battery impedance. EMI considerations
usually make it desirable to minimize ripple current in
the battery leads. Ferrite beads or an inductor may be
added to increase battery impedance at the 500kHz
switching frequency. If the ESR of the output capacitor is
0.2Ω and the battery impedance is raised to 4Ω with a
bead or inductor, only 5% of the current ripple will flow
in the battery.
Design Example
As a design example, take a charger with the following
specifications:
For single cell charge, VIN = 5V to 20V, VBAT = 4V
nominal, IBAT =1.5A, fOSC = 500kHz, IEOC=0.375A, see
Figure 2.
Figure 7. Temperature Sensing Configuration
First, calculate the SENSE resistor :
R SENSE =
Choose the inductor for about 65% ripple current at the
maximum VIN:
4V 
4V

L=
 = 6.56 µH
1 −
(500 kHz )(0.65)(1.5A )  20V 
Figure 8. Temperature Sensing Thresholds
Input and Output Capacitors
Since the input capacitor is assumed to absorb all input
switching ripple current in the converter, it must have an
adequate ripple current rating. Worst-case RMS ripple
current is approximately one-half of output charge
current. Actual capacitance value is not critical. Solid
tantalum capacitors have a high ripple current rating in a
relatively small surface mount package, but caution must
be used when tantalum capacitors are used for input
bypass. High input surge currents can be created when
the adapter is hot-plugged to the charger and solid
tantalum capacitors have a known failure mechanism
when subjected to very high turn-on surge currents.
Selecting the highest possible voltage rating on the
capacitor will minimize problems. Consult with the
manufacturer before use.
The selection of output capacitor COUT is primarily
determined by the ESR required to minimize ripple
voltage and load step transients. The output ripple ∆VOUT
is approximately bounded by:



∆VOUT ≤ ∆I L  ESR +
1
8f OSC C OUT




Since ∆IL increases with input voltage, the output ripple
is highest at maximum input voltage. Typically, once the
ESR requirement is satisfied, the capacitance is adequate
DS8202 Ver 1.1 Nov.2007
100mV
= 68mΩ
1.5A
18
Selecting a standard value of 6.8µH results in a
maximum ripple current of :
∆I
L
=
4V 

 = 941.2mA
1 −
(500kHz )(6.8µH )  20V 
I LPK = I
4V
CHG
+
∆I
L = 1.5A + 941.2mA ≈ 1.975A
2
2
Next, choose the P-channel MOSFET. For example, a
TSSOP-8 package with RDS(ON) = 42mΩ (nom), 55mΩ
(max) offers a small solution. The maximum power
dissipation with VIN = 5V and VBAT = 4V at 50℃
ambient temperature is:
(1.5A )2 (55mΩ )(4V ) = 0.099 W
P =
D
5V
TJ = 50℃ + (0.099W)(65℃/W) = 56.5℃
CIN is chosen for an RMS current rating of about 0.8A at
85℃. The output capacitor is chosen for an ESR similar
to the battery impedance of about 100mΩ The ripple
voltage on the BAT pin is:
EUP8202-4.2/8.4
∆I L(max ) (ESR )
VOUT ( RIPPLE ) =
2
=
(0.94A )(0.1Ω ) = 47mV
2
For dual cells charge,
VIN = 5V to 20V, VBAT = 8V nominal, IBAT =3A,
fOSC = 500kHz, IEOC=0.45A,
R SENSE =
100mV
= 33mΩ
3A
Choose the inductor for about 50% ripple current at the
maximum VIN:
L=
8V 

 = 6 .4 µ H
1 −
(500 kHz )(0.5)(3A )  20V 
8V
Selecting a standard value of 6.8µH results in a
maximum ripple current of :
∆I
L
=
8V 

 = 1.441A
1 −
(500kHz )(6.8µH )  20V 
8V
∆I
L = 3A + 1.441A ≈ 3.720 A
CHG
2
2
The maximum power dissipation with VIN = 9V and VBAT
= 8V at 50℃ ambient temperature is:
I LPK = I
P =
D
+
(3A )2 (55mΩ )(8V ) = 0.44 W
9V
TJ = 50℃ + (0.44W)(65℃/W) = 78.6℃
VOUT ( RIPPLE ) =
=
∆I L(max ) (ESR )
2
(1.441A )(0.1Ω ) = 72mV
2
The Schottky diode D2 shown in Figure 2 conducts
current when the pass transistor is off. In a low duty
cycle case, the current rating should be the same or
higher than the charge current. Also it should withstand
reverse voltage as high as VIN.
DS8202 Ver 1.1 Nov.2007
19
Board Layout Suggestions
When laying out the printed circuit board, the following
considerations should be taken to ensure proper operation
of the EUP8202.
GATE pin rise and fall times are 20ns and 50ns
respectively (with CGATE = 2000pF). To minimize
radiation, the catch diode, pass transistor and the input
bypass capacitor traces should be kept as short as
possible. The positive side of the input capacitor should
be close to the source of the P-channel MOSFET; it
provides the AC current to the pass transistor. The
connection between the catch diode and the pass
transistor should also be kept as short as possible. The
SENSE and BAT pins should be connected directly to the
sense resistor (Kelvin sensing) for best charge current
accuracy. Avoid routing the NTC PC board trace near the
MOSFET switch to minimize coupling switching noise
into the NTC pin.
The compensation capacitor connected at the COMP pin
should return to the ground pin of the IC or as close to it
as possible. This will prevent ground noise from
disrupting the loop stability. The ground pin also works
as a heat sink, therefore use a generous amount of copper
around the ground pin. This is especially important for
high VCC and/or high gate capacitance applications.
EUP8202-4.2/8.4
Packaging Information
TDFN-10
SYMBOLS
A
A1
D
E1
E
L
b
e
D1
DS8202 Ver 1.1 Nov.2007
MILLIMETERS
MIN.
MAX.
0.70
0.80
0.00
0.05
2.90
3.10
1.70
2.90
3.10
0.30
0.50
0.18
0.30
0.50
2.40
20
INCHES
MIN.
0.028
0.000
0.114
MAX.
0.031
0.002
0.122
0.067
0.114
0.012
0.007
0.122
0.020
0.012
0.020
0.094
EUP8202-4.2/8.4
SOP-8
SYMBOLS
MILLIMETERS
INCHES
MIN.
MAX.
MIN.
MAX.
A
1.35
1.75
0.053
0.069
A1
0.10
0.25
0.004
0.010
D
E
4.90
5.80
E1
6.20
0.228
3.90
0.244
0.153
L
0.40
1.27
0.016
0.050
b
0.31
0.51
0.012
0.020
e
DS8202 Ver 1.1 Nov.2007
0.193
1.27
0.050
21