MP2626GR_技术文档

MP2626

USB-Compliant Single Cell Li-ion

Switching Charger with USB-OTG Boost

The Future of Analog IC Technology

DESCRIPTION

FEATURES

The MP2626 is a highly-integrated, flexible,

switch-mode battery charger with system power

management, designed for single-cell Li-ion

and Li-Polymer batteries used in a wide range

of portable applications.

•

20V Absolute Maximum Input Voltage

6V Maximum Input Operating Voltage

Selectable 4.2V/ 4.35V Charge Voltage with

0.5% Accuracy at 25ºC

•

Power Management Function

Integrated Input-Current Limit and Input-

Voltage Regulation

Up to 2A Programmable Charge Current

Trickle-Charge Function

The MP2626 can operate in both charge mode

and boost mode to allow full system and battery

power management. It is also able to work as a

boost regulator to power a USB peripheral from

the battery.

•

Negative Temperature Coefficient Pin for

Battery Temperature Monitoring

Programmable Timer Back-Up Protection

Thermal Regulation and Thermal Shutdown

Internal Battery Reverse Leakage Blocking

Reverse Boost Operation Mode for USB

Peripheral

Up to 91% 5V Boost Mode Efficiency @ 1A

Programmable Output Current Limit for

Boost Mode

The MP2626 automatically detects the battery

voltage and charges the battery in the three

phases: trickle current charge, constant current

charge and constant voltage charge. Other

features include charge termination and auto-

recharge. This IC also integrates both input-

current limit and input-voltage regulation in

order to ensure USB compliant and minimize

the charging time.

•

Integrated Short Circuit Protection for Boost

Mode

The MP2626 can operate as a boost regulator

by setting the MODE pin to a HIGH logic. The

boost regulator includes output current limit and

short circuit protection. As long as MODE pin is

high, the MP2626 will discharge the battery in

the boost mode.

APPLICATIONS

•

Sub-Battery Application

Power-Bank Applications for Smart-Phone

Tablet and other Portable Device

To guarantee safe operation, the MP2626 limits

the die temperature to a preset value of 120^oC.

Other safety features include input over-voltage

protection, battery over-voltage protection,

All MPS parts are lead-free and adhere to the RoHS directive. For MPS green

status, please visit MPS website under Products, Quality Assurance page.

“MPS” and “The Future of Analog IC Technology” are registered trademarks of

Monolithic Power Systems, Inc.

thermal

shutdown,

battery

temperature

monitoring, and a programmable timer to

prevent prolonged charging of a dead battery.

MP2626 Rev. 1.0

2/28/2015

www.MonolithicPower.com

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1

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

TYPICAL APPLICATION

R1

R2

R_OLIM

C2

OLIM

SW

FB

VIN

PMID

RS1

L1

5V Input

C_IN

I_CHG

V_BATT

I_BATT

C3 C_BATT

R3

C1

R5

R6

CSP

Battery

REG

BATT

VPMID

PWIN

R4

NTC

VB

Battery Voltage

Programmable Pin

GND: 4.35V

High/Float: 4.2V

CHG

VCC

ACOK

BOOST

ISET

FREQ

EN

C4

VCC

MODE

ILIM

TMR

AGND

PGND

R_ILIM

C_TMRR_ISET

Table 1: Operation Mode

__________

MODE

EN

High

Low

X

Operating Mode

ACOK

Charge Mode, Enable Charging

Sleep Mode

Low

High

Boost Mode

X=Don’t Care.

MP2626 Rev. 1.0

2/28/2015

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2

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

ORDERING INFORMATION

Part Number*

Package

Top Marking

MP2626GR

QFN-24 (4mm×4mm)

See Below

*For Tape & Reel, add suffix – Z (e.g. MP2626GR-Z);

TOP MARKING

MPS: MPS prefix;

Y: year code;

WW: week code:

MP2626: product code of MP2626GR;

LLLLLL: lot number;

PACKAGE REFERENCE

TOP VIEW

MP2626 Rev. 1.0

2/28/2015

www.MonolithicPower.com

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3

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

ABSOLUTE MAXIMUM RATINGS ⁽¹⁾

VIN ............................................... –0.3V to 20V

SW …………….. .................................................

–0.3V (-2V for <10ns) to 6.5V (8.5V for <20ns)

Thermal Resistance ⁽⁴⁾

QFN-24 (4mm×4mm)............. 42....... 9.... °C/W

θ_JAθ_JC

Notes:

1) Exceeding these ratings may damage the device.

2) The maximum allowable power dissipation is a function of the

maximum junction temperature T_J(MAX), the junction-to-

ambient thermal resistance θ_JA, and the ambient temperature

T_A. The maximum allowable continuous power dissipation at

any ambient temperature is calculated by P_D(MAX) = (T_J

(MAX)-T_A)/θ_JA. 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.

PMID, BATT ................................ –0.3V to 6.5V

----------------- ------------- ---------------------

ACOK, CHG, BOOST .................. –0.3V to 6.5V

All Other Pins............................... –0.3V to 6.5V

Junction Temperature..............................150°C

Lead Temperature ...................................260°C

(2)

Continuous Power Dissipation (T_A= +25°C)

..........................................................2.97W

Junction Temperature..............................150°C

Operating Temperature............. –20°C to +85°C

3) The device is not guaranteed to function outside of its

operating conditions.

4) Measured on JESD51-7, 4-layer PCB.

Recommended Operating Conditions ⁽³⁾

Supply Voltage VIN........................... 4.5V to 6V

Battery Voltage V_OUT.................... 2.5V to 4.35V

Operating Junction Temp. (T_J).−40°C to +125°C

MP2626 Rev. 1.0

2/28/2015

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4

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

ELECTRICAL CHARACTERISTICS

V_IN= 5.0V, T_A= 25°C, unless otherwise noted.

Parameter

Symbol Condition

Min

Typ

Max

Units

VIN to PMID NMOS ON

Resistance

R_{IN to PMID}

100

mΩ

High-side PMOS ON Resistance

Low-side NMOS ON Resistance

R_{H DS}

R_{L DS}

72

70

mΩ

CC Charge Mode/Boost

Mode

4.5

1.5

4.5

A

High-Side PMOS Peak Current

Limit

I_{PEAK_HS}

TC Charge Mode

Low-Side NMOS Peak Current

Limit

I_{PEAK_LS}

FREQ = 0

600

1200

2.2

Switching Frequency

f_SW

kHz

FREQ = Float/ High

VCC UVLO

V_{CC UVLO}

2

2.4

0.85

1.2

V

mV

V

VCC UVLO Hysteresis

PWIN, Lower Threshold

Lower Threshold Hysteresis

PWIN, Upper Threshold

Upper Threshold Hysteresis

Charge Mode

100

0.8

V_{PWIN L}

V_{PWIN H}

0.75

1.1

50

mV

V

1.15

50

mV

EN = 5V, Battery Float

EN = 0

2.5

1.5

mA

Input Quiescent Current

I_IN

R

_lLIM= 90.9kΩ

400

720

450

810

2000

3

500

900

2200

Input Current Limit

I_{IN_LIMIT}R_lLIM= 49.9kΩ

R_lLIM= 20kΩ

mA

1800

Input Over-Current Threshold

I_IN(OCP)

A

Input Over-Current Blanking

Time⁽⁵⁾

τ_INOCBLK

τ_INRECVR

120

100

µs

Input Over-Current Recovery

Time⁽⁵⁾

ms

V

Leave VB floating or

connect to logic HIGH

4.179

4.328

3.950

4.091

4.200

4.350

4.015

4.221

4.372

4.080

4.223

Terminal Battery Voltage

Recharge Threshold

V_{BATT_FULL}

Connect VB to GND

Leave VB floating or

connect to logic HIGH

V_RECH

V

Connect to VB to GND

4.157

250

Recharge Threshold Hysteresis

Battery Over Voltage Threshold

mV

103.3%

1000

1500

250

V_{BATT FULL}

RS1=40mΩ, R_ISET= 69.8kΩ

900

1100

1650

Constant Charge (CC) Current

Trickle-Charge Current

I_CC

I_TC

mA

RS1=40mΩ, R_ISET= 46.4kΩ 1350

MP2626 Rev. 1.0

2/28/2015

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5

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

ELECTRICAL CHARACTERISTICS (continued)

V_IN= 5.0V, T_A= 25°C, unless otherwise noted.

Parameter

Symbol Condition

Leave VB floating or connect

Min

Typ

Max

3.060

3.170

Units

2.860

2.970

2.960

Trickle-Charge Voltage

Threshold

to high logic

V_{BATT_TC}

V

Connect to VB to GND

3.070

200

Trickle-Charge Hysteresis

Termination Charge Current

mV

I_CC

I_BF

RS1=40mΩ, R_ISET=69.8kΩ

2.5%

1.18

10%

17.5%

1.22

Input-Voltage-Regulation

Reference

V_REG

1.2

V

Boost Mode

IN Voltage Range

Feedback Voltage

Feedback Input Current

4.2

6

V

1.18

1.2

1.22

200

V_FB=1V

nA

Boost Over-Voltage Protection

Threshold

Threshold to turn off the

converter during boost mode

V_IN(OVP

)

5.8

6

6.2

V

Boost Over-Voltage Protection

Threshold Hysteresis

V_INfalling from V_IN(OVP)

I_IN= 0A, MODE = 5V

125

mV

mA

A

Boost Quiescent Current

2.0

Programmable Boost Output

Current Limit Accuracy

I_OLIM

RS1 = 40mΩ, R_OLIM= 100kΩ

0.896

1.52

1.120

1.344

RS1 = 50mΩ, R_OLIM=49.9kΩ

V_BATT= 4.2V

Programmable Boost Output

Current⁽⁵⁾

A

Boost Over-Current Blanking

Time⁽⁵⁾

τ_OUTOCBLK

τ_OUTRECVR

V_BATT(LOW)

120

1

µs

ms

Boost Over-Current Recovery

Time⁽⁵⁾

During Boost mode

Before Boost mode

2.5

2.9

V

Weak-Battery Threshold

3.05

30

Sleep Mode

V_BATT= 4.2V, V_IN= 0V, MODE

Battery Leakage Current

Indication and Logic

I_LEAKAGE

15

μA

= 0V

---------------- ------------ -------------------

ACOK, CHG, BOOST pin

output low voltage

---------------- ------------ -------------------

Sinking 1.5mA

400

1

mV

ACOK, CHG, BOOST pin

leakage current

Connected to 5V

μA

NTC and Time-Out Fault

Blinking Frequency⁽⁵⁾

f_BLK

C_TMR=0.1μF, I_CHG=1A

13.7

Hz

EN Input Logic LOW Voltage

EN Input High Voltage

0.4

V

1.4

Mode Input Logic LOW Voltage

Mode Input Logic HIGH Voltage

MP2626 Rev. 1.0

2/28/2015

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6

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

ELECTRICAL CHARACTERISTICS (continued)

V_IN= 5.0V, T_A= 25°C, unless otherwise noted.

Parameter

Protection

Symbol Condition

Min

Typ

Max

Units

C_TMR=0.1µF, remains in TC

mode, I_TC= 0.25A

Trickle-Charge Time

Total Charge Time

16.6

400

Min

C_TMR=0.1µF, I_CHG= 1A

NTC Low Temp, Rising

Threshold

65.3% 66.3% 67.3%

1%

R

_NTC=NCP18XH103(0°C)

_NTC=NCP18XH103(50°C)

NTC Low Temp, Rising

Threshold Hysteresis

V_PMID

NTC High Temp, Rising

Threshold

34%

35%

1%

36%

NTC High Temp, Rising

Threshold Hysteresis

Charging Current Fold-back

Charge Mode

120

150

°C

Threshold⁽⁵⁾

Thermal Shutdown Threshold⁽⁵⁾

Notes:

5) Guaranteed by design.

MP2626 Rev. 1.0

2/28/2015

www.MonolithicPower.com

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7

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

TYPICAL CHARACTERISTICS

C_IN=C_BATT=C_PMID=C3=22µF, C1=C2=1µF, L1=4.7µH, RS1=50mΩ, C4=C_TMR=0.1µF, Battery Simulator,

unless otherwise noted.

Sleep_Mode_Battery Current

vs. Temperature

VIN_OVP vs. Temperature

70

60

50

40

30

20

10

0

1.26

1.24

1.22

1.20

1.18

1.16

5.97

5.96

5.95

5.94

5.93

-50

0

50

100

-50

0

50

100

-50

0

50

100

BATT_full VBH

vs. Temperature

BATT_full V_BH= 4.2V

Batt_full VBL

vs. Temperature

BATT_full V_BL= 4.35V

BATTOVP_VBH_%

vs. Temperature

4.30

4.20

4.10

4.00

3.90

3.80

103.5

103.4

103.3

103.2

4.40

4.35

4.30

4.25

4.20

4.15

4.10

4.05

4.00

3.95

3.90

-50

0

50

-50

0

50

100

-50

0

50

100

BATTOVP_VBL_%

vs. Temperature

103.5

103.4

103.3

103.2

-50

0

50

MP2626 Rev. 1.0

2/28/2015

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8

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

TYPICAL PERFORMANCE CHARACTERISTICS

V_IN=5V, C_IN=C_BATT=C_PMID=C3=22µF, C1=C2=1µF, L1=4.7µH, RS1=50mΩ, C4=C_TMR=0.1µF, Battery

Simulator, unless otherwise noted.

MP2626 Rev. 1.0

2/28/2015

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9

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

TYPICAL PERFORMANCE CHARACTERISTICS (continued)

V_IN=5V, C_IN=C_BATT=C_PMID=C3=22µF, C1=C2=1µF, L1=4.7µH, RS1=50mΩ, C4=C_TMR=0.1µF, Battery

Simulator, unless otherwise noted.

MP2626 Rev. 1.0

2/28/2015

www.MonolithicPower.com

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10

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

TYPICAL PERFORMANCE CHARACTERISTICS (continued)

V_IN=5V, C_IN=C_BATT=C_PMID=C3=22µF, C1=C2=1µF, L1=4.7µH, RS1=50mΩ, C4=C_TMR=0.1µF, Battery

Simulator, unless otherwise noted.

Power On, Charge Mode

BATT_FULL BATT

Power Off, Charge Mode

BATT_FULL BATT

EN On, Charge Mode

V

=4.2V, V

=3.7V,

V

=4.2V, V

=3.7V,

V

=4.2V, V =3.7V,

BATT_FULL BATT

I

=2A

I

=2A

I

=2A

CHG

V

EN

V

BATT

5V/div.

1V/div.

V

PMID

V

SW

PMID

2V/div.

V

IN

V

BATT

1V/div.

I

L

1A/div.

I

L

1A/div.

En Off, Charge Mode

BATT_FULL BATT

Input Current Limit

BATT_FULL BATT

Input Voltage Clamp

V

=4.2V, V

=3.7V，

V

=4.2V, V

=3.7V

V

=4.2V, V =3.7V

BATT_FULL BATT

I

=2A

CHG

V

IN

V

IN

1V/div.

V

EN

V

BATT

5V/div.

1V/div.

I

IN

1A/div.

V

I

SW

I

PMID

2V/div.

2A/div.

1A/div.

V

BATT

1V/div.

I

CHG

2A/div.

I

L

1A/div.

IN_PMID_Rdson

vs. Temperature

HS_Rdson

vs. Temperature

LS_Rdson

vs. Temperature

140.0

120.0

100.0

80.0

100.0

80.0

60.0

100.0

60.0

40.0

80.0

60.0

40.0

20.0

-50

0

50

100

-50

0

50

100

-50

0

50

100

MP2626 Rev. 1.0

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11

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

TYPICAL PERFORMANCE CHARACTERISTICS (continued)

V_IN=5V, C_IN=C_BATT=C_PMID=C3=22µF, C1=C2=1µF, L1=4.7µH, RS1=50mΩ, C4=C_TMR=0.1µF, Battery

Simulator, unless otherwise noted.

V

BATT

1V/div.

SW

2V/div.

1V/div.

V

SW

2V/div.

V

IN

1V/div.

I

L

500mA/div.

V

MODE

5V/div.

V

BATT

1V/div.

V

SW

V

SW

2V/div.

V

1V/div.

2V/div.

V

1V/div.

2V/div.

V

IN

1V/div.

I

L

500mA/div.

I

IN

500mA/div.

V

MODE

5V/div.

V

BATT

2V/div.

V

SW

2V/div.

V

1V/div.

2V/div.

V

1V/div.

V

IN

1V/div.

I

IN

500mA/div.

I

IN

500mA/div.

MP2626 Rev. 1.0

2/28/2015

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12

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

TYPICAL PERFORMANCE CHARACTERISTICS (continued)

V_IN=5V, C_IN=C_BATT=C_PMID=C3=22µF, C1=C2=1µF, L1=4.7µH, RS1=50mΩ, C4=C_TMR=0.1µF, Battery

Simulator, unless otherwise noted.

V

BATT

V

1V/div.

BATT

V

BATT

1V/div.

V

SW

V

SW

V

2V/div.

SW

2V/div.

V

IN

1V/div.

I

L

2A/div.

V

IN

1V/div.

V

BATT

V

/AC

1V/div.

V

/AC

IN

500mV/div.

V

BOOST

2V/div.

V

BATT

1V/div.

V

BATT

1V/div.

I

IN

1A/div.

I

L

2A/div.

100

95

6

5

V

/AC

90

85

80

4

3

IN

200mV/div.

V

BATT

1V/div.

2

1

0

I

75

70

IN

500mA/div.

0

0.3

0.6

0.9

1.2 1.5

0

0.5

1

1.5

MP2626 Rev. 1.0

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13

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

PIN FUNCTIONS

Pin #

Name Description

Connect to GND to program the operating frequency to 600kHz. Leave floating or connect to

HIGH to program the operating frequency to 1.2MHz.

1

2

3

FREQ

VIN

Adapter Input. Place a bypass capacitor close to this pin to prevent large input voltage spikes.

Internal Circuit Power Supply. Bypass to GND with a 100nF ceramic capacitor. This pin

CANNOT carry any load.

VCC

Input Current Set. Connect to GND with an external resistor to program input current limit in

charge mode.

4

5

6

ILIM

PWIN

TMR

Input pin to detect the presence of valid input power. Pulling this pin to GND will turn off the IN-

to-PMID pass through MOSFET.

Oscillator Period Timer. Connect a timing capacitor between this pin and GND to set the

oscillator period. Short to GND to disable the Timer function.

Input Voltage Feedback for input voltage regulation loop. Connect to tap of an external resistor

divider from VIN to GND to program the input voltage regulation. Once the voltage at REG pin

drops to the inner threshold, the charge current is reduced to maintain the input voltage at the

regulation value.

7

8

REG

----------------

Valid Input Supply Indicator. Logic LOW on this pin indicates the presence of a valid power

supply.

ACOK

9

FB

Boost Output Voltage Feedback.

10

NTC Negative Temperature Coefficient (NTC) Thermistor.

Programmable Charge Current Pin. Connect an external resistor to GND to program the

charge current.

11

ISET

Programmable Output-Current Limit for boost mode. Connect an external resistor to GND to

program the system current in boost mode.

12

13

14

OLIM

AGND Analog Ground

Programmable Battery-Full Voltage. Leave floating or connect to logic HIGH for 4.2V, while

Connect to GND for 3.6V.

VB

15

16

BATT Positive Battery Terminal / Battery Charge Current Sense Negative Input.

CSP

Battery Charge Current Sense, Positive Input.

-------------------

Boost Mode Indicator. Logic LOW indicates boost mode in operation. This is an open drain pin

during charge mode or sleep mode.

17

18

BOOST

------------

Charge Completion indicator. Logic LOW indicates charge mode. This is an open drain pin

during charge complete or suspended.

CHG

PGND,

19

Exposed Power Ground. Connect the exposed pad and GND pin to the same ground plane.

Pad

20

21, 22

23

SW

Switch Output Node. It is recommended not to place vias on the SW plane during PCB layout.

Connect Point of Blocking Switch and High-side switch. A minimum of 22μF ceramic cap is

required to be placed as close as possible to the PMID and GND pins.

PMID

MODE Mode Select. Logic HIGH→boost mode. Logic LOW→charge mode.

Charge Control Input. Logic HIGH enables charging. Logic LOW disables charging. Active only

__________

24

EN

when ACOK is low (input power is OK)

MP2626 Rev. 1.0

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14

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

BLOCK DIAGRAM

PMID

FB

SW

Q1

HSMOS

VIN

Buffer

VCC

Current

Sense

LSMOS

A1

CSP

Driver

BATT

K1*I_CHG

V_BATT

PWM Signal

Charge

Pump

PGND

ACOK

V_BATT

PWIN

0.8V

FREQ

Mode Control

PWM Controller

1.15V

VSYS

SYS

VCC

Control Logic&

Mode Selection

BATT+

300mV

NTC

T_Ref

MODE

EN

GMT

T_J

VB

V_{BATT_Ref}

ACOK

Thermal

Shutdown

GMV

V_BATT

CHG

REG

BOOST

GMINV

Indication&

Timer

MIN

V_{REG_Ref}

GMI

I_{CHG_Ref}

K1*I_CHG

ISET

ILIM

I_{IN_Ref}

Current Setting

GMINI

TMR

K2*I_IN

AGND

Figure 1: Functional Block Diagram in Charge Mode

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15

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

PMID

FB

SW

HSMOS

Q1

VIN

A1

CSP

VCC

LSMOS

Driver

BATT

Charge

Pump

V_BATT

PWM Signal

Integration

ACOK

PGND

FREQ

To Current

Setting

V_BATT

PWIN

0.8V

Mode Control

PWM Controller

1.15V

VCC

Control Logic&

Mode Selection

BATT+

300mV

NTC

MODE

EN

VB

V_Ref

ACOK

CHG

Thermal

Shutdown

GMV

V_FB

REG

BOOST

Indication&

Timer

I_{OLIM_Ref}

Current Setting

GMINI

TMR

K3*I_SYS

OLIM

AGND

Figure 2: Functional Block Diagram in Boost Mode

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16

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

OPERATION FLOW CHART

POR

MODE High

NO

ACOK

YES

NO

Boost Mode

/BOOST Low

Charge Mode

/CHG Low

Sleep Mode

Figure 3: Mode Selection Flow Chart

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17

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

OPERATION FLOW CHART (continued)

Figure 4: Normal Operation and Fault Protection in Charge Mode

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18

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

OPERATION FLOW CHART (continued)

Power Path Management

V_PWINtouch the V_REG

?

I_INhit the I_{IN_LIMIT}?

No

Yes

Charge Current

Decrease

I_CHG≤0?

No

Yes

I_IN>7A?

No

Normal Operation

I_INexceeds I_IN(OCP)

?

No

Yes

Regulate the I_INat

I_IN(OCP)

No

Yes

T_INOCBLKreaches?

Yes

IN to PMID MOSFET

turns Off

No

T_INRECVRreaches?

Figure 5: Power-Path Management in Charge Mode

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19

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

OPERATION FLOW CHART (continued)

Boost Mode

/BOOST Low

Normal Boost

Operation

No

I_IN> I_OLIM

?

V_BATT>2.9V?

Yes

Output current loop

works, V_SYSdecreases

No

Mode High?

Yes

V_IN< V_BATT

?

Yes

Normal Boost

Operation

V_IN< 2V?

Yes

No

Yes

No

V_BATT<2.5V?

Yes

Down mode

No

I_Lhits the

current limit

T_SYSBLKReaches?

Yes

Boost Turns Off

Yes

Boost Shutdown

No

T_SYSRECVR

Reaches?

Figure 6: Operation Flow Chart in Boost Mode

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MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

START UP TIME FLOW IN CHARGE MODE

Condition: EN = 5V, Mode = 0V, /ACOK and /CHG are always pulled up to an external constant 5V

V_PWIN> 0.8V

0V

&

V_IN

V_IN> V_BATT+ 300mV

5V

0V

EN

Mode

V_CC

V_CCfollows V_IN

2.2V

Band

Gap

0V

5V

ACOK

0V

V_PMID> V_BATT+ 50mV

V_PMID

5V

0V

CHG

SS

400μs

150μs

Force

Charge

I_CC

10%I_CC

Charge

Current

0A

I_BF

Comparator

V_{BATT_FULL}

Battery

Voltage

Auto‐recharge threshold

Assume v_BATT> V_{BATT_TC}

Auto-

recharge

Figure 7: Input Power Start-Up Time Flow in Charge Mode

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21

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

START UP TIME FLOW IN CHARGE MODE

Condition: V_IN= 5V, Mode = 0V, /ACOK and /CHG are always pulled up to an external constant 5V.

Figure 8: EN Start-Up Time Flow in Charge Mode

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22

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

START UP TIME FLOW IN BOOST MODE

Condition: V_{IN_SET}= 5V, Mode = 5V, /Boost is always pulled up to an external constant 5V.

Figure 9: Battery Power Start-Up Time Flow in Boost Mode

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MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

START UP TIME FLOW IN BOOST MODE

Condition: V_{IN_SET}= 5V, /Boost is always pulled up to an external constant 5V.

Figure 10: Mode Start-Up Time Flow in Boost Mode

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MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

OPERATION

Auto-Recharge

INTRODUCTION

Once the battery charge cycle is completed, the

charger remains off. During this time, the system

load may consume battery power, or the battery

may self discharge. To ensure the battery will not

The MP2626 is a highly-integrated, flexible,

switch-mode battery charger with bi-directional

operation for a boost function that can step-up

the battery voltage to power the USB peripheral.

Depending on the status of MODE and VIN, it

operates in three different modes: charge mode,

boost mode and sleep mode.

go into depletion,

a

new charge cycle

automatically begins when the battery voltage

falls below the auto-recharge threshold and the

input power is present. The timer is reset when

the auto-recharge cycle begins.

In charge mode, the MP2626 can work with a

single cell Li-ion or Li-polymer battery. In boost

mode, MP2626 boosts the battery voltage to VIN

to power higher-voltage systems. In sleep mode,

both charging and boosting operations are

disabled and the device enters a power saving

mode to help reduce the overall power

consumption. The MP2626 monitors MODE and

VIN to allow smooth transition between different

modes of operation.

During the off state after the battery is fully

charged, if the input power re-starts or the EN

signal refreshes, the charge cycle will start and

the timer will reset no matter what the battery

voltage is.

CC>>>CV

Threshold

Constant

Charge

Current

I_CHG

V_BAT

CHARGE MODE OPERATION

TC>>>CC

Threshold

Trickle

Charge

Charge Cycle (TC ChargeÆCC ChargeÆCV

Charge)

Current

Trickle charge CC charge

CV charge Charge Full

In charge mode, the MP2626 has five control

loops to regulate the input current, input voltage,

charge current, charge voltage, and device

junction temperature. The MP2626 charges the

battery in three phases: trickle current (TC),

constant current (CC), and constant voltage (CV).

While charging operation is enabled, all five

loops are active but only one determines the IC

behavior. A typical battery charge profile is

depicted in Figure 11(a). The charger stays in TC

charge mode until the battery voltage reaches a

TC-to-CC threshold. Otherwise the charger

enters CC charge mode. When the battery

voltage rises to the CV-mode threshold, the

charger operates in constant voltage mode.

Figure 11 (b) shows a typical charge profile when

the input-current-limit loop dominates during the

CC charge mode. And in this case the charger

maximizes the charging current due to the

switching-mode charger solution, resulting in

faster charging than a traditional linear solution.

(a) Without input current limit

Constant

Charge

Current

CC>>>CV

Threshold

I_CHG

Input

Current

Limit

V_BAT

TC>>>CC

Threshold

Trickle

Charge

Current

Trickle charge CC charge

CV charge Charge Full

(b) With input current limit

Figure 11: Typical Battery Charging Profile

Battery Over-Voltage Protection

The MP2626 has battery over-voltage protection.

If the battery voltage exceeds the battery over-

voltage threshold (103.3% of the battery-full

voltage), charging is disabled. Under this

condition, an internal current source draws a

current from the BATT pin to decrease the

battery voltage and protect the battery.

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MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

Input Voltage Regulation in Charge Mode

Timer Operation in Charge Mode

The MP2626 uses an internal timer to terminate

the charging. The timer remains active during the

charging process. An external capacitor between

TMR and GND programs the charge cycle

duration.

In charge mode, if the input power source is not

sufficient to support both the charge current and

system load current, the input voltage will

decrease. As the input voltage approaches the

programmed input voltage regulation value,

charge current is reduced to allow priority of

system power and maintain proper regulation of

the input voltage.

If charging remains in TC mode beyond the

trickle-charge time τ_{TOTAL_TMR}

,

charging will

terminate. The following equation determines the

length of the trickle-charge period:

The input voltage can be regulated by a resistor

divider from IN pin to REG pin to AGND

according to the following equation:

4.5×10⁴×1.6(V)×C_TMR(μF)

0.52×I_TC(A)×RS1(mΩ) + 2(μA)

The maximum total charge time is:

(１)

τ_{TRICKLE_ TMR}

=

R6

(4)

V_REG= V

×

IN_R

R6+R5

where the V_REGis the internal voltage reference,

1.2V, and the V_{IN_R}is the desired regulation

voltage.

3.4×10⁶×1.6(V)×C_TMR(μF)

0.52×I_TC(A)×RS1(mΩ)+ 2(μA)

(2)

τ_{TRICKLE_TMR}

=

Negative Temperature Coefficient (NTC) Input

for Battery Temperature Monitoring

Input Over-Current Protection and Over

Voltage Protection for Pass-through Path

The MP2626 has a built-in NTC resistance

window comparator, which allows the MP2626 to

monitor the battery temperature via the battery-

integrated thermistor. Connect an appropriate

resistor from V_PMIDto the NTC pin and connect

the thermistor from the NTC pin to GND. The

resistor divider determines the NTC voltage

depending on the battery temperature. If the NTC

voltage falls out of the NTC window, the MP2626

stops charging. The charger will then restart if the

temperature goes back into NTC window range.

Please refer to Application Information section for

the appropriate resistance selection.

The MP2626 has an integrated IN to PMID pass-

through path to allow direct connection of the

input voltage to the system even if charging is

disabled. Based on the above, the MP2626

continuously monitors both input current and

voltage. In the event of an OCP or OVP, charge

current will be reduced to ensure priority of the

system power requirements.

In addition, the MP2626 also features input over

current and voltage protection for the IN to PMID

pass-through path.

Input over-current protection (OCP)

Input-Current Limiting in Charge Mode

When the total input current exceeds 3A, Q2 (Fig

12) is controlled linearly to regulate the current. If

the current continuous to exceed 3A after a

120µs blanking time, Q2 will be turned off. In the

event of input current exceeding 7A, Q2 will be

turned off almost instantaneously and without

any blanking time, this to protect both Q1 and Q2.

The MP2626 has a dedicated pin used to

program the input current limit. The current at

ILIM is a fraction of the input current; the voltage

at ILIM indicates the average input current of the

switching regulator as determined by the resistor

value between ILIM and GND. As the input

current approaches the programmed input

current limit, charge current is reduced to allow

priority to system power.

Use the following equation to determine the input

current limit threshold,

40.5(kΩ)

I =

(A)

ILIM

R_ILIM(kΩ)

(3)

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26

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

Input over-voltage protection (OVP)

voltage drops below the TC threshold. Moreover,

the switching frequency also decreases when the

BATT voltage drops to 40% of the charge-full

voltage.

The MP2626 uses the PWIN pin to sense the

status of input voltage. When the voltage at the

PWIN pin is lower than 0.8V or higher than 1.15V,

an invalid input power source is detected by the

MP2626. At this time the IN to PMID pass-

through path will be turned off. An OVP threshold

can be programmed via PWIN pin to prevent an

over voltage event happening at PMID side when

plugging in a wrong adapter.

Thermal Foldback Function

The MP2626 implements thermal protection to

prevent thermal damage to the IC and the

surrounding components. An internal thermal

sense and feedback loop automatically

decreases the programmed charge current when

the die temperature reaches 120°C. This function

is called the charge-current-thermal foldback. Not

only does this function protect against thermal

damage, it can also set the charge current based

on requirements rather than worst-case

conditions while ensuring safe operation.

Furthermore, the part includes thermal shutdown

protection where the ceases charging if the

junction temperature rises to 150°C.

Non-sync Operation Mode

Figure12: Integrated Pass-through Path

Charge Current Setting

During charging mode, the MP2626 continuously

monitors the total input current flowing from IN

pin to PMID pin. When the input current is lower

than 170mA, the low side switch operates as a

non-synchronous MOSFET.

The external sense resistors, RS1 and R_ISET

program the battery charge current, I_CHG. Select

,

R_ISETbased on RS1:

Fully Operation Indication

2800

(5)

I_CHG(A) =

R_ISET(kΩ)×RS1(mΩ)

The MP2626 integrates indicators for the

following conditions as shown in Table 2.

When timer or NTC fault happens, charging will

Battery Short Protection

The MP2626 has two current limit thresholds. CC

and CV modes have a peak current limit

threshold of 4.5A, while TC mode has a current

limit threshold of 1.5A. Therefore, the current limit

threshold decreases to 1.5A when the battery

terminate or be suspended and indication of

------------

CHG blinks in a frequency f_BLK

:

2(μA)

1.46(V)×C_TMR(μF)

(6)

f_BLK

=

Table 2: Indicator for Each Operation Mode

----------------

------------

-------------------

Operation

ACOK

CHG

BOOST

Charging

Low

End of Charge, charging disabled

NTC Fault, Timer Out

High

Charge Mode

Boost Mode

Low

High

Blinking

High

Low

Sleep Mode, VCC absent

High

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MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

Boost Output-Current Limiting

The MP2626 integrates a programmable output

current limit function in boost mode. If the boost

output current exceeds this programmable limit,

the output current will be limited at this level and

the VIN voltage will start to drop down. The OLIM

pin programs the current limit threshold up to

1.5A as per the following equation:

BOOST MODE OPERATION

Low-Voltage Start-Up

The minimum battery voltage required to start up

the circuit in boost mode is 2.9V. Initially, when

V_PMID< V_BATT, the MP2626 works in down mode.

In this mode, the synchronous P-MOSFET stops

switching and its gate connects to V_BATTstatically.

The P_MOSFET keeps off as long as the voltage

2800

(7)

I_OLIM(A) =

×1.6

R_OLIM(kΩ)×RS1((mΩ)

across the parasitic C_DS(V_SW) is lower than V_BATT

.

When the voltage across C_DSexceeds V_BATT, the

synchronous P-MOSFET enters a linear mode

allowing the inductor current to decrease and

flowing into the PMID pin. Once V_PMIDexceeds

V_BATT, the P-MOSFET gate is released and

normal closed-loop PWM operation is initiated. In

boost mode, the battery voltage can drop to as

low as 2.5V without affecting circuit operation.

Boost Output Over-Current Protection

The MP2626 integrates three-phase output over-

current protection.

Phase one (boost mode output current limit):

when the output current exceeds the

programmed output current limit, the output

constant current loop controls the output current,

the output current remains at its limit of I_OLIM, and

VIN decreases.

Output Disconnect and Inrush Limiting

Phase two (down mode): when VIN drops below

V_BATT+100mV and the output current loop

remains in control, the boost converter enters

down mode and shutdown after a 120μs blanking

time.

The MP2626 allows for true output disconnect by

eliminating body diode conduction of the internal

P-MOSFET rectifier. VIN can go to 0V during

shutdown, drawing no current from the input

source. It also allows for inrush current limiting at

start-up, minimizing surge currents from the input

supply. To optimize the benefits of output

disconnect, avoid connecting an external

Schottky diode between the SW and PMID pins.

Board layout is extremely critical to minimize

voltage overshoot at the SW pin due to stray

inductance. Keep the output filter capacitor as

close as possible to the PMID pin and use very

low ESR/ESL ceramic capacitors tied to a good

ground plane.

Phase three (short circuit mode): when VIN

drops below 2V, the boost converter shuts down

immediately once the inductor current hits the

fold-back peak current limit of the low side N-

MOSFET. The boost converter can also recover

automatically after a 1ms deglitch period.

Thermal Shutdown Protection

Thermal shutdown protection is also active in

boost mode. Once the junction temperature rises

higher than 150°C, the MP2626 enters thermal

shutdown. It will not resume normal operation

until the junction temperature drops below 120°C.

Boost Output Voltage Setting

In boost mode, the MP2626 programs the output

voltage via the external resistor divider at FB pin,

and provides built-in output over-voltage

protection (OVP) to protect the device and other

components against damage when VIN goes

beyond 6V. Once the output over-voltage occurs,

the MP2626 turns off the boost converter. When

the voltage on VIN drops to a normal level, the

boost converter restarts again as long as the

MODE pin remains active.

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28

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

APPLICATION INFORMATION

COMPONENT SELECTION

V − V

IN

R3 =

^PWIN×R4

(12)

Setting the Charge Current in Charge Mode

V_PWIN

For a typical application, start with R4=5.1kꢀ, R3

is 21.5kꢀ.

In charge mode, both the external sense resistor,

RS1, and the resistor R_ISETconnect to the ISET

pin to set the charge current (I_CHG) of the MP2626.

Setting the Input Voltage Regulation in

Charge Mode

(see the Typical Application Circuit)

Given I_CHGand RS1, RISET can be calculated as:

2800

In Charge mode, connect a resistor divider from

the VIN to GND with tapped to REG pin to

program the input voltage regulation.

(8)

R_ISET(kΩ) =

I_CHG(A)×RS1((mΩ)

R6+R5

V

= V_REG

×

(V)

IN_R

(13)

R6

For example, for I_CHG=2A, and RS1=50mΩ, thus:

R_ISET=28kΩ.

With the given R6, R5 is:

_{IN_R}− V

Setting the input Current Limiting in Charge

Mode

V

R5 =

^REG×R6(V)

(14)

V_REG

In charge mode, connect a resistor from the ILIM

pin to AGND to program the input current limit.

The relationship between the input current limit

and setting resistor is as following:

For a preset input voltage regulation value, say

4.75V, start with R6=5.1kꢀ, R5 is 15kꢀ.

NTC Function in Charge Mode

Figure 13 shows that an internal resistor divider

sets the low temperature threshold (V_TL) and high

temperature threshold (V_TH) at 66.3%·V_PMIDand

35%·V_PMIDrespectively. For a given NTC

thermistor, select an appropriate R_T1and R_T2to

set the NTC window.

40.5(kΩ)×1(A)

R_ILIM(kΩ) =

(9)

I_{IN_LIM}(A)

Where, R_ILIMmust exceed 15kΩ so that I_{IN_LIM}is

in the range of 0A to 2.7A.

R_T2//R_{NTC _Cold}

V_TL

For

most

applications,

(I_{USB_LIM}=900mA) for USB3.0 mode, and use

use

R_ILIM=45kΩ

(15)

=

= TL = 66.3%

V_SYSR_T1+ R_T2//R_{NTC _Cold}

R_ILIM=81kΩ (I_{USB_LIM}=500mA) for USB2.0 mode.

R_T2//R_{NTC _Hot}

V_SYSR_T1+ R_T2//R_{NTC _ Hot}

V_TH

=

= TH = 35%

(16)

Setting the Input Voltage Range for Different

Operation Modes

A resistive voltage divider from the input to PWIN

pin determines the operation mode of MP2626.

Where R_{NTC_Hot}is the value of the NTC resistor at

the upper bound of its operating temperature

range, and R_{NTC_Cold}is its lower bound.

R4

V_PWIN= V ×

IN

(10)

R4 +R3

The two resistors, R_T1and R_T2, independently

determine the upper and lower temperature limits.

This flexibility allows the MP2626 to operate with

most NTC resistors for different temperature

range requirements. Calculate R_T1and R_T2as

follows:

When MP2626 works in the charge mode (see

Table1), the voltage on PWIN should be between

0.8V and 1.15V. For a wide operating range, use

a maximum input voltage of 6V as the upper

threshold for a voltage ratio of:

R_{NTC _ hot}×R_{NTC _ Cold}×(TL − TH)

R_T1

=

(17)

V_PWIN1.15

R4

TH× TL×(R_{NTC _ Cold}−R_{NTC _Hot}

)

=

(11)

V

6

R4 + R3

IN

With the given R4 and R3,

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MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

R_{NTC_hot}×R_{NTC _Cold}×(TL−TH)

(1−TL)×TH×R_{NTC_ Cold}−(1−TH)×TH×R_{NTC_Hot}

In the boost mode, connect a resistor form the

OLIM pin to AGND to program the output current

limit. The relationship between the output current

limit and setting resistor is as follows:

R_T2

=

(18)

)

For example, the NCP18XH103 thermistor has

the following electrical characteristic:

2800

(21)

At 0^oC, R_{NTC_Cold}=27.445kΩ;

R_OLIM(kΩ) =

×1.6

I_OLIM(A)× RS1(mΩ)

At 50^oC, R_{NTC_Hot}=4.1601kΩ;

The output current limit of the boost can be

programmed up to 1.5A (min). Considering 15%

output current limit accuracy, typical 1.79A output

current limit is required. According to the above

equation, given 50mꢀ sense resistor, 49.9kꢀ

ROLIM will get 1.79A output current limit.

Base on equation (17) and equation (18),

R_T1=6.65kΩ and R_T2=24.9kΩ are suitable for an

NTC window between 0^oC and 50^oC

If no external NTC is available, connect R_T1and

R_T2to keep the voltage on the NTC pin within the

valid NTC window: e.g., R_T1=R_T2=10kΩ.

Selecting the Inductor

Inductor selection trades off between cost, size,

and efficiency.

A

lower inductance value

corresponds with smaller size, but results in

higher ripple currents, higher magnetic hysteretic

losses, and higher output capacitances. However,

a higher inductance value benefits from lower

ripple current and smaller output filter capacitors,

but results in higher inductor DC resistance (DCR)

loss.

Figure 13: NTC Function Block

Choose an inductor that does not saturate under

the worst-case load condition.

For Convenience, an NTC thermistor design

spreadsheet is also provided, please inquire if

necessary.

1. In Charge Mode

When MP2626 works in charge mode (as a Buck

Converter), estimate the required inductance as:

Setting the Output Voltage in Boost Mode

V − V_BATTV_BATT

IN

In the boost mode, the output voltage on the VIN

pin can be regulated to the value customer

required between 4.2V and 6V by the resistor

divider at FB pin as R1 and R2 in the typical

application circuit.

L =

×

(22)

ΔI_{L _MAX}

V × f_S

IN

Where VIN, V_BATT, and f_SWare the typical input

voltage, the CC charge threshold, and the

switching frequency, respectively. ΔI_{L_MAX}is the

maximum inductor ripple current, which is usually

designed at 30% of the CC charge current.

R1+ R2

V = 1.2V ×

(19)

IN

R2

Where, 1.2V is the voltage reference of boost

output voltage. With a typical value for R2, 10kΩ,

R1 can be determined by:

With a typical 5V input voltage, 30% inductor

current ripple at the corner point between trickle

charge and CC charge (V_BATT=3V), the

inductance is 2.2μH (for a 1.2MHz switching

frequency) and 4.4μH (for a 600kHz switching

frequency).

V −1.2V

IN

R1 =

×R2

(20)

1.2V

For example, for a 5V output voltage, R2 is 10kΩ,

and R1 is 31.6kΩ.

Setting the Output Current Limit in Boost

Mode

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30

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

2 In Boost Mode

The capacitor C_PMIDacts as the input capacitor of

the buck converter in the charge mode. The input

effective ripple current:

When the MP2626 is in boost mode (as a Boost

Converter), the required inductance value is

calculated as:

V_TC×(VIN_MAX− V_TC)

I_{RMS _MAX}= I_{CC _MAX}

×

(26)

VIN_MAX

V − V_BATT

V

IN

L =

×

(23)

(24)

ΔI_{L _MAX}

V_BATT× f_S

2. Boost Mode

The capacitor, C_PMID, is the output capacitor of

the boost converter. C_PMIDkeeps the output

voltage ripple small and ensures feedback loop

stability. The output effective ripple current is

given by:

ΔI_{L _MAX}= (30% − 40%)×I_BATT(MAX)

V ×I

IN

IN_MAX

I_BATT(MAX)

=

(25)

V_BATT× η

Where V_BATTis the minimum battery voltage, f_SW

is the switching frequency, and ΔI_{L_MAX}is the

peak-to-peak inductor ripple current, which is

approximately 30% of the maximum battery

current I_BATT(MAX), I_{IN_MAX}is the maximum output

current and η is the efficiency.

V_TC×(VIN_MAX− V_TC)

I_{RMS _MAX}= I_{CC _MAX}

×

(27)

VIN_MAX

Since the input voltage is passes to PMID directly,

_{IN_MAX}=V_{PMID_MAX}, both charge mode and boost

mode have the same current ripple.

V

In the worst case where the battery voltage is 3V,

a 30% inductor current ripple, and a typical boost

output voltage (VIN=5V), the inductance is 2.0μH

(for a 1.2MHz switching frequency) and 4.0μH

(for a 600 kHz switching frequency) when the

efficiency is about 90% and I_{IN_MAX}1.5A.

For I_{CC_MAX}=1.5A, V_TC=3V, V_{IN_MAX}=6V, the

maximum effective ripple current is 0.75A, Select

the PMID capacitors base on the ripple-current

temperature rise not exceeding 10^oC. For best

results, use ceramic capacitors with X7R

dielectrics with low ESR and small temperature

coefficients. For most applications, use one 22μF

capacitor.

For Best results, use an inductor with an

inductance of 2.2μH (for a 1.2MHz switching

frequency) and 4.4μH (for a 600kHz switching

frequency) with a DC current rating that is at least

30% higher maximum charge current for

applications. For higher efficiency, minimize the

inductor’s DC resistance. For higher efficiency,

minimize the inductor’s DC resistance.

Selecting the Battery Capacitor C_BATT

C_BATTis in parallel with the battery to absorb the

high-frequency switching ripple current.

1. Charge Mode

The capacitor C_BATTis the output capacitor of the

buck converter. The output voltage ripple is then:

Selecting the Input Capacitor C_IN

The input capacitor C_INreduces both the surge

current drawn from the input and 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 from passing to

in the input. For best cases, use ceramic

capacitors with X7R dielectrics because of their

low ESR and small temperature coefficients. For

most applications, a 22μF capacitor will suffice.

ΔV_BATT

V_BATT

1− V_BATT/ V

IN

Δr_BATT

=

(28)

8×C_BATT× f_S²×L

2. Boost Mode

The capacitor C_BATTis the input capacitor of the

boost converter. The input voltage ripple is the

Selecting the PMID Capacitor C_PMID

Select C_PMIDbased on the demand of the current

ripple.

1. Charge Mode

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31

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

same as the output voltage ripple from equation

(28).

3) The PCB should have a ground plane

connected directly to the return of all components

through vias (e.g. two vias per capacitor for

power stage capacitors, one via per capacitor for

small-signal components). If possible, add vias

inside the exposed pads for the IC. A star ground

design approach is typically used to keep the

circuit block currents isolated (power-signal /

control-signal), which reduces noise-coupling and

ground-bounce issues. A single ground plane for

this design gives good results.

Both charge mode and boost mode have the

same battery voltage ripple. The capacitor C_BATT

can be calculated as:

1− V_TC/ V __MAX

IN

C_BATT

=

(29)

8× Δr_{BATT _MAX}× f_S²×L

To guarantee the ±0.5% BATT voltage accuracy,

the maximum BATT voltage ripple must not

exceed 0.5% (e.g. 0.2%). The worst case occurs

at the minimum battery voltage of the CC charge

with the maximum input voltage.

4) Place ISET, OLIM and ILIM resistors very

close to their respective IC pins.

For VIN_MAX=6V, V_{CC_MIN}=V_TC=3V, L=4.4μH,

f_SW=600kHz or 1.2MHz, Δr_{BATT_MAX}=0.1%, C_BATTis

8.9μF (for a 600kHz switching frequency) or

5.6μF (for a 1.2MHz switching frequency).

FREQ

VIN

CHG

BOOST

CSP

VCC

ILIM

BATT

PWIN

TMR

VB

AGND

A 22μF ceramic with X7R dielectrics capacitor

will suffice.

PCB LAYOUT GUIDE

PCB layout is very important to meet specified

noise, efficiency and stability requirements. The

following design considerations can improve

circuit performance:

Figure 14: PCB Layout Guide

DESIGN EXAMPLE

1) Route the power stage adjacent to their

grounds. Aim to minimize the high-side switching

node (SW, inductor) trace lengths in the high-

current paths

Below is a design example following the

application guides for the specifications:

Table 3 Design Example

V_IN

V_OUT

f_SW

5V

3.7V

1200KHz

Keep the switching node short and away from all

small control signals, especially the feedback

network.

Place the input capacitor as close as possible to

the VIN and PGND pins. The local power input

capacitors, connected from the PMID to GND,

must be placed as close as possible to the IC.

Figure 15 shows the detailed application

schematic. The Typical Performance

Characteristics section shows the typical

performance and circuit waveforms. For more

possible applications of this chip, please refer to

the related Evaluation Board datasheets.

Place the output inductor close to the IC and

connect the output capacitor between the

inductor and PGND of the IC.

2) For high-current applications, the power pads

for IN, SW, BATT and PGND should be

connected to as many copper planes on the

board as possible. The exposed pad should

connect to as many GND copper planes on the

board as possible, too. This improves thermal

performance because the board conducts heat

away from the IC.

MP2626 Rev. 1.0

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32

MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

TYPICAL APPLICATION CIRCUITS

SYS

R_Single

VIN

SYS

0

R_Dual

R1

R2

C7

22uF

PMID

FB

C2

NC

31.6K

C8

10K

CSYS

22uF

1

2

ROLM

49.9K

PGND

NC

1uF

PMID

FB

VIN

U1

C5

NC

R4

R3

RS1

CIN

C1

SW 1

2

VBATT

22uF 1uF

5.1K

R6

21.5K

R5

BATT

L1

4.7uH

50m

2

7

5

20

C3 CBATT

22uF 22uF

PGND

VCC

VIN

SW

C6

NC

5.1K

15K

16

15

10

CSP

BATT

NTC

REG

VCC

NTC

SYS

VCC

R6

10K

R7

10K

R8

10K

PWIN

RT2

10K

1 3

RT1 10K

C4

100nF

1

3

1

2

MP2626

14

18

8

JP4

VB

CHG

10K R5

VCC

3

1

2

JP3

JP1

JP2

VCC

FREQ

EN

2K R9

2K R10

2K R11

LED1

1

ACOK

BOOST

ISET

LED2

24

23

4

17

11

6

1

2

LED

2

JP5

LED3

MODE

ILIM

VBATT

RISET

28K

TMR

CTMR

100nF

RILIM

15K 1%

AGND

Figure 15: Detailed Application Circuit

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MP2626 – SINGLE CELL LI-ION SWITCHING CHARGER WITH USB OTG

PACKAGE INFORMATION

QFN-24 (4mmx4mm)

3.90

4.10

2.50

2.80

PIN 1 ID

SEE DETAIL A

19

24

PIN 1 ID

MARKING

18

1

6

0.50

BSC

3.90

4.10

2.50

2.80

PIN 1 ID

INDEX AREA

0.18

0.30

13

12

7

0.35

0.45

TOP VIEW

BOTTOM VIEW

PIN 1 ID OPTION A

0.30x45º TYP.

PIN 1 ID OPTION B

R0.25 TYP.

0.80

1.00

0.20 REF

0.00

0.05

DETAIL A

SIDE VIEW

3.90

2.70

NOTE:

1) ALL DIMENSIONS ARE IN MILLIMETERS.

2) EXPOSED PADDLE SIZE DOES NOT INCLUDE MOLD FLASH.

3) LEAD COPLANARITY SHALL BE0.10 MILLIMETER MAX.

4) DRAWING CONFIRMS TO JEDEC MO-220, VARIATION VGGD.

5) DRAWING IS NOT TO SCALE.

0.70

0.25

0.50

RECOMMENDED LAND PATTERN

NOTICE: The information in this document is subject to change without notice. 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.

MP2626 Rev. 1.0

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34


型号：	MP2626GR
厂家：	MONOLITHIC POWER SYSTEMS
描述：	USB-Compliant Single Cell Li-ion Switching Charger with USB-OTG Boost
文件：	总34页 (文件大小：1032K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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