LTC3559_技术文档

LTC3559/LTC3559-1

Linear USB Battery Charger

with Dual Buck Regulators

FEATURES

DESCRIPTION

The LTC^®3559/LTC3559-1 are USB battery chargers with

dual high efﬁciency buck regulators. The parts are ideally

suitedtopowersingle-cellLi-Ion/Polymerbasedhandheld

applications needing multiple supply rails.

Battery Charger

n

Standalone USB Charger

n

Up to 950mA Charge Current Programmable via

Single Resistor

n

HPWR Input Selects 20% or 100% of Programmed

Battery charge current is programmed via the PROG pin

and the HPWR pin, with capability up to 950mA at the BAT

pin. The battery charger has an NTC input for temperature

qualiﬁed charging. The CHRG pin allows battery status to

be monitored continuously during the charging process.

An internal timer controls charger termination.

Charge Current

n

NTC Input for Temperature Qualiﬁed Charging

n

Internal Timer Termination

Bad Battery Detection

CHRG Indicates C/10 or Timeout

n

Buck Regulators

Each monolithic synchronous buck regulator provides up

to 400mA of output current while operating at efﬁciencies

greater than 90% over the entire Li-Ion/Polymer range.

A MODE pin provides the ﬂexibility to place both buck

regulators in a power saving Burst Mode^®operation or a

low noise pulse skip mode.

n

400mA Output Current

n

2.25MHz Constant Frequency Operation

n

Zero Current in Shutdown

Low Noise Pulse Skip Operation or Power Saving

Burst Mode Operation

Low No-Load Quiescent Current: 35μA

Available in a Low Proﬁle Thermally Enhanced

16-Lead 3mm × 3mm QFN Package

n

The LTC3559/LTC3559-1 are offered in a low proﬁle ther-

mally enhanced 16-lead (3mm × 3mm) QFN package.

L, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.

All other trademarks are the property of their respective owners.

APPLICATIONS

n

SD/Flash-Based MP3 Players

Low Power Handheld Applications

n

TYPICAL APPLICATION

USB Charger Plus Dual Buck Regulators

UP TO 500mA

USB (4.3V TO 5.5V)

OR AC ADAPTOR

V

CC

BAT

SINGLE

+

1μF

Li-lon CELL

PV

IN

(2.7V TO 4.2V)

2.2μF

NTC

LTC3559

4.7μH

22pF

1.74k

2.5V

PROG

SW1

FB1

400mA

655k

309k

10μF

CHRG

SUSP

HPWR

EN1

DIGITAL

CONTROL

4.7μH

22pF

1.2V

400mA

SW2

FB2

324k

10μF

EN2

649k

MODE

GND

EXPOSED

PAD

3559 TA01

3559fb

1

LTC3559/LTC3559-1

ABSOLUTE MAXIMUM RATINGS

PIN CONFIGURATION

(Note 1)

V

(Transient);

TOP VIEW

CC

t < 1ms and Duty Cycle < 1%....................... –0.3V to 7V

(Static) .................................................. –0.3V to 6V

V

CC

16 15 14 13

BAT, CHRG, SUSP ........................................ –0.3V to 6V

GND

BAT

1

2

3

4

12 HPWR

11 SUSP

HPWR, NTC, PROG.......–0.3V to Max (V , BAT) + 0.3V

CC

17

MODE

FB1

FB2

EN2

10

9

PROG Pin Current...............................................1.25mA

BAT Pin Current ..........................................................1A

5

6

7

8

PV ................................................ –0.3V to BAT + 0.3V

IN

EN1, EN2, MODE.......................................... –0.3V to 6V

UD PACKAGE

16-LEAD (3mm s 3mm) PLASTIC QFN

FB1, FB2, SW1, SW2 ............–0.3V to PV + 0.3V or 6V

IN

I

, I

......................................................600mA DC

T

= 125°C, θ = 68°C/W

JA

JMAX

SW1 SW2

EXPOSED PAD (PIN 17) IS GND, MUST BE SOLDERED TO PCB

Junction Temperature (Note 2) ............................. 125°C

Operating Temperature Range (Note 3).... –40°C to 85°C

Storage Temperature.............................. –65°C to 125°C

ORDER INFORMATION

LEAD FREE FINISH

LTC3559EUD#PBF

LTC3559EUD-1#PBF

TAPE AND REEL

PART MARKING

LCMB

PACKAGE DESCRIPTION

TEMPERATURE RANGE

LTC3559EUD#TRPBF

LTC3559EUD-1#TRPBF

–40°C to 85°C

16-Lead (3mm × 3mm) Plastic QFN

LDQD

Consult LTC Marketing for parts speciﬁed with wider operating temperature ranges.

Consult LTC Marketing for information on non-standard lead based ﬁnish parts.

For more information on lead free part marking, go to: http://www.linear.com/leadfree/

For more information on tape and reel speciﬁcations, go to: http://www.linear.com/tapeandreel/

ELECTRICAL CHARACTERISTICS ^Thel denotes speciﬁcations that apply over the full operating temperature

range, otherwise speciﬁcations are at T_A= 25°C.

SYMBOL

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

Battery Charger. V = 5V, BAT = PV = 3.6V, R

= 1.74k, HPWR = 5V, SUSP = NTC = EN1 = EN2 = 0V

CC

IN

PROG

l

V

Input Supply Voltage

4.3

5.5

V

CC

I

Battery Charger Quiescent Current (Note 4) Standby Mode, Charge Terminated

200

8.5

400

17

μA

VCC

Suspend Mode, V

= 5V

SUSP

V

FLOAT

BAT Regulated Output Voltage

LTC3559

4.179

4.165

4.200

4.221

4.235

V

0°C ≤ T ≤ 85°C, LTC3559

A

LTC3559-1

4.079

4.065

4.100

4.121

4.135

V

0°C ≤ T ≤ 85°C, LTC3559-1

A

l

I

Constant-Current Mode Charge Current

Battery Drain Current

HPWR = 5V

HPWR = 0V

440

84

460

92

500

100

mA

CHG

Standby Mode, Charger Terminated

–3.5

–2.5

–1.5

–7

–4

–3

μA

BAT

Shutdown, V < V

, BAT = V

CC

UVLO

FLOAT

Suspend Mode, SUSP = 5V, BAT = V

FLOAT

V

Undervoltage Lockout Threshold

Undervoltage Lockout Hysteresis

BAT = 3.5V, V Rising

3.85

4.0

4.125

V

UVLO

CC

BAT = 3.5V

200

mV

ΔV

UVLO

V

Differential Undervoltage Lockout

Threshold

BAT = 4.05V, (V – BAT) Falling (LTC3559)

30

50

70

mV

DUVLO

CC

BAT = 3.95V, (V – BAT) Falling (LTC3559-1)

CC

3559fb

2

LTC3559/LTC3559-1

ELECTRICAL CHARACTERISTICS ^Thel denotes speciﬁcations that apply over the full operating temperature

range, otherwise speciﬁcations are at T_A= 25°C.

SYMBOL

ΔV

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

Differential Undervoltage Lockout

Hysteresis

BAT = 4.05V (LTC3559)

BAT = 3.95V (LTC3559-1)

130

mV

DUVLO

V

PROG Pin Servo Voltage

HPWR = 5V

HPWR = 0V

1.000

0.200

0.100

V

PROG

BAT < V

TRKL

h

Ratio of I to PROG Pin Current

800

46

mA/mA

mA

PROG

BAT

I

Trickle Charge Current

BAT < V

36

56

TRKL

V

Trickle Charge Threshold Voltage

Trickle Charge Hysteresis Voltage

Recharge Battery Threshold Voltage

Recharge Comparator Filter Time

Safety Timer Termination Period

Bad Battery Termination Time

BAT Rising

2.8

2.9

100

–100

1.7

4

3.0

V

TRKL

mV

ΔV

TRKL

Threshold Voltage Relative to V

BAT Falling

–85

–130

mV

FLOAT

RECHRG

t

ms

RECHRG

BAT = V

BAT < V

3.5

0.4

4.5

0.6

Hour

mA/mA

ms

TERM

FLOAT

TRKL

0.5

0.1

2.2

500

BADBAT

h

End-of-Charge Indication Current Ratio

End-of-Charge Comparator Filter Time

(Note 5)

Falling

0.085

0.11

C/10

t

I

BAT

R

Battery Charger Power FET On-Resistance I = 190mA

BAT

mΩ

ON(CHG)

(Between V and BAT)

CC

T

Junction Temperature in Constant

Temperature Mode

105

°C

LIM

NTC

V

Cold Temperature Fault Threshold Voltage Rising NTC Voltage

Hysteresis

75

33.4

0.7

–1

76.5

1.6

78

36.4

2.7

1

%V

COLD

HOT

DIS

CC

Hot Temperature Fault Threshold Voltage Falling NTC Voltage

Hysteresis

34.9

1.6

%V_CC

l

NTC Disable Threshold Voltage

Falling NTC Voltage

Hysteresis

1.7

50

%V

CC

mV

μA

I

NTC Leakage Current

V

= V = 5V

NTC CC

NTC

Logic (HPWR, SUSP, CHRG)

V

Input Low Voltage

HPWR, SUSP Pins

0.4

V

IL

Input High Voltage

1.2

1.9

IH

l

R

Logic Pin Pull-Down Resistance

CHRG Pin Output Low Voltage

CHRG Pin Input Current

4

100

0

6.3

250

1

MΩ

mV

μA

DN

V

I

= 5mA

CHRG

I

BAT = 4.5V, V

= 5V

CHRG

Buck Switching Regulators, BAT = PV = 3.8V, EN1 = EN2 = 3.8V

IN

l

PV

IN

Input Supply Voltage

LTC3559

LTC3559-1

3

4.2

4.1

V

I

Pulse Skip Supply Current

Burst Mode Supply Current

Shutdown Supply Current

Supply Current in UVLO

MODE = 0 (One Buck Enabled) (Note 6)

MODE = 1 (One Buck Enabled) (Note 6)

EN1 = EN2 = 0V

220

35

0

400

50

2

μA

PVIN

l

PV = 2.0V

4

8

IN

PV UVLO PV Falling

2.45

2.55

V

IN

PV Rising

IN

f

Switching Frequency

Input Low Voltage

MODE = 0V

1.91

2.25

2.59

0.4

MHz

V

OSC

V

MODE, EN1, EN2

MODE = 0V or 3.8V

IL

Input High Voltage

1.2

V

IH

I

Peak PMOS Current Limit

550

800

1050

mA

LIMSW

3559fb

3

LTC3559/LTC3559-1

ELECTRICAL CHARACTERISTICS ^Thel denotes speciﬁcations that apply over the full operating temperature

range, otherwise speciﬁcations are at T_A= 25°C.

SYMBOL

PARAMETER

CONDITIONS

MIN

780

TYP

MAX

820

UNITS

mV

μA

l

V

Feedback Voltage

FB Input Current

Maximum Duty Cycle

800

FB

I

FB1, FB2 = 0.82V

FB1, FB2 = 0V

–0.05

100

0.05

FB

D

R

%

MAX

R

of PMOS

of NMOS

I

= 150mA

0.65

0.75

13

Ω

PMOS

NMOS

SW(PD)

DS(ON)

SW

= –150mA

Ω

SW Pull-Down in Shutdown

kΩ

Note 1: Stresses beyond those listed under Absolute Maximum Ratings

may cause permanent damage to the device. Exposure to any Absolute

Maximum Rating condition for extended periods may affect device

reliability and lifetime.

temperature range are assured by design, characterization and correlation

with statistical process controls.

Note 4: V supply current does not include current through the PROG pin

CC

or any current delivered to the BAT pin. Total input current is equal to this

Note 2: T is calculated from the ambient temperature T and power

speciﬁcation plus 1.00125 • I where I is the charge current.

J

A

BAT BAT

dissipation P according to the following formula:

D

Note 5: I

is expressed as a fraction of measured full charge current

C/10

T = T + (P • θ °C/W)

with indicated PROG resistor.

J

A

D

JA

Note 3: The LTC3559/LTC3559-1 are guaranteed to meet speciﬁcations

Note 6: FB high, regulator not switching.

from 0°C to 85°C. Speciﬁcations over the –40°C to 85°C operating

TYPICAL PERFORMANCE CHARACTERISTICS

Battery Regulation (Float) Voltage

vs Battery Charge Current,

Constant-Voltage Charging

Suspend State Supply and BAT

Currents vs Temperature

Battery Regulation (Float)

Voltage vs Temperature

10

9

8

7

6

5

4

3

2

1

0

4.250

4.205

4.200

4.195

4.190

4.185

4.180

4.175

4.170

4.165

4.160

4.155

4.150

V

CC

= 5V

4.225

4.200

I

VCC

LTC3559

4.175

4.150

4.125

4.100

4.075

V

= 5V

CC

BAT = 4.2V

SUSP = 5V

EN1 = EN2 = 0V

LTC3559-1

V

= 5V

CC

I

BAT

HPWR = 5V

R

= 845Ω

PROG

EN1 = EN2 = 0V

4.050

–55

–15

5

25

45

65

85

–55

–35 –15

5

25

45

65

85

–35

0

100 200 300 400 500 600 700 800 9001000

TEMPERATURE (°C)

I

(mA)

BAT

3559 G01

3559 G02

3559 G03

3559fb

4

LTC3559/LTC3559-1

TYPICAL PERFORMANCE CHARACTERISTICS

Battery Charge Current

vs Ambient Temperature in

Thermal Regulation

Battery Charge Current

vs Supply Voltage

Battery Charge Current

vs Battery Voltage (LTC3559)

500

450

400

350

300

250

200

150

500

495

490

485

480

475

470

465

460

455

450

445

440

500

450

400

350

300

250

200

150

100

50

HPWR = 5V

V

= 5V

V

= 5V

PROG

CC

HPWR = 5V

= 1.74k

R

= 1.74k

R

PROG

EN1 = EN2 = 0V

V

= 5V

HPWR = 0V

CC

100

50

0

HPWR = 5V

= 1.74k

R

PROG

EN1 = EN2 = 0

0

4.3 4.4

4.6

4.8 4.9 5.0 5.1 5.2 5.3 5.4 5.5

85

105 125

4.5

4.7

–55 –35 –15

5

25 45 65

2

2.5

3

V

3.5

(V)

4

4.5

V

CC

(V)

TEMPERATURE (°C)

BAT

3559 G04

3559 G06

3559 G05

Battery Drain Current in

Undervoltage Lockout

vs Temperature

Battery Charger Undervoltage

PROG Voltage

Lockout Threshold vs Temperature

vs Battery Charge Current

3.0

2.5

2.0

1.5

1.2

1.0

4.2

4.1

V

CC

= 5V

EN1 = EN2 = 0V

BAT = 3.5V

HPWR = 5V

= 1.74k

R

PROG

BAT = 4.2

(LTC3559)

RISING

EN1 = EN2 = 0V

4.0

3.9

3.8

3.7

3.6

0.8

0.6

BAT = 3.6

FALLING

1.0

0.5

0

0.4

0.2

0

3.5

25

TEMPERATURE (°C)

65

85

–55 –35 –15

5

45

25

TEMPERATURE (°C)

65

85

0

50 100 150 200 250 300 350 400 450 500

(mA)

–55 –35 –15

5

45

I

BAT

3559 G08

3559 G09

3559 G07

Recharge Threshold

vs Temperature

Battery Charger FET

On-Resistance vs Temperature

SUSP/HPWR Pin Rising

Thresholds vs Temperature

115

111

107

103

99

1.2

700

650

600

550

500

450

400

350

300

V

CC

= 5V

V

BAT

EN1 = EN2 = 0V

= 4V

V

CC

= 5V

CC

I

= 200mA

1.1

1.0

0.9

0.8

0.7

0.6

0.5

95

91

87

83

79

0.4

75

–15

5

25

45

65

85

–35 –15

25

45

65

85

–55 –35

–55

5

–55

–15

5

25

45

65

85

–35

TEMPERATURE (°C)

3559 G11

3559 G12

3559 G10

3559fb

5

LTC3559/LTC3559-1

TYPICAL PERFORMANCE CHARACTERISTICS

CHRG Pin Output Low Voltage

vs Temperature

CHRG Pin I-V Curve

Timer Accuracy vs Supply Voltage

2.0

1.5

1.0

0.5

0

140

120

70

60

50

40

30

20

10

0

V

= 5V

V

CHRG

= 5V

CC

BAT = 3.8V

I

= 5mA

100

80

60

40

20

–0.5

–1.0

0

25

TEMPERATURE (°C)

65

85

4.3

4.5

4.7

4.9

(V)

5.1

5.3

5.5

–55 –35 –15

5

45

4

6

0

1

2

3

5

V

CHRG (V)

CC

3559 G15

3559 G13

3559 G14

Buck Regulator Input Current vs

Temperature, Burst Mode Operation

Complete Charge Cycle

2400mAh Battery (LTC3559)

Timer Accuracy vs Temperature

50

45

7

6

1000

800

600

400

200

0

V

CC

= 5V

V

FB

= 0.82V

V

= 5V

PROG

CC

R

= 0.845k

HPWR = 5V

5

40

4

5.0

4.5

4.0

3.5

3.0

5.0

4.0

3.0

2.0

1.0

0

PV = 4.2V

IN

3

35

30

2

PV = 2.7V

IN

1

0

25

20

–1

–2

–55 –35 –15

5

25 45 65 85 105 125

–55 –35 –15

5

85

0

1

2

3

4

5

6

25

45

65

TEMPERATURE (°C)

TIME (HOUR)

3559 G17

3559 G18

3559 G16

Buck Regulator Input Current vs

Temperature, Pulse Skip Mode

(LTC3559)

Buck Regulator PV_INUndervoltage

Thresholds vs Temperature

Frequency vs Temperature

2.5

2.4

2.3

2.2

2.1

2.0

1.9

1.8

1.7

1.6

1.5

2.85

2.75

400

350

PV = 3.8V

IN

V

FB

= 0.82V

2.65

300

PV = 4.2V

IN

RISING

2.55

2.45

250

200

PV = 2.7V

IN

FALLING

2.35

2.25

150

100

–55

45

TEMPERATURE (°C)

85 105

125

–35 –15

5

25

65

–55 –35 –15

5

25 45 65 85 105 125

–55 –35 –15

5

25 45 65 85 105 125

TEMPERATURE (°C)

3559 G21

3559 G20

3559 G19

3559fb

6

LTC3559/LTC3559-1

TYPICAL PERFORMANCE CHARACTERISTICS

Buck Regulator PMOS R_DS(0N)

vs Temperature (LTC3559)

Buck Regulator NMOS R_DS(0N)

vs Temperature (LTC3559)

1300

Buck Regulator Enable

Thresholds vs Temperature

1300

1200

1100

1000

900

1200

1100

1000

900

PV = 3.8V

IN

1200

1100

1000

PV = 2.7V

IN

900

800

700

600

500

PV = 2.7V

IN

800

RISING

PV = 4.2V

IN

PV = 4.2V

IN

700

FALLING

600

500

400

25 45

TEMPERATURE (°C)

–55 –35 –15

5

25 45

125

–55 –35 –15

5

25 45

125

4.2

–55 –35 –15

5

65 85 105 125

65 85 105

TEMPERATURE (°C)

3559 G22

3559 G23

3559 G24

Buck Regulator Efﬁciency vs I_LOAD

(LTC3559)

Buck Regulator Load Regulation

Buck Regulator Line Regulation

100

90

80

70

60

50

40

30

20

10

0

2.60

2.58

2.56

2.54

2.52

2.50

2.48

2.46

2.44

2.60

2.58

2.56

2.54

V

I

= 2.5V

OUT

LOAD

PV = 3.8V

IN

Burst Mode

OPERATION

= 200mA

V

= 2.5V

OUT

PULSE SKIP

MODE

Burst Mode

OPERATION

2.52

2.50

PULSE SKIP

MODE

2.48

2.46

2.44

V

= 2.5V

OUT

IN

PV = 4.2V

3.0

3.3

PV (V)

3.9

2.7

1

10

100

1000

3.6

0.1

1

10

(mA)

100

1000

I

(mA)

LOAD

IN

LOAD

3559 G26

3559 G25

3559 G27

Buck Regulator Efﬁciency vs I_LOAD

(LTC3559)

Buck Regulator Load Regulation

Buck Regulator Line Regulation

100

90

80

70

60

50

40

30

20

10

0

1.25

1.24

1.23

1.22

1.21

1.20

1.19

1.18

1.17

1.16

1.15

1.25

1.24

1.23

1.22

PV = 3.8V

IN

V

I

= 1.2V

= 200mA

OUT

LOAD

Burst Mode

OPERATION

V

= 1.2V

OUT

Burst Mode

OPERATION

1.21

1.20

PULSE SKIP

MODE

PULSE SKIP

MODE

1.19

1.18

1.17

1.16

1.15

V

OUT

= 1.2V

PV = 2.7V

IN

PV = 4.2V

IN

0.1

1

10

(mA)

100

1000

2.7

3.0

3.3

3.6

3.9

1

10

100

1000

I

PV (V)

IN

LOAD

I

(mA)

LOAD

3559 G28

3559 G29

3559 G30

3559fb

7

LTC3559/LTC3559-1

TYPICAL PERFORMANCE CHARACTERISTICS

Buck Regulator Pulse Skip Mode

Operation

Buck Regulator Start-Up Transient

V

OUT

500mV/DIV

20mV/DIV (AC)

INDUCTOR

CURRENT

I = 200mA/DIV

L

SW

2V/DIV

INDUCTOR

CURRENT

I = 50mA/DIV

L

EN

2V/DIV

3559 G33

3559 G34

PV = 3.8V

IN

50μs/DIV

PULSE SKIP MODE

LOAD = 6Ω

PV = 3.8V

IN

LOAD = 10mA

200ns/DIV

Buck Regulator Burst Mode

Operation

Buck Regulator Transient

Response, Pulse Skip Mode

INDUCTOR

CURRENT

I = 200mA/DIV

L

V

OUT

20mV/DIV (AC)

SW

2V/DIV

V

OUT

50mV/DIV (AC)

INDUCTOR

CURRENT

I = 60mA/DIV

L

LOAD STEP

5mA TO 290mA

3559 G35

3559 G36

PV = 3.8V

IN

LOAD = 60mA

2μs/DIV

PV = 3.8V

IN

50μs/DIV

Buck Regulator Transient

Response, Burst Mode Operation

INDUCTOR

CURRENT

I = 200mA/DIV

L

V

OUT

50mV/DIV (AC)

LOAD STEP

5mA TO 290mA

3559 G37

PV = 3.8V

IN

50μs/DIV

3559fb

8

LTC3559/LTC3559-1

PIN FUNCTIONS

GND (Pin 1): Ground, Connect to Exposed Pad (Pin 17).

can toggle between low power and high power modes per

USB speciﬁcation. A weak pull-down current is internally

applied to this pin to ensure it is low at power up when

the input is not being driven externally.

BAT (Pin 2): Charge Current Output. Provides charge cur-

rent to the battery and regulates ﬁnal ﬂoat voltage to 4.2V

(LTC3559) or 4.1V (LTC3559-1).

NTC (Pin 13): Input to the NTC Thermistor Monitoring

Circuit. The NTC pin connects to a negative temperature

coefﬁcient thermistor which is typically co-packaged with

the battery pack to determine if the battery is too hot or

too cold to charge. If the battery temperature is out of

range, charging is paused until the battery temperature

re-enters the valid range. A low drift bias resistor is re-

MODE (Pin 3): MODE Pin for Buck Regulators. When held

high, both regulators are in Burst Mode operation. When

held low both regulators operate in pulse skip mode. This

pin is a high impedance input; do not ﬂoat.

FB1 (Pin 4): Buck 1 Feedback Voltage Pin. Receives feed-

back by a resistor divider connected across the output.

quired from V to NTC and a thermistor is required from

CC

EN1 (Pin 5): Enable Input Pin for Buck 1. This pin is a high

impedance input; do not ﬂoat. Active high.

NTC to ground. To disable the NTC function, the NTC pin

should be grounded.

SW1 (Pin 6): Buck 1 Switching Node. External inductor

connects to this node.

PROG (Pin 14): Charge Current Program and Charge

Current Monitor Pin. Charge current is programmed by

connecting a resistor from PROG to ground. When charg-

ing in constant-current mode, the PROG pin servos to 1V

if the HPWR pin is pulled high, or 200mV if the HPWR pin

is pulled low. The voltage on this pin always represents

the battery current through the following formula:

PV (Pin 7): Input Supply Pin for Buck Regulators.

IN

Connect to BAT. A 2.2μF decoupling capacitor to GND is

recommended.

SW2 (Pin 8): Buck 2 Switching Node. External inductor

connects to this node.

PROG

R_PROG

EN2 (Pin 9): Enable Input Pin for Buck 2. This pin is a high

impedance input; do not ﬂoat. Active high.

I_BAT

=

•800

FB2(Pin10):Buck2FeedbackVoltagePin.Receivesfeed-

CHRG (Pin 15): Open-Drain Charge Status Output. The

CHRG pin indicates the status of the battery charger. Four

possible states are represented by CHRG: charging, not

charging (i.e., the charge current is less than 1/10th of the

full-scale charge current), unresponsive battery (i.e., the

batteryvoltageremainsbelow2.9Vafter1/2hourofcharg-

ing) and battery temperature out of range. CHRG requires

a pull-up resistor and/or LED to provide indication.

back by a resistor divider connected across the output.

SUSP (Pin 11): Suspend Battery Charging Operation.

A voltage greater than 1.2V on this pin puts the battery

charger into suspend mode, disables the charger and

resets the termination timer. A weak pull-down current is

internally applied to this pin to ensure it is low at power

up when the input is not being driven externally.

HPWR (Pin 12): High Current Battery Charging Enabled.

A voltage greater than 1.2V at this pin programs the

BAT pin current at 100% of the maximum programmed

charge current. A voltage less than 0.4V sets the BAT pin

current to 20% of the maximum programmed charge

current. When used with a 1.74k PROG resistor, this pin

V

(Pin 16): Battery Charger Input. A 1μF decoupling

CC

capacitor to GND is recommended.

Exposed Pad (Pin 17): Ground. The Exposed Pad must

be soldered to PCB ground to provide electrical contact

and rated thermal performance.

3559fb

9

LTC3559/LTC3559-1

BLOCK DIAGRAM

16

V

CC

V

BAT

BODY

IN

1x

800x

MAXER

BAT

2

–

+

CHRG

15

HPWR

12

CA

TA

LOGIC

SUSP

11

T

DIE

PROG

14

NTCA

NTC

13

NTC REF

BATTERY CHARGER

PV

IN

7

MODE

3

EN1

5

UNDERVOLTAGE

LOCKOUT

EN2

EN MODE

9

4

CLK

V

–

+

FB1

FB

SW1

CONTROL

LOGIC

6

V

C

G

OT

m

DIE

0.8V

T

TEMPERATURE

DIE

BUCK REGULATOR 1

V

REF

BANDGAP

OSCILLATOR

2.25MHz

CLK

EN MODE

CLK

V

–

+

FB2

FB

SW2

CONTROL

LOGIC

10

8

V

C

G

m

0.8V

BUCK REGULATOR 2

GND

1

EXPOSED PAD

17

3559 BD

3559fb

10

LTC3559/LTC3559-1

OPERATION

at the BAT pin via a single PROG resistor. The actual BAT

pin current is set by the status of the HPWR pin.

The LTC3559/LTC3559-1 are linear battery chargers with

dual monolithic synchronous buck regulators. The buck

regulatorsareinternallycompensatedandneednoexternal

compensation components.

For proper operation, the BAT and PV pins must be tied

IN

together. If a buck regulator is also enabled during the

battery charging operation, the net current charging the

battery may be lower than the actual programmed value.

Refer to Figure 1 for an explanation.

Thebatterychargeremploysaconstant-current/constant-

voltage charging algorithm and is capable of charging a

singleLi-Ionbatteryatchargingcurrentsupto950mA.The

usercanprogramthemaximumchargingcurrentavailable

500mA 300mA

USB (5V)

V

BAT

CC

SINGLE Li-lon

CELL 3.6V

+

PV

IN

200mA

PROG

SUSP

+

R

LTC3559/

LTC3559-1

PROG

2.2μF

1.62k

HIGH

V

HPWR

EN1

SW1

SW2

OUT1

HIGH

V

OUT2

EN2

LOW (PULSE SKIP MODE)

MODE

3559 F01

Figure 1. Current Being Delivered at the BAT Pin Is 500mA. Both Buck Regulators Are Enabled. The Sum of the

Average Input Currents Drawn by Both Buck Regulators Is 200mA. This Makes the Effective Battery Charging Current

Only 300mA. If the HPWR Pin Were Tied LO, the BAT Pin Current Would Be 100mA. With the Buck Regulator

Conditions Unchanged, This Would Cause the Battery to Discharge at 100mA

APPLICATIONS INFORMATION

Battery Charger Introduction

Input Current vs Charge Current

The LTC3559/LTC3559-1 have a linear battery charger

designed to charge single-cell lithium-ion batteries. The

charger uses a constant-current/constant-voltage charge

algorithm with a charge current programmable up to

950mA. Additional features include automatic recharge,

an internal termination timer, low-battery trickle charge

conditioning, bad-battery detection, and a thermistor

sensor input for out of temperature charge pausing.

The battery charger regulates the total current delivered

to the BAT pin; this is the charge current. To calculate the

total input current (i.e., the total current drawn from the

V

pin), it is necessary to sum the battery charge current,

CC

charger quiescent current and PROG pin current.

Undervoltage Lockout (UVLO)

The undervoltage lockout circuit monitors the input volt-

age (V ) and disables the battery charger until V rises

Furthermore, the battery charger is capable of operating

from a USB power source. In this application, charge

current can be programmed to a maximum of 100mA or

500mA per USB power speciﬁcations.

CC

above V

(typically 4V). 200mV of hysteresis prevents

UVLO

oscillations around the trip point. In addition, a differential

undervoltage lockout circuit disables the battery charger

when V falls to within V

(typically 50mV) of the

CC

DUVLO

BAT voltage.

3559fb

11

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

Suspend Mode

mode, the 4-hour timer is started. After the safety timer

expires, charging of the battery will discontinue and no

more current will be delivered.

The battery charger can also be disabled by pulling the

SUSP pin above 1.2V. In suspend mode, the battery

drain current is reduced to 1.5μA and the input current is

reduced to 8.5μA.

Automatic Recharge

After the battery charger terminates, it will remain off,

drawing only microamperes of current from the battery.

If the portable product remains in this state long enough,

thebatterywilleventuallyselfdischarge.Toensurethatthe

battery is always topped off, a charge cycle will automati-

Charge Cycle Overview

When a battery charge cycle begins, the battery charger

ﬁrst determines if the battery is deeply discharged. If the

batteryvoltageisbelowV

,typically2.9V,anautomatic

callybeginwhenthebatteryvoltagefallsbelowV

.In

RECHRG

TRKL

trickle charge feature sets the battery charge current to

10% of the full-scale value.

the event that the safety timer is running when the battery

voltage falls below V , it will reset back to zero. To

RECHRG

preventbriefexcursionsbelowV

fromresettingthe

RECHRG

Once the battery voltage is above 2.9V, the battery charger

begins charging in constant-current mode. When the

battery voltage approaches the 4.2V (LTC3559) or 4.1V

(LTC3559-1) required to maintain a full charge, otherwise

known as the ﬂoat voltage, the charge current begins to

decrease as the battery charger switches into constant-

voltage mode.

safety timer, the battery voltage must be below V

RECHRG

for more than 1.7ms. The charge cycle and safety timer

will also restart if the V UVLO or DUVLO cycles low and

CC

then high (e.g., V is removed and then replaced) or the

CC

charger enters and then exits suspend mode.

Programming Charge Current

Trickle Charge and Defective Battery Detection

The PROG pin serves both as a charge current program

pin, and as a charge current monitor pin. By design, the

PROG pin current is 1/800th of the battery charge current.

Therefore, connecting a resistor from PROG to ground

programsthechargecurrentwhilemeasuringthePROGpin

voltage allows the user to calculate the charge current.

Any time the battery voltage is below V , the charger

TRKL

goes into trickle charge mode and reduces the charge

current to 10% of the full-scale current. If the battery

voltage remains below V

for more than 1/2 hour, the

TRKL

chargerlatchesthebad-batterystate, automaticallytermi-

nates, and indicates via the CHRG pin that the battery was

unresponsive. If for any reason the battery voltage rises

Full-scale charge current is deﬁned as 100% of the con-

stant-current mode charge current programmed by the

PROG resistor. In constant-current mode, the PROG pin

servosto1VifHPWRishigh,whichcorrespondstocharg-

ing at the full-scale charge current, or 200mV if HPWR

is low, which corresponds to charging at 20% of the full-

scale charge current. Thus, the full-scale charge current

and desired program resistor for a given full-scale charge

current are calculated using the following equations:

above V , the charger will resume charging. Since the

TRKL

charger has latched the bad-battery state, if the battery

voltagethenfallsbelowV againbutwithoutrisingpast

TRKL

V

ﬁrst, the charger will immediately assume that

RECHRG

the battery is defective. To reset the charger (i.e., when

the dead battery is replaced with a new battery), simply

remove the input voltage and reapply it or put the part in

and out of suspend mode.

800V

R_PROG

I_CHG

=

Charge Termination

The battery charger has a built-in safety timer that sets the

totalchargetimefor4hours.Oncethebatteryvoltagerises

800V

I_CHG

R_PROG

=

above V

and the charger enters constant-voltage

RECHRG

3559fb

12

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

In any mode, the actual battery current can be determined

by monitoring the PROG pin voltage and using the follow-

ing equation:

charge current has dropped to below 10% of the full-scale

current, the CHRG pin is released (high impedance). If a

fault occurs after the CHRG pin is released, the pin re-

mains high impedance. However, if a fault occurs before

the CHRG pin is released, the pin is switched at 35kHz.

Whileswitching,itsdutycycleismodulatedbetweenahigh

and low value at a very low frequency. The low and high

duty cycles are disparate enough to make an LED appear

to be on or off thus giving the appearance of “blinking”.

Each of the two faults has its own unique “blink” rate for

human recognition as well as two unique duty cycles for

microprocessor recognition.

PROG

R_PROG

I_BAT

=

•800

Thermal Regulation

To prevent thermal damage to the IC or surrounding

components, an internal thermal feedback loop will auto-

matically decrease the programmed charge current if the

die temperature rises to approximately 115°C. Thermal

regulation protects the battery charger from excessive

temperature due to high power operation or high ambient

thermal conditions and allows the user to push the limits

of the power handling capability with a given circuit board

design without risk of damaging the LTC3559/LTC3559-1

or external components. The beneﬁt of the LTC3559/

LTC3559-1 battery charger thermal regulation loop is that

charge current can be set according to actual conditions

rather than worst-case conditions with the assurance that

the battery charger will automatically reduce the current

in worst-case conditions.

Table 1 illustrates the four possible states of the CHRG

pin when the battery charger is active.

Table 1. CHRG Output Pin

MODULATION

(BLINK)

STATUS

FREQUENCY

0Hz

FREQUENCY

DUTY CYCLE

100%

Charging

0 Hz (Lo-Z)

I

< C/10

0Hz

0 Hz (Hi-Z)

0%

BAT

35kHz

1.5Hz at 50%

6.1Hz at 50%

6.25% to 93.75%

12.5% to 87.5%

NTC Fault

Bad Battery

An NTC fault is represented by a 35kHz pulse train whose

duty cycle varies between 6.25% and 93.75% at a 1.5Hz

rate. A human will easily recognize the 1.5Hz rate as a

“slow” blinking which indicates the out of range battery

temperaturewhileamicroprocessorwillbeabletodecode

either the 6.25% or 93.75% duty cycles as an NTC fault.

Charge Status Indication

The CHRG pin indicates the status of the battery charger.

Four possible states are represented by CHRG: charging,

notcharging,unresponsivebatteryandbatterytemperature

out of range.

If a battery is found to be unresponsive to charging (i.e.,

ThesignalattheCHRGpincanbeeasilyrecognizedasone

of the above four states by either a human or a micropro-

cessor. The CHRG pin, which is an open-drain output, can

drive an indicator LED through a current limiting resistor

for human interfacing, or simply a pull-up resistor for

microprocessor interfacing.

its voltage remains below V

for over 1/2 hour), the

TRKL

CHRG pin gives the battery fault indication. For this fault,

a human would easily recognize the frantic 6.1Hz “fast”

blinking of the LED while a microprocessor would be able

to decode either the 12.5% or 87.5% duty cycles as a bad

battery fault.

To make the CHRG pin easily recognized by both humans

and microprocessors, the pin is either low for charging,

high for not charging, or it is switched at high frequency

(35kHz) to indicate the two possible faults: unresponsive

battery and battery temperature out of range.

Although very improbable, it is possible that a duty cycle

reading could be taken at the bright-dim transition (low

duty cycle to high duty cycle). When this happens the

duty cycle reading will be precisely 50%. If the duty cycle

reading is 50%, system software should disqualify it and

take a new duty cycle reading.

When charging begins, CHRG is pulled low and remains

low for the duration of a normal charge cycle. When the

3559fb

13

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

NTC Thermistor

value of R25 or approximately 54k (for a Vishay “Curve

1” thermistor, this corresponds to approximately 40°C). If

thebatterychargerisinconstant-voltagemode, thesafety

timer will pause until the thermistor indicates a return to

a valid temperature.

The battery temperature is measured by placing a nega-

tive temperature coefﬁcient (NTC) thermistor close to the

battery pack. The NTC circuitry is shown in Figure 3.

To use this feature, connect the NTC thermistor, R

,

NTC

NOM

As the temperature drops, the resistance of the NTC

thermistor rises. The battery charger is also designed

to pause charging when the value of the NTC thermistor

increases to 3.25 times the value of R25. For a Vishay

“Curve 1” thermistor, this resistance, 325k, corresponds

to approximately 0°C. The hot and cold comparators each

haveapproximately3°Cofhysteresistopreventoscillation

about the trip point. Grounding the NTC pin disables all

NTC functionality.

betweentheNTCpinandground,andabiasresistor,R

from V to NTC. R

should be a 1% resistor with a

CC

NOM

value equal to the value of the chosen NTC thermistor at

25°C (R25). A 100k thermistor is recommended since

thermistor current is not measured by the battery charger

and its current will have to be considered for compliance

with USB speciﬁcations.

The battery charger will pause charging when the re-

sistance of the NTC thermistor drops to 0.54 times the

DUVLO, UVLO AND SUSPEND

IF SUSP < 0.4V AND

DISABLE MODE

NO

POWER

CHRG HIGH IMPEDANCE

ON

V

CC

V

CC

> 4V AND

> BAT + 130mV

YES

FAULT

NTC FAULT

STANDBY MODE

BATTERY CHARGING SUSPENDED

NO CHARGE CURRENT

CHRG PULSES

CHRG HIGH IMPEDANCE

NO FAULT

BAT b 2.9V

2.9V < BAT < V

RECHRG

BAT > 2.9V

TRICKLE CHARGE MODE

CONSTANT CURRENT MODE

4-HOUR

TIMEOUT

1/10 FULL CHARGE CURRENT

CHRG STRONG PULL-DOWN

30 MINUTE TIMER BEGINS

FULL CHARGE CURRENT

CHRG STRONG PULL-DOWN

30 MINUTE

TIMEOUT

DEFECTIVE BATTERY

CONSTANT VOLTAGE MODE

NO CHARGE CURRENT

CHRG PULSES

4-HOUR TERMINATION TIMER

BEGINS

BAT DROPS BELOW V

RECHRG

4-HOUR TERMINATION TIMER RESETS

3559 F02

Figure 2. State Diagram of the Battery Charger Operation

3559fb

14

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

Alternate NTC Thermistors and Biasing

In the explanation below, the following notation is used.

R25 = Value of the thermistor at 25°C

The battery charger provides temperature qualiﬁed

charging if a grounded thermistor and a bias resistor are

connected to the NTC pin. By using a bias resistor whose

value is equal to the room temperature resistance of the

thermistor (R25) the upper and lower temperatures are

pre-programmed to approximately 40°C and 0°C, respec-

tively (assuming a Vishay “Curve 1” thermistor).

R

= Value of thermistor at the cold trip point

NTC|COLD

= Value of the thermistor at the hot trip point

NTC|HOT

r

= Ratio of R

to R25

COLD

NTC|COLD

= Ratio of R

to R25

HOT

NTC|HOT

R

= Primary thermistor bias resistor (see Figure 3)

NOM

The upper and lower temperature thresholds can be ad-

justed by either a modiﬁcation of the bias resistor value

or by adding a second adjustment resistor to the circuit.

If only the bias resistor is adjusted, then either the upper

or the lower threshold can be modiﬁed but not both. The

other trip point will be determined by the characteristics

of the thermistor. Using the bias resistor in addition to an

adjustmentresistor,boththeupperandthelowertempera-

ture trip points can be independently programmed with

the constraint that the difference between the upper and

lower temperature thresholds cannot decrease. Examples

of each technique are given below.

R1 = Optional temperature range adjustment resistor (see

Figure 4)

The trip points for the battery charger’s temperature quali-

ﬁcation are internally programmed at 0.349 • V for the

CC

hot threshold and 0.765 • V for the cold threshold.

CC

Therefore, the hot trip point is set when:

R_NTC|HOT

• V_CC= 0.349 • V_CC

R_NOM+R_NTC|HOT

and the cold trip point is set when:

NTC thermistors have temperature characteristics which

areindicatedonresistance-temperatureconversiontables.

TheVishay-DalethermistorNTHS0603N011-N1003F,used

in the following examples, has a nominal value of 100k

and follows the Vishay “Curve 1” resistance-temperature

characteristic.

R_NTC|COLD

• V_CC= 0.765 • V_CC

R_NOM+R_NTC|COLD

V

CC

NTC BLOCK

V

CC

16

0.765 • V

CC

0.765 • V

CC

(NTC RISING)

–

+

R

–

+

R

NOM

105k

100k

TOO_COLD

TOO_HOT

TOO_COLD

TOO_HOT

NTC

13

R1

12.7k

R

100k

NTC

–

+

–

+

R

100k

NTC

0.349 • V

CC

(NTC FALLING)

CC

(NTC FALLING)

+

–

+

–

NTC_ENABLE

0.017 • V

CC

(NTC FALLING)

0.017 • V

CC

(NTC FALLING)

3559 F03

3559 F04

Figure 3. Typical NTC Thermistor Circuit

Figure 4. NTC Thermistor Circuit with Additional Bias Resistor

3559fb

15

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

Solving these equations for R

and R

NTC|COLD

NTC|HOT

For example, to set the trip points to 0°C and 45°C with

a Vishay Curve 1 thermistor choose:

results in the following:

R

= 0.536 • R

NTC|HOT

NOM

3.266 – 0.4368

R_NOM

=

•100k = 104.2k

and

2.714

R

= 3.25 • R

NTC|COLD

NOM

the nearest 1% value is 105k.

By setting R

equal to R25, the above equations result

NOM

= 0.536 and r

R1 = 0.536 • 105k – 0.4368 • 100k = 12.6k

in r

= 3.25. Referencing these ratios

HOT

COLD

the nearest 1% value is 12.7k. The ﬁnal solution is shown

in Figure 4 and results in an upper trip point of 45°C and

a lower trip point of 0°C.

to the Vishay Resistance-Temperature Curve 1 chart gives

a hot trip point of about 40°C and a cold trip point of about

0°C. The difference between the hot and cold trip points

is approximately 40°C.

USB and Wall Adapter Power

By using a bias resistor, R

, different in value from

NOM

Although the battery charger is designed to draw power

from a USB port to charge Li-Ion batteries, a wall adapter

can also be used. Figure 5 shows an example of how to

combine wall adapter and USB power inputs. A P-channel

MOSFET, MP1, is used to prevent back conduction into

the USB port when a wall adapter is present and Schottky

diode, D1, is used to prevent USB power loss through the

1k pull-down resistor.

R25, the hot and cold trip points can be moved in either

direction.Thetemperaturespanwillchangesomewhatdue

to the nonlinear behavior of the thermistor. The following

equations can be used to easily calculate a new value for

the bias resistor:

r_HOT

R_NOM

=

•R25

0.536

Typically, a wall adapter can supply signiﬁcantly more

current than the 500mA-limited USB port. Therefore, an

N-channelMOSFET,MN1,andanextraprogramresistorare

used to increase the maximum charge current to 950mA

when the wall adapter is present.

r_COLD

3.25

=

where r

and r

are the resistance ratios at the de-

HOT

COLD

sired hot and cold trip points. Note that these equations

are linked. Therefore, only one of the two trip points can

be chosen, the other is determined by the default ratios

designed in the IC. Consider an example where a 60°C

hot trip point is desired.

5V WALL

I

BAT

ADAPTER

BAT

BATTERY

CHARGER

V

CC

950mA I

CHG

D1

USB

POWER

MP1

500mA I

+

CHG

Li-Ion

BATTERY

FromtheVishayCurve1R-Tcharacteristics,r is0.2488

at 60°C. Using the above equation, R

to 46.4k. With this value of R

about 16°C. Notice that the span is now 44°C rather than

the previous 40°C.

HOT

PROG

should be set

NOM

1.65k

, the cold trip point is

MN1

NOM

1.74k

1k

3559 F05

The upper and lower temperature trip points can be inde-

pendentlyprogrammedbyusinganadditionalbiasresistor

as shown in Figure 4. The following formulas can be used

Figure 5. Combining Wall Adapter and USB Power

to compute the values of R

and R1:

NOM

r

_COLD–r_HOT

R_NOM

=

•R25

2.714

R1= 0.536 •R_NOM–r_HOT•R25

3559fb

16

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

Power Dissipation

Furthermore, the voltage at the PROG pin will change

proportionally with the charge current as discussed in

the Programming Charge Current section.

The conditions that cause the LTC3559/LTC3559-1 to

reduce charge current through thermal feedback can be

approximated by considering the power dissipated in the

IC. For high charge currents, the LTC3559/LTC3559-1

power dissipation is approximately:

It is important to remember that LTC3559/LTC3559-1

applications do not need to be designed for worst-case

thermal conditions since the IC will automatically reduce

powerdissipationwhenthejunctiontemperaturereaches

approximately 105°C.

P = V – V

•I

BAT

(

)

D

CC

BAT

where P is the power dissipated, V is the input supply

D

CC

Battery Charger Stability Considerations

voltage, V is the battery voltage, and I is the charge

BAT

The LTC3559/LTC3559-1 battery charger contains two

control loops: the constant-voltage and constant-cur-

rent loops. The constant-voltage loop is stable without

any compensation when a battery is connected with low

impedanceleads.Excessiveleadlength,however,mayadd

enough series inductance to require a bypass capacitor

of at least 1.5μF from BAT to GND. Furthermore, a 4.7μF

capacitor with a 0.2Ω to 1Ω series resistor from BAT to

GND is required to keep ripple voltage low when the bat-

tery is disconnected.

current.Itisnotnecessarytoperformanyworst-casepower

dissipation scenarios because the LTC3559/LTC3559-1

will automatically reduce the charge current to maintain

the die temperature at approximately 105°C. However, the

approximate ambient temperature at which the thermal

feedback begins to protect the IC is:

T_A=105°C–P_Dθ_JA

T =105°C– V – V

•I_BAT•θ_JA

(

)

A

CC

BAT

Example:ConsideranLTC3559/LTC3559-1operatingfrom

a USB port providing 500mA to a 3.5V Li-Ion battery.

The ambient temperature above which the LTC3559/

LTC3559-1 will begin to reduce the 500mA charge cur-

rent is approximately:

High value capacitors with very low ESR (especially

ceramic) reduce the constant-voltage loop phase margin,

possibly resulting in instability. Ceramic capacitors up to

22μF may be used in parallel with a battery, but larger

ceramics should be decoupled with 0.2Ω to 1Ω of series

resistance.

T =105°C– 5V –3.5V • 500mA •68°C / W

(

) (

)

A

T_A=105°C–0.75W •68°C / W =105°C–51°

T_A= 54°C

Inconstant-currentmode,thePROGpinisinthefeedback

loop,notthebattery.Becauseoftheadditionalpolecreated

bythePROGpincapacitance,capacitanceonthispinmust

be kept to a minimum. With no additional capacitance on

the PROG pin, the charger is stable with program resistor

values as high as 25K. However, additional capacitance

on this node reduces the maximum allowed program

resistor. The pole frequency at the PROG pin should be

kept above 100kHz. Therefore, if the PROG pin is loaded

The LTC3559/LTC3559-1 can be used above 70°C, but

the charge current will be reduced from 500mA. The

approximate current at a given ambient temperature can

be calculated:

105°C– T_A

I_BAT

=

V – V

•θ

(

)

CC

BAT

JA

with a capacitance, C

, the following equation should

PROG

be used to calculate the maximum resistance value for

Using the previous example with an ambient tem-

perature of 88°C, the charge current will be reduced to

approximately:

R

PROG

:

1

R_PROG

≤

2π •10⁵•C_PROG

105°C–88°C

17°C

I_BAT

=

5V –3.5V •68°C / W 102°C / A

(

)

I_BAT=167mA

3559fb

17

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

the current from building up in the cable too fast thus

dampening out any resonant overshoot.

Average,ratherthaninstantaneous,batterycurrentmaybe

of interest to the user. For example, if a switching power

supply operating in low-current mode is connected in

parallel with the battery, the average current being pulled

out of the BAT pin is typically of more interest than the

instantaneous current pulses. In such a case, a simple RC

ﬁlter can be used on the PROG pin to measure the average

battery current as shown in Figure 6. A 10k resistor has

been added between the PROG pin and the ﬁlter capacitor

to ensure stability.

Buck Switching Regulator General Information

The LTC3559/LTC3559-1 contain two 2.25MHz constant-

frequencycurrentmodeswitchingregulatorsthatprovide

up to 400mA each. Both switchers can be programmed

for a minimum output voltage of 0.8V and can be used

to power a microcontroller core, microcontroller I/O,

memory or other logic circuitry. Both regulators support

100% duty cycle operation (dropout mode) when the

input voltage drops very close to the output voltage and

are also capable of operating in Burst Mode operation for

highest efﬁciencies at light loads (Burst Mode operation

is pin selectable). The switching regulators also include

soft-start to limit inrush current when powering on, short

circuit current protection, and switch node slew limiting

circuitry to reduce radiated EMI.

LTC3559/

LTC3559-1

CHARGE

10k

CURRENT

MONITOR

CIRCUITRY

PROG

GND

R

C

FILTER

PROG

3559 F06

Figure 6. Isolated Capacitive Load on PROG Pin and Filtering

A single MODE pin sets both regulators in Burst Mode

operationorpulseskipoperatingmodewhileeachregula-

tor is enabled individually through their respective enable

USB Inrush Limiting

When a USB cable is plugged into a portable product,

the inductance of the cable and the high-Q ceramic input

capacitor form an L-C resonant circuit. If there is not

much impedance in the cable, it is possible for the voltage

at the input of the product to reach as high as twice the

USB voltage (~10V) before it settles out. In fact, due to

the high voltage coefﬁcient of many ceramic capacitors

(a nonlinearity), the voltage may even exceed twice the

USBvoltage. Topreventexcessivevoltagefromdamaging

the LTC3559/LTC3559-1 during a hot insertion, the soft

connect circuit in Figure 7 can be employed.

pinsEN1andEN2.Thebuckregulatorsinputsupply(PV )

IN

should be connected to the battery pin (BAT). This allows

the undervoltage lockout circuit on the BAT pin to disable

the buck regulators when the BAT voltage drops below

2.45V. Do not drive the buck switching regulators from

a voltage other than BAT. A 2.2μF decoupling capacitor

from the PV pin to GND is recommended.

IN

Buck Switching Regulator

Output Voltage Programming

In the circuit of Figure 7, capacitor C1 holds MP1 off when

thecableisﬁrstconnected.EventuallyC1beginstocharge

up to the USB voltage applying increasing gate support

to MP1. The long time constant of R1 and C1 prevents

Both switching regulators can be programmed for output

voltages greater than 0.8V. The output voltage for each

buck switching regulator is programmed using a resistor

divider from the switching regulator output connected to

the feedback pins (FB1 and FB2) such that:

MP1

Si2333

V

OUT

= 0.8(1 + R1/R2)

CC

C1

100nF

5V USB

INPUT

Typical values for R1 are in the range of 40k to 1M. The

capacitor C_FBcancels the pole created by feedback re-

sistors and the input capacitance of the FB pin and also

helps to improve transient response for output voltages

much greater than 0.8V. A variety of capacitor sizes can

LTC3559/

LTC3559-1

C2

10μF

USB CABLE

R1

40k

GND

3559 F07

Figure 7. USB Soft Connect Circuit

be used for C_FBbut a value of 10pF is recommended for

3559fb

18

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

most applications. Experimentation with capacitor sizes

between 2pF and 22pF may yield improved transient

response if so desired by the user.

regulators will automatically skip pulses as needed to

maintain output regulation. At high duty cycle (V

>

OUT

PV /2) in pulse skip mode, it is possible for the inductor

IN

current to reverse causing the buck converter to switch

continuously. Regulation and low noise operation are

maintained but the input supply current will increase to a

couple mA due to the continuous gate switching.

Buck Switching Regulator Operating Modes

The step-down switching regulators include two possible

operating modes to meet the noise/power needs of a

variety of applications.

During Burst Mode operation, the step-down switching

regulators automatically switch between ﬁxed frequency

PWM operation and hysteretic control as a function of

the load current. At light loads the step-down switching

regulators control the inductor current directly and use a

hystereticcontrollooptominimizebothnoiseandswitching

losses. DuringBurstModeoperation, theoutputcapacitor

is charged to a voltage slightly higher than the regulation

point. The step-down switching regulator then goes into

sleep mode, during which the output capacitor provides

the load current. In sleep mode, most of the switching

regulator’s circuitry is powered down, helping conserve

battery power. When the output voltage drops below a

pre-determined value, the step-down switching regulator

circuitryispoweredonandanotherburstcyclebegins.The

sleeptimedecreasesastheloadcurrentincreases.Beyond

a certain load current point (about 1/4 rated output load

current) the step-down switching regulators will switch to

a low noise constant frequency PWM mode of operation,

much the same as pulse skip operation at high loads. For

applications that can tolerate some output ripple at low

output currents, Burst Mode operation provides better

efﬁciency than pulse skip at light loads.

In pulse skip mode, an internal latch is set at the start of

every cycle, which turns on the main P-channel MOSFET

switch.Duringeachcycle,acurrentcomparatorcompares

thepeakinductorcurrenttotheoutputofanerrorampliﬁer.

The output of the current comparator resets the internal

latch,whichcausesthemainP-channelMOSFETswitchto

turn off and the N-channel MOSFET synchronous rectiﬁer

to turn on. The N-channel MOSFET synchronous rectiﬁer

turns off at the end of the 2.25MHz cycle or if the current

through the N-channel MOSFET synchronous rectiﬁer

drops to zero. Using this method of operation, the error

ampliﬁer adjusts the peak inductor current to deliver the

required output power. All necessary compensation is

internal to the step-down switching regulator requiring

only a single ceramic output capacitor for stability. At

light loads in pulse skip mode, the inductor current may

reach zero on each pulse which will turn off the N-channel

MOSFET synchronous rectiﬁer. In this case, the switch

node (SW1 or SW2) goes high impedance and the switch

node voltage will “ring”. This is discontinuous operation,

and is normal behavior for a switching regulator. At very

light loads in pulse skip mode, the step-down switching

Thestep-downswitchingregulatorsallowmodetransition

on-the-ﬂy, providing seamless transition between modes

even under load. This allows the user to switch back and

forth between modes to reduce output ripple or increase

low current efﬁciency as needed. Burst Mode operation is

set by driving the MODE pin high, while pulse skip mode

is achieved by driving the MODE pin low.

P

VIN

EN

MP

SW

PWM

L

V

OUT

CONTROL

+

C

O

C

MODE

FB

MN

R1

R2

FB

0.8V

Buck Switching Regulator in Shutdown

The buck switching regulators are in shutdown when

not enabled for operation. In shutdown, all circuitry in

the buck switching regulator is disconnected from the

regulator input supply, leaving only a few nanoamps of

GND

3559 F08

Figure 8. Buck Converter Application Circuit

3559fb

19

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

leakage pulled to ground through a 10k resistor on the

switch (SW1 or SW2) pin when in shutdown.

Buck Switching Regulator Inductor Selection

The buck regulators are designed to work with inductors

in the range of 2.2μH to 10μH, but for most applications

a 4.7μH inductor is suggested. Larger value inductors

reduceripplecurrentwhichimprovesoutputripplevoltage.

Lowervalueinductorsresultinhigherripplecurrentwhich

improvestransientresponsetime. Tomaximizeefﬁciency,

choose an inductor with a low DC resistance. For a 1.2V

output efﬁciency is reduced about 2% for every 100mΩ

series resistance at 400mA load current, and about 2%

forevery300mΩseriesresistanceat100mAloadcurrent.

Choose an inductor with a DC current rating at least 1.5

timeslargerthanthemaximumloadcurrenttoensurethat

the inductor does not saturate during normal operation.

If output short circuit is a possible condition the induc-

tor should be rated to handle the maximum peak current

speciﬁed for the buck regulators.

Buck Switching Regulator Dropout Operation

It is possible for a step-down switching regulator’s input

voltagetoapproachitsprogrammedoutputvoltage(e.g.,a

battery voltage of 3.4V with a programmed output voltage

of 3.3V). When this happens, the PMOS switch duty cycle

increasesuntilitisturnedoncontinuouslyat100%.Inthis

dropoutcondition,therespectiveoutputvoltageequalsthe

regulator’s input voltage minus the voltage drops across

the internal P-channel MOSFET and the inductor.

Buck Switching Regulator Soft-Start Operation

Soft-start is accomplished by gradually increasing the

peak inductor current for each switching regulator over

a 500μs period. This allows each output to rise slowly,

helping minimize the battery in-rush current required to

charge up the regulator’s output capacitor. A soft-start

cycle occurs whenever a switcher ﬁrst turns on, or after a

faultconditionhasoccurred(thermalshutdownorUVLO).

A soft-start cycle is not triggered by changing operating

modes using the MODE pin. This allows seamless output

operation when transitioning between operating modes.

Differentcorematerialsandshapeswillchangethesize/cur-

rentandprice/currentrelationshipofaninductor.Toroidor

shieldedpotcoresinferriteorpermalloymaterialsaresmall

and don’t radiate much energy, but generally cost more

than powdered iron core inductors with similar electrical

characteristics. Inductors that are very thin or have a very

small volume typically have much higher DCR losses, and

will not give the best efﬁciency. The choice of which style

inductor to use often depends more on the price vs size,

performance, and any radiated EMI requirements than on

what the buck regulator requires to operate.

Buck Switching Regulator

Switching Slew Rate Control

Thebuckswitchingregulatorscontaincircuitrytolimitthe

slewrateoftheswitchnode(SW1andSW2).Thiscircuitry

is designed to transition the switch node over a period of

a couple of nanoseconds, signiﬁcantly reducing radiated

EMI and conducted supply noise while maintaining high

efﬁciency.

The inductor value also has an effect on Burst Mode

operation. Lower inductor values will cause Burst Mode

switching frequency to increase.

Table 2 shows several inductors that work well with the

LTC3559/LTC3559-1.Theseinductorsofferagoodcompro-

miseincurrentrating,DCRandphysicalsize.Consulteach

manufacturer for detailed information on their entire

selection of inductors.

Buck Switching Regulator Low Supply Operation

An undervoltage lockout (UVLO) circuit on PV shuts

IN

downthestep-downswitchingregulatorswhenBATdrops

below2.45V.ThisUVLOpreventsthestep-downswitching

regulatorsfromoperatingatlowsupplyvoltageswhereloss

of regulation or other undesirable operation may occur.

3559fb

20

LTC3559/LTC3559-1

APPLICATIONS INFORMATION

Table 2 Recommended Inductors

INDUCTOR TYPE

L (μH)

MAX I (A)

MANUFACTURER

MAX DCR(Ω)

SIZE IN MM (L × W × H)

DC

DB318C

4.7

3.3

4.7

3.3

4.7

3.3

1.07

1.20

0.79

0.90

1.15

1.37

0.1

0.07

Toko

www.toko.com

3.8 × 3.8 × 1.8

3.6 × 3.6 × 1.2

3.0 × 2.8 × 1.2

D312C

0.24

0.20

0.13*

0.105*

DE2812C

CDRH3D16

CDRH2D11

4.7

3.3

4.7

3.3

4.7

0.9

1.1

0.11

0.085

0.17

Sumida

4 × 4 × 1.8

www.sumida.com

0.5

3.2 × 3.2 × 1.2

4.9 × 4.9 × 1

0.6

0.75

0.123

0.19

CLS4D09

SD3118

4.7

3.3

4.7

3.3

4.7

3.3

4.7

3.3

1.3

1.59

0.8

0.97

1.29

1.42

1.08

1.31

0.162

0.113

Cooper

www.cooperet.com

3.1 × 3.1 × 1.8

3.1 × 3.1 × 1.2

5.2 × 5.2 × 1.2

5.2 × 5.2 × 1.0

SD3112

SD12

0.246

0.165

0.117*

0.104*

0.153*

0.108*

SD10

LPS3015

4.7

3.3

1.1

1.3

0.2

0.13

Coilcraft

www.coilcraft.com

3.0 × 3.0 × 1.5

*Typical DCR

Buck Switching Regulator

Table 3: Recommended Ceramic Capacitor Manufacturers

Input/Output Capacitor Selection

AVX

Murata

(803) 448-9411

(714) 852-2001

(408) 537-4150

(888) 835-6646

www.avxcorp.com

www.murata.com

www.t-yuden.com

www.tdk.com

Low ESR (equivalent series resistance) ceramic capaci-

tors should be used at both switching regulator outputs

as well as the switching regulator input supply. Only

X5R or X7R ceramic capacitors should be used because

they retain their capacitance over wider voltage and

temperature ranges than other ceramic types. A 10μF

output capacitor is sufﬁcient for most applications.

For good transient response and stability the output

capacitor should retain at least 4μF of capacitance over

operating temperature and bias voltage. The switching

regulator input supply should be bypassed with a 2.2μF

capacitor. Consult manufacturer for detailed information

on their selection and speciﬁcations of ceramic capaci-

tors. Many manufacturers now offer very thin (< 1mm

tall) ceramic capacitors ideal for use in height-restricted

designs. Table3showsalistofseveralceramiccapacitor

manufacturers.

Taiyo Yuden

TDK

PCB Layout Considerations

As with all DC/DC regulators, careful attention must be

paid while laying out a printed circuit board (PCB) and to

componentplacement.Theinductors,inputPV capacitor

IN

and output capacitors must all be placed as close to the

LTC3559/LTC3559-1 as possible and on the same side as

theLTC3559/LTC3559-1.Allconnectionsmustbemadeon

thatsamelayer.Placealocalunbrokengroundplanebelow

these components that is tied to the Exposed Pad (Pin 17)

of the LTC3559/LTC3559-1. The Exposed Pad must also

be soldered to system ground for proper operation.

3559fb

21

LTC3559/LTC3559-1

TYPICAL APPLICATIONS

The Output Voltage of a Buck Regulator Is Programmed for 3.3V. When BAT Voltage Approaches 3.3V, the Regulator Operates in

Dropout and the Output Voltage Will Be BAT – (I_LOAD• 0.6). An LED at CHRG Gives a Visual Indication of the Battery Charger State.

A 3-Resistor Bias Network for NTC Sets Hot and Cold Trip Points at Approximately 55°C and 0°C

UP TO

950mA

ADAPTER

4.5V TO 5.5V

V

BAT

CC

SINGLE

Li-lon CELL

+

1μF

510Ω 110k

28.7k

PV

IN

2.7V TO 4.2V (LTC3559)

2.7V TO 4.1V (LTC3559-1)

NTC

2.2μF

100k

NTC

LTC3559/

LTC3559-1

NTH50603N01

887Ω

4.7μH

1.02M

3.3V AT

400mA

CHRG

PROG

SUSP

HPWR

MODE

EN1

SW1

FB1

22pF

10μF

324k

649k

4.7μH

806k

1.8V AT

400mA

SW2

FB2

DIGITALLY

CONTROLLED

10μF

EN2

GND EXPOSED PAD

3559 TA03

Buck Regulator Efﬁciency vs I_LOAD

100

90

80

70

60

50

40

30

20

10

0

Burst Mode

OPERATION

90

80

70

60

50

40

30

20

10

0

Burst Mode

OPERATION

PULSE SKIP

MODE

PULSE SKIP

MODE

V

= 1.8V

OUT

PV = 4.2V

IN

OUT

PV = 2.7V

PV = 4.2V

IN

V

= 3.3V

0.1

1

10

100

1000

0.1

1

10

(mA)

100

1000

I

(mA)

LOAD

I

LOAD

3559 TA02c

3559 TA02b

3559fb

22

LTC3559/LTC3559-1

TYPICAL APPLICATIONS

The Battery Can be Charged with Up to 950mA of Charge Current. Buck Regulator 2 Is Enabled Only After V_OUT1Is Up to Approximately

0.7V. This Provides a Sequencing Function Which May Be Desirable in Applications Where a Microprocessor Needs to Be Powered Up

Before Peripherals. CHRG Interfaces to a Microprocessor Which Decodes the Battery Charger State

UP TO

950mA

ADAPTER

4.5V TO 5.5V

V

CC

BAT

SINGLE

Li-lon CELL

+

1μF

100k

PV

IN

2.7V TO 4.2V (LTC3559)

2.7V TO 4.1V (LTC3559-1)

NTC

2.2μF

100k

NTC

NTH50603NO1

100k

LTC3559/

LTC3559-1

4.7μH

655k

2.5V AT

400mA

TO

CHRG

PROG

SUSP

HPWR

MODE

EN1

SW1

FB1

MICROPROCESSOR

887Ω

22pF

10μF

309k

649k

DIGITALLY

CONTROLLED

4.7μH

324k

1.2V AT

400mA

10μF

SW2

FB2

EN2

GND EXPOSED PAD

3559 TA02

PACKAGE DESCRIPTION

UD Package

16-Lead Plastic QFN (3mm × 3mm)

(Reference LTC DWG # 05-08-1691)

BOTTOM VIEW—EXPOSED PAD

PIN 1 NOTCH R = 0.20 TYP

OR 0.25 s 45o CHAMFER

R = 0.115

TYP

0.75 p 0.05

3.00 p 0.10

(4 SIDES)

15 16

0.70 p0.05

PIN 1

TOP MARK

(NOTE 6)

0.40 p 0.10

1

2

3.50 p 0.05

2.10 p 0.05

1.45 p 0.05

(4 SIDES)

1.45 p 0.10

(4-SIDES)

PACKAGE

OUTLINE

(UD16) QFN 0904

0.200 REF

0.25 p 0.05

0.25 p0.05

0.50 BSC

0.00 – 0.05

0.50 BSC

RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS

NOTE:

1. DRAWING CONFORMS TO JEDEC PACKAGE OUTLINE MO-220 VARIATION (WEED-2)

2. DRAWING NOT TO SCALE

3. ALL DIMENSIONS ARE IN MILLIMETERS

4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE

MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE

5. EXPOSED PAD SHALL BE SOLDER PLATED

6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION

ON THE TOP AND BOTTOM OF PACKAGE

3559fb

Information furnished by Linear Technology Corporation is believed to be accurate and reliable.

However, no responsibility is assumed for its use. Linear Technology Corporation makes no representa-

tion that the interconnection of its circuits as described herein will not infringe on existing patent rights.

23

LTC3559/LTC3559-1

RELATED PARTS

PART NUMBER

DESCRIPTION

COMMENTS

LTC3550

Dual Input USB/AC Adapter Li-Ion Battery Charger with Synchronous Buck Converter, Efﬁciency: 93%, Adjustable Output at

Adjustable Output 600mA Buck Converter

600mA, Charge Current: 950mA Programmable, USB Compatible,

Automatic Input Power Detection and Selection

LTC3552

LTC3552-1

LTC3455

Standalone Linear Li-Ion Battery Charger with Adjustable Synchronous Buck Converter, Efﬁciency: >90%, Adjustable Outputs at

Output Dual Synchronous Buck Converter

800mA and 400mA, Charge Current Programmable Up to 950mA, USB

Compatible, 5mm × 3mm DFN16 Package

Standalone Linear Li-Ion Battery Charger with Dual

Synchronous Buck Converter

Synchronous Buck Converter, Efﬁciency: >90%, Outputs 1.8V at 800mA

and 1.575 at 400mA, Charge Current Programmable Up to 950mA, USB

Compatible

Dual DC/DC Converter with USB Power Manager and

Li-Ion Battery Charger

Seamless Transition Between Input Power Sources: Li-Ion Battery, USB

and 5V Wall Adapter, Two High Efﬁciency DC/DC Converters: Up to 96%,

Full-Featured Li-Ion Battery Charger with Accurate USB Current Limiting

(500mA/100mA) Pin-Selectable Burst ModeOperation, Hot Swap^TM

Output for SDIO and Memory Cards, 4mm × 4mm QFN24 Package

LTC3456

2-Cell, Multi-Output DC/DC Converter with USB Power

Manager

Seamless Transition Between 2-Cell Battery, USB and AC Wall Adapter

Input Power Sources, Main Output: Fixed 3.3V Output, Core Output:

Adjustable From 0.8V to V

, Hot Swap Output for Memory Cards,

BATT(MIN)

Power Supply Sequencing: Main and Hot Swap Accurate USB Current

Limiting, High Frequency Operation: 1MHz, High Efﬁciency: Up to 92%,

4mm × 4mm QFN24 Package

LTC4080

500mA Standalone Charger with 300mA Synchronous

Buck

Charges Single-Cell Li-Ion Batteries, Timer Termination +C/10, Thermal

Regulation, Buck Output: 0.8V to V , Buck Input V : 2.7V to 5.5V, 3mm

BAT

IN

× 3mm DFN10 Package

Hot Swap is a trademark of Linear Technology Corporation.

3559fb

LT 0508 REV B • PRINTED IN USA

LinearTechnology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

24

●

(408) 432-1900 FAX: (408) 434-0507 www.linear.com


型号：	LTC3559
厂家：	Linear
描述：	Linear USB Battery Charger with Dual Buck Regulators 线性USB电池充电器，双通道降压稳压器稳压器电池
文件：	总24页 (文件大小：300K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

LTC3559 [Linear]

相关型号：

LTC3559-1_15

LTC3559EUD

LTC3559EUD#PBF

LTC3559EUD#TR

LTC3559EUD#TRPBF

LTC3559EUD-1#PBF

LTC3559EUD-1#TRPBF

LTC3559EUD-1-PBF

LTC3559EUD-1-TRPBF

LTC3559EUD-PBF

LTC3559EUD-TRPBF

LTC3559_15