MPS MP2612ER 2a,24v input, 600khz 2-3 cells switching li-ion battery charger Datasheet

MP2612
2A,24V Input, 600kHz
2-3 Cells Switching Li-Ion Battery Charger
The Future of Analog IC Technology
DESCRIPTION
FEATURES
The MP2612 is a monolithic switching charger
for 2-3 cells series Li-Ion cells battery with a
built-in internal power MOSFET. It achieves up
to 2A charge current with current mode control
for fast loop response and easy compensation.
The charge current can be programmed by
sensing the current through an accurate sense
resistor.

MP2612 regulates the charge current and
charge voltage using two control loops to
realize high accuracy CC charge and CV
charge.
Fault condition protection includes cycle- bycycle current limiting and thermal shutdown.
Other safety features include battery temperature
monitoring, charge status indication and
programmable timer to finish the charging cycle.
The MP2612 requires a minimum number of
readily available standard external components.
The MP2612 is available in 16-pin 4mm x 4mm
QFN package.
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Charges 2-3 Cells Series Li-Ion Battery
Packs
Wide Operating Input Range
Up to 2 A Programmable Charging Current
±0.75% VBATT Accuracy
0.2Ω Internal Power MOSFET Switch
Up to 90% Efficiency
Fixed 600kHz Frequency
Preconditioning for Fully Depleted Batteries
Charging Operation Indicator
Input Supply and Battery Fault Indicator
Thermal Shutdown
Cycle-by-Cycle Over Current Protection
Battery Temperature Monitor and Protection
APPLICATIONS

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Distributed Power Systems
Chargers for 2-Cell or 3-Cell Li-Ion Batteries
Pre-Regulator for Linear Regulators
Smart Phones
Net-book
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“MPS” and “The Future of Analog IC Technology” are Registered Trademarks of
Monolithic Power Systems, Inc.
TYPICAL APPLICATION
Figure 1—Standalone Switching Charger
MP2612 Rev. 1.0
9/7/2011
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1
MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
D1
VIN
RS2
9V to 24V
(9V min for 2-cell)
VSYS
20m
RG1
M2
RG2
C8
22uF
RG1
RG2
MP8110
VCC
NC
SHDN
OUT2
GND
OUT1
M3
C1
4.7uF
L
VIN
VREF33
SW
VREF25
BST
C3
1uF
R1
R2
MP2612
ACOK
CELLS
10k
EN
ON OFF
100m
2-3 cells
battery
C2
D2
CSP
BATT
R5
750
R4
2.5k
COMPI
COMPV
NTC
RNTC
C7
0.1uF
22uF
CHGOK
R3
10k
RS1
4.7uH
GND
TMR
C6
C4
0.1uF
2.2nF
C5
2.2nF
Figure 2—Switching Charger with Power Path Management
(1)
Notes:
1) ACOK should be pulled up to VIN in the power path management application.
MP2612 Rev. 1.0
9/7/2011
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2
MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
ORDERING INFORMATION
Part Number*
MP2612ER
Package
4mm x 4mm QFN16
Top Marking
2612ER
Free Air Temperature (TA)
-20C to +85C
*For Tape & Reel, add suffix –Z (eg. MP2612ER–Z);
For RoHS compliant packaging, add suffix –LF (eg. MP MP2612ER–LF–Z)
PACKAGE REFERENCE
TOP VIEW
VIN
SW
BST
TMR
PIN 1 ID
16
15
14
13
ACOK
2
11
CSP
CHGOK
3
10
BATT
VREF33
4
9
COMPI
EXPOSED PAD
ON BACKSIDE
5
6
7
8
COMPV
GND
CELLS
12
EN
1
VREF25
NTC
ABSOLUTE MAXIMUM RATINGS (2)
Thermal Resistance
Supply Voltage VIN ....................................... 26V
VSW ........................................ -0.3V to VIN + 0.3V
VBST ...................................................... VSW + 6V
VCSP, VBATT, ...................................-0.3V to +18V
VACOK, VCHGOK, ..............................-0.3V to +26V
All Other Pins ..................................-0.3V to +6V
Continuous Power Dissipation (TA=+25C) (3)
............................................................. 2.7W
Junction Temperature ...............................150C
Lead Temperature ....................................260C
Storage Temperature ............... -65C to +150C
4x4 QFN16 ............................. 46 ...... 10... C/W
Recommended Operating Conditions
(4)
(5)
θJA
θJC
Notes:
2) Exceeding these ratings may damage the device.
3) The maximum allowable power dissipation is a function of the
maximum junction temperature TJ(MAX), the junction-toambient thermal resistance θJA, and the ambient temperature
TA. The maximum allowable continuous power dissipation at
any ambient temperature is calculated by PD(MAX)=(TJ(MAX)TA)/ θJA. Exceeding the maximum allowable power dissipation
will cause excessive die temperature, and the regulator will go
into thermal shutdown. Internal thermal shutdown circuitry
protects the device from permanent damage.
4) The device is not guaranteed to function outside of its
operating conditions.
5) Measured on JESD51-7 4-layer board.
Supply Voltage VIN .............................. 9V to 24V
Maximum Junction Temp. (TJ) ............. +125C
MP2612 Rev. 1.0
9/7/2011
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
ELECTRICAL CHARACTERISTICS (6)
VIN = 19V, TA = +25C, CELLS=0V, unless otherwise noted.
Parameters
Symbol Condition
Terminal Battery Voltage
VBATT
CSP，BATT Current
Min
8.337
8.4
8.463
CELLS= VREF33
12.505
12.6
12.695
RDS(ON)
Switch Leakage
CC
Trickle
CC current
ICC
Trickle charge current
RS1=100mΩ
1.8
ITRICKLE
Units
V
1
µA
0.2
Ω
0
EN = 4V, VSW = 0V
(6)
Peak Current Limit
Max
CELLS=0V
ICSP,IBATT Charging disabled
Switch On Resistance
Typ
10
μA
4.1
A
2
A
2.0
2.2
A
10%
ICC
Trickle charge voltage threshold
2.8
V/cell
Trickle charge hysteresis
350
mV
Termination current threshold
IBF
Oscillator Frequency
fSW
Fold-back Frequency
5%
15%
kHz
VBATT =0V
190
kHz
90
Sense
Voltage
Minimum On Time (6)
Under Voltage
Rising
Lockout
Threshold
Under Voltage
Hysteresis
Lockout
Threshold
170
VSENSE
tON
CELLS=0V, VBATT =5V
200
230
3.2
VDRAIN =0.3V
Dead-battery indication
Termination delay
Time after
CTMR=0.1μF
3.4
reached,
VRECHG
Recharge Hysteresis
RNTC=NCP18XH103(0°C)
V
mV
5
IBF
mV
ns
200
Stay at trickle mode
CTMR=0.1μF
NTC Low Temp Rising Threshold
%
100
3
Open-drain sink current
Recharge threshold at VBATT
ICC
600
Maximum Duty Cycle
Maximum current
(CSP to BATT)
10%
CELLS=0V,
VBATT =4.5V
mA
30
min
1
min
4.0
V/cell
100
mV
73
%VREF33
NTC High Temp Falling Threshold
RNTC=NCP18XH103(50°C)
30
%VREF33
VIN min head-room (reverse blocking)
VIN-VBATT
180
mV
0.4
EN Input Low Voltage
1.8
EN Input High Voltage
EN Input Current
MP2612 Rev. 1.0
9/7/2011
V
V
EN =4V
4
EN =0V
0.2
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μA
4
MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
ELECTRICAL CHARACTERISTICS (continued)
VIN = 19V, TA = +25C, CELLS=0V, unless otherwise noted.
Parameters
Symbol Condition
Supply Current (Shutdown)
Supply Current (Quiescent)
Typ
Max
Units
EN =4V
0.16
mA
EN =4V,
Consider
VREF33
pin output current,
R3=10k,RNTC=10k
0.32
mA
2.0
EN =0V, CELLS=0V
(6)
Thermal Shutdown
VREF25 output voltage
VREF33 output voltage
VREF33 load regulation
Min
ILOAD =0 to 10mA
150
2.5
3.3
30
mA
°C
V
V
mV
Notes:
6) Guaranteed by design.
MP2612 Rev. 1.0
9/7/2011
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5
MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
TYPICAL PERFORMANCE CHARACTERISTICS
VIN=19V, C1=4.7μF, C2=22μF, L=4.7μH, RS1=100mΩ, Real Battery Load, TA=25ºC, unless
otherwise noted.
2
VBATT
8.2
8.1
1.5
8
7.9
1
7.8
IBATT
7.7
0.5
7.6
0
20
40
60
80
C HAR G E C UR R E NT (A)
8.3
CV Load
1. 5
1
VIN=12V
2
4
6
8
12.6
2
12.2
1.5
12
11.8
1
11.6
IBATT
11.4
0.5
11.2
11
10
VBATT
12.4
0
50
B AT T E R Y V OL T AG E (V )
3 Cells Charge Current vs.
Battery Voltage
0
150
100
T IME S (MIN)
NTC Control Window
CV Load
3
Low Temp Off
2.5
2
VIN=24V
1.5
2.5
1
2
Low Temp On
2
ICHG(A)
VIN=19V
VNTC(V)
C HA R G E C U R R E NT(A )
VIN=19V
VIN=24V
0. 5
T IME S (MIN)
2.5
2.5
12.8
2
0
0
0
100 120
3 Cells Battery Charge Curve
B A T T E R Y C UR R E NT (A )
8.4
7.5
2. 5
2.5
B A T T E R Y C UR R E NT (A )
B A T T E R Y V O L T A G E (V )
8.5
2 Cells Charge Current vs.
Battery Voltage
B A T T E R Y V O L T A G E (V )
2 Cells Battery Charge Curve
1.5
High Temp On
1.5
1
1
High Temp Off
0.5
0
0
0.5
0.5
2
4
6
8
10
12
B ATTER Y V OL TAGE(V )
MP2612 Rev. 1.0
9/7/2011
14
0
0
8
12
16
20
VIN(V)
24
28
0
0.5
1
1.5
2
2.5
ISYS(A)
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN=19V, C1=4.7μF, C2=22μF, L=4.7μH, RS1=100mΩ, Real Battery Load, TA=25ºC, unless
otherwise noted.
Efficiency vs. ICHG
Efficiency vs. ICHG
Efficiency vs. VIN
2 Cells, VBATT=8.4V
3 Cells, VBATT=12.6V
2 Cells, VBATT=7.4V
100
90
VIN=19V
VIN=24V
80
VIN=15V
VIN=15V
EFFICIENCY (%)
EFFICIENCY (%)
VIN=12V
70
60
92
90
VIN=24V
80
70
0.4
0.8
1.2
1.6
2
89
86
83
80
60
0
0
0.4
0.8
ICHG(A)
1.2
1.6
5
2
2 Cells
8.4
8.4
2
8.2
8.1
VBATT (V)
2.2
VBATT (V)
8.5
8.3
8.3
8.2
18
23
28
8
-20
25
2 Cells, VBATT=7.4V
1.8
1.6
1.4
8.1
8
20
Charge Current vs.
Temperature
8.5
13
15
VIN(V)
BATT Float Voltage vs.
Temperature
2 Cells
8
10
ICHG(A)
BATT Float Voltage vs. VIN
VBATT (V)
95
VIN=19V
EFFICIENCY (%)
100
0
20
40
60
80
1.2
-20
0
20
40
60
80
VIN(V)
MP2612 Rev. 1.0
9/7/2011
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN=19V, C1=4.7μF, C2=22μF, L=4.7μH, RS1=100mΩ, Real Battery Load, TA=25ºC, unless
otherwise noted.
VIN
10V/div.
VBATT
5V/div.
Steady State Waveform
Steady State Waveform
Steady State Waveform
Trickle Charge
2 Cells, VBATT=5V
CC Charge
2 Cells, VBATT=7.4V
CV Charge
2 Cells, VBATT=8.4V
VIN
10V/div.
VBATT
5V/div.
VIN
10V/div.
VBATT
5V/div.
VSW
10V/div.
VSW
10V/div.
VSW
10V/div.
IBATT
500mA/div.
IBATT
200mA/div.
IBATT
1A/div.
Power On Waveform
Power Off Waveform
EN On Waveform
2 Cells, ICHG=2A,VBATT=8V
2 Cells, ICHG=2A,VBATT=8V
2 Cells, ICHG=2A,VBATT=8V
VEN
5V/div.
VIN
10V/div.
VIN
10V/div.
VBATT
5V/div.
VBATT
5V/div.
VBATT
5V/div.
VSW
10V/div.
VSW
10V/div.
VSW
10V/div.
IBATT
2A/div.
IBATT
2A/div.
IBATT
2A/div.
EN Off Waveform
NTC Control,
Timer Out
2 Cells, ICHG=2A,VBATT=8V
VBATT=7.4V
2 Cells, VBATT=7.4V, CTMR=1nF
VEN
5V/div.
VNTC
2V/div.
VBATT
5V/div.
VBATT
5V/div.
VBATT
5V/div.
VSW
10V/div.
VSW
10V/div.
VTMR
500mV/div.
IBATT
2A/div.
IBATT
2A/div.
MP2612 Rev. 1.0
9/7/2011
VIN
10V/div.
IBATT
2A/div.
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN=19V, C1=4.7μF, C2=22μF, L=4.7μH, RS1=110mΩ, RS2=20mΩ, Real Battery Load, TA=25ºC,
unless otherwise noted.
Power Path Management
Current Sharing
Power Path Management
Steady State
2 Cells, ICHG=2A, VBATT=7.4V
VIN
10V/div.
VBATT
5V/div.
ISYS
1A/div.
IBATT
1A/div.
2 Cells, ICHG=2A, VBATT=8V, ISYS=0.8A
VIN
10V/div.
VSW
10V/div.
ISYS
500mA/div.
IBATT
1A/div.
VIN
10V/div.
VBATT
5V/div.
IBATT
1A/div.
VSYS
5V/div.
VIN
10V/div.
VBATT
5V/div.
IBATT
1A/div.
VSYS
5V/div.
MP2612 Rev. 1.0
9/7/2011
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9
MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
PIN FUNCTIONS
Pin #
1
2
3
4
5
6
Name
Description
Thermistor Input. Connect a resistor from this pin to the pin VREF33 and the Thermistor
from this pin to ground.
Valid Input Supply Indicator. A logic LOW on this pin indicates the presence of a valid input
ACOK supply.
Charging Completion Indicator. A logic LOW indicates charging operation. The pin will
CHGOK become an open drain once the charging is complete.
Internal linear regulator 3.3V reference output. Bypass to GND with a 1μF ceramic
VREF33
capacitor.
NTC
VREF25 Internal linear 2.5V reference circuit. PLEASE KEEP THIS PIN FLOATING.
EN
On/Off Control Input.
8
Command Input for the number of Li-Ion Cells. Connect this pin to VREF33 for 3-cell
operation or ground the pin for 2-cell operation. DO NOT LEAVE THIS PIN FLOAT.
COMPV V-LOOP Compensation. Decouple this pin with a capacitor and a resistor.
9
COMPI I-LOOP Compensation. Decouple this pin with a capacitor and a resistor.
7
CELLS
10
BATT
11
CSP
Positive Battery Terminal.
Battery Current Sense Positive Input. Connect a resistor RSEN between CSP and BATT. The
200mV
full charge current is: ICHG A  
.
RS1mΩ 
12
GND
Ground. This pin is the voltage reference for the regulated output voltage. For this reason
care must be taken in its layout. This node should be placed outside of the switching diode
(D2) to the input ground path to prevent switching current spikes from inducing voltage
noise into the part.
13
TMR
Set time constant. 0.1uA current charges and discharges the external cap.
14
BST
15
SW
16
IN
MP2612 Rev. 1.0
9/7/2011
Bootstrap. This capacitor is needed to drive the power switch’s gate above the supply
voltage. It is connected between SW and BS pins to form a floating supply across the power
switch driver.
Switch Output.
Supply Voltage. The MP2612 operates from a 9V to 24V unregulated input to charge 2~3
cell li-ion battery. Capacitor is needed to prevent large voltage spikes from appearing at the
input.
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
BLOCK DIAGRAM
Figure 3—Function Block Diagram
MP2612 Rev. 1.0
9/7/2011
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11
MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
OPERATION
The MP2612 is a peak current mode controlled
switching charger for use with Li-Ion batteries.
Figure 3 shows the block diagram. At the
beginning of a cycle, M1 is off. The COMP
voltage is higher than the current sense result
from amplifier A1’s output and the PWM
comparator’s output is low. The rising edge of the
600 kHz CLK signal sets the RS Flip-Flop. Its
output turns on M1 thus connecting the SW pin
and inductor to the input supply.
The increasing inductor current is sensed and
amplified by the Current Sense Amplifier A1.
Ramp compensation is summed to the output of
A1 and compared to COMP by the PWM
comparator.
When the sum of A1’s output and the Slope
Compensation signal exceeds the COMP
voltage, the RS Flip-Flop is reset and M1 is
turned off. The external switching diode D2 then
conducts the inductor current.
If the sum of A1’s output and the Slope
Compensation signal does not exceed the COMP
voltage, then the falling edge of the CLK resets
the Flip-Flop.
The MP2612 have two internal linear regulators
power internal circuit, VREF33 and VREF25. The
output of 3.3V reference voltage can also power
external circuitry as long as the maximum current
(50mA) is not exceeded. A 1μF bypass capacitor
is required from VREF33 to GND to ensure
stability. The output of 2.5V reference voltage
can not carry any load.
In typical application, VREF25 should be float
and no capacitor is required. It can only connect
to a capacitor which is smaller than 100pF.
Charge Cycle (Mode change: Trickle CC
CV)
The battery current is sensed via RS1 (Figure 3)
and amplified by A2. The charge will start in
“trickle charging mode” (10% of the RSEN
programmed current ICC) until the battery voltage
reaches 2.8V/cell. If the charge stays in the
“trickle charging mode” till “timer out” condition is
triggered, the charge is terminated. Otherwise,
the output of A2 is then regulated to the level set
by RS1. The charger is operating at “constant
MP2612 Rev. 1.0
9/7/2011
current charging mode.” The duty cycle of the
switcher is determined by the COMPI voltage
that is regulated by the amplifier GMI.
When the battery voltage reaches the “constant
voltage mode” threshold, the amplifier GMV will
regulate the COMP pin, and then the duty cycle.
The charger will then operate in “constant voltage
mode.”
Automatic Recharge
A programmable time delay after the battery
charging current drops below the termination
threshold, the charger will cease charging and
the CHGOK pin becomes an open drain. If for
some reason, the battery voltage is lowered to
4.0V/Cell, recharge will automatically kick in.
Termination Delay  1min 
C TMR
0.1uF
Charger Status Indication
MP2612 has two open-drain status outputs:
CHGOK and ACOK . The ACOK pin pulls low
when an input voltage is greater than battery
voltage 300mV and over the under voltage
lockout threshold. CHGOK is used to indicate the
status of the charge cycle. Table 1 describes the
status of the charge cycle based on the
CHGOK and ACOK outputs.
Table 1―Charging Status Indication
ACOK
low
low
CHGOK
low
high
high
high
Charger status
In charging
End of charge,
Vin<UVLO, timer out,
thermal shutdown EN
disable
Timer Operation
MP2612 uses internal timer to terminate the
charge if the timer times out. The timer duration
is programmed by an external capacitor at the
TMR pin.
The trickle mode charge time is:
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12
MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
TTICKLE_TMR  30mins 
CTMR
0.1uF
The total charge time is:
CTMR
0.1uF
Coefficient
TTOTAL_TMR  3hours 
Negative
Thermal
(NTC)
Thermistor
The MP2612 has a built-in NTC resistance
window comparator, which allows MP2612 to
sense the battery temperature via the thermistor
packed internally in the battery pack to ensure a
safe operating environment of the battery. A
resistor with appropriate value should be
connected from VREF33 to NTC pin and the
thermistor is connected from NTC pin to GND.
The voltage on NTC pin is determined by the
resistor divider whose divide ratio depends on
the battery temperature. When the voltage of pin
NTC falls out of NTC window range, MP2612 will
stop the charging. The charger will restart if the
temperature goes back into NTC window range.
MP2612 Rev. 1.0
9/7/2011
Power Path Management
Using MP8110 together with MP2612 can
implement a switching charger circuit with power
path management function, which realizes the
current sharing of the charger and system load
(Figure 2). In another word, MP8110 senses the
system current and feeds back to MP2612 and
MP2612 reduces charge current according to the
increase of the system current.
However, after the charge current decrease to 0,
the system current can only be limited by the
adapter.
The system current is satisfied first and always. It
chooses the adapter as its power source when
the adapter plugs in, and the battery is the
backup power source when the adapter is
removed.
Figure 4 to 8 shows the charge profile, operation
waveform and flow chart, respectively.
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
CHARGE PROFILE AND POWER PATH MANAGEMENT FUNCTION
Figure 4—Li-Ion Battery Charge Profile
Figure 5 — Power Path Management Function- Current Sharing
MP2612 Rev. 1.0
9/7/2011
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
OPERATION FLOW CHART
Figure 6— Normal Charging Operation Flow Chart
MP2612 Rev. 1.0
9/7/2011
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
OPERATION FLOW CHART (continued)
Figure 7— Power Path Management Operation Flow Chart
MP2612 Rev. 1.0
9/7/2011
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
OPERATION FLOW CHART (continued)
Normal Operation
Charge On,
ACOK&
CHGOK is low
Charge Mode?
VBATT=VBATT_FULL
VBATT_TC<VBATT<VBATT_FULL
VBATT<VBATT_TC
C.V.C
C.C.C
T.C.C
No
No
No
Battery Full?
ICHG<IBF
VBATT>VBATT_FULL
VBATT>VBATT_TC
Yes
Yes
Yes
Stop Charge.
ACOK is low,
CHGOK is high
Yes
No
VBATT<VBATT_RECH?
No
No
No
o
Timer Out ?
NTC Fault?
Tj>=150 C?
Yes
Yes
Yes
Charge
Termination,
ACOK& CHGOK
are high
Charge Suspend
Charge Current
Thermal Shutdown,
ACOK& CHGOK
are high
No
NTC OK?
Tj<=130oC?
Yes
Yes
Charger Recovery,
Return to Normal
Operation
No
Fault Protection
Figure 8— Fault Protection Flow Chart
MP2612 Rev. 1.0
9/7/2011
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
APPLICATION INFORMATION
Setting the Charge Current
1. Standalone Switching Charger
The charge current of MP2612 is set by the
sense resistor RS1 (Figure1). The charge current
programmable formula is as following:
ICHG A  
200mV
RS1mΩ 
RS1 RGS1

RS2 RG1
RGS1/2 causes charge current sense error as it
changes the sense gain of A2, which can be
calculated from:
(1)
2. Switching Charger with Power Path
Management
When MP2612 is applied together with MP8110,
the charge current setting should be calibrated
(Figure2).
Figure 8 shows MP8110 sensing the system
current and feeding back to the MP2612.
(5)
G A2 
12.3 kΩ 
2kΩ   RGS kΩ 
(6)
The charge current is set as:
ICHG A  
1230
G A2  RS1mΩ 
(7)
Then the influence of RGS1 to the charge current
is:
ICHG A  
2000  RGSΩ 
10  RS1mΩ 
(8)
To decrease the power loss of the sensing circuit,
choose RS2 as small as possible, 20m is
recommended. Too small RG1 results in too big
current sense error of MP8110, 50Ω is at least.
Substitute these two values into equation (5),
then the calibrated charge current set formula in
power path application is got from equation (8):
ICHG A  
2000  2.5  RS1mΩ 
10  RS1mΩ 
(9)
Following table is the calculated RS1 and RGS1
value for setting different charge current.
Figure 8— System Current Sensing Circuit
The gain of MP8110 is set as:
Gain 
RGS1
RG1
(2)
The voltage of OUT1 pin, VOUT1 can be calculated
from:
I  RS2  RGS1
VOUT1  ISYS  RS2  Gain  SYS
(3)
RG1
Table2—ICHG Set in Power Path Application
ICHG(A)
2
1.5
1
0.8
0.5
RGS(Ω)
280
402
665
909
2k
RS1(mΩ)
110
160
260
360
800
If choose different RS2 and RG1, re-calculated
from equation (5) and equation (8), then get the
different equation (9) and the table.
When the system current increased ΔISYS, to
satisfy the charge current decreased ΔISYS
accordingly, the relationship should be:
ΔIBAT 
ΔVOUT1 ΔISYS  RS2  RGS1

RS1
RS1 RG1
(4)
BecauseΔISYS=ΔIBATT, we can get:
MP2612 Rev. 1.0
9/7/2011
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MP2612 – 2A, 24V INPUT, 600kHz 2-3CELL SWITCHING LI-ION BATTERY CHARGER
Also, any relationship between ΔISYS and ΔIBATT
can be realized by re-calculate equation (4),(5)
and (8).
Selecting the Inductor
A 1µH to 10µH inductor is recommended for
most applications. The inductance value can be
derived from the following equation.
L
VOUT  (VIN  VOUT )
VIN  IL  fOSC
According to equation (12) and equation (13), we
can find that R3 = 9.63k and R6 = 505k.
To be simple in project, making R3=10k and R6
no connect will approximately meet the
specification.
VREF33
(10)
Where ΔIL is the inductor ripple current. VOUT is
the 2/3 cell battery voltage.
Choose inductor current to be approximately
30% if the maximum charge current, 2A. The
maximum inductor peak current is:
IL(MAX)  ICHG 
IL
2
(11)
Under light load conditions below 100mA, larger
inductance is recommended for improved
efficiency.
For optimized efficiency, the inductor DC
resistance is recommended to be less than
200mΩ.
NTC Function
As Figure 9 shows, the low temperature
threshold and high temperature threshold are
preset internally via a resistive divider, which are
73%·VREF33 and 30%·VREF33. For a given
NTC thermistor, we can select appropriate R3
and R6 to set the NTC window.
In detail, for the thermistor (NCP18XH103) noted
in above electrical characteristic,
At 0ºC, RNTC_Cold = 27.445k;
At 50ºC, RNTC_Hot = 4.1601k.
Assume that the NTC window is between 0ºC
and 50ºC, the following equations could be
derived:
R6//R NTC_Cold
R3  R6//R NTC_Cold
R6//R NTC_Hot
R3  R6//R NTC_Hot
MP2612 Rev. 1.0
9/7/2011


VTH_Low
VREF33
VTH_High
VREF33
 73%
(12)
 30%
(13)
Low Temp Threshold
R3
NTC
R6
VTH_Low
RNTC
High Temp Threshold
VTH_High
Figure 9— NTC function block
Selecting the Input Capacitor
The input capacitor reduces the surge current
drawn from the input and also the switching noise
from the device. The input capacitor impedance
at the switching frequency should be less than
the input source impedance to prevent high
frequency switching current passing to the input.
Ceramic capacitors with X5R or X7R dielectrics
are highly recommended because of their low
ESR and small temperature coefficients. For
most applications, a 4.7µF capacitor is sufficient.
Selecting the Output Capacitor
The output capacitor keeps output voltage ripple
small and ensures regulation loop stability. The
output capacitor impedance should be low at the
switching frequency. Ceramic capacitors with
X5R or X7R dielectrics are recommended.
PC Board Layout
The high frequency and high current paths (GND,
IN and SW) should be placed to the device with
short, direct and wide traces. The input capacitor
needs to be as close as possible to the IN and
GND pins. The external feedback resistors
should be placed next to the FB pin. Keep the
switching node SW short and away from the
feedback network.
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19
MP2612 – 2A, 24V INPUT, 600kHz SWITCHING LI-ION BATTERY CHARGER
MPS CONFIDENTIAL AND PROPRIETARY INFORMATION – INTERNAL USE ONLY
PACKAGE INFORMATION
QFN16 (4mm x 4mm)
3.90
4.10
2.15
2.45
0.50
0.70
PIN 1 ID
MARKING
0.25
0.35
3.90
4.10
PIN 1 ID
INDEX AREA
13
PIN 1 ID
SEE DETAIL A
16
1
12
2.15
2.45
0.65
BSC
9
4
8
TOP VIEW
5
BOTTOM VIEW
PIN 1 ID OPTION A
0.45x45º TYP.
PIN 1 ID OPTION B
R0.25 TYP.
0.80
1.00
0.20 REF
0.00
0.05
DETAIL A
SIDE VIEW
3.80
2.30
NOTE:
1) ALL DIMENSIONS ARE IN MILLIMETERS.
2) EXPOSED PADDLE SIZE DOES NOT INCLUDE MOLD FLASH.
3) LEAD COPLANARITY SHALL BE 0.10 MILLIMETER MAX.
4) JEDEC REFERENCE IS MO-220, VARIATION VGGC.
5) DRAWING IS NOT TO SCALE.
1.00
0.35
0.65
RECOMMENDED LAND PATTERN
NOTICE: The information in this document is subject to change without notice. Please contact MPS for current specifications.
Users should warrant and guarantee that third party Intellectual Property rights are not infringed upon when integrating MPS
products into any application. MPS will not assume any legal responsibility for any said applications.
MP2612 Rev. 1.0
9/7/2011
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20