LTC4121IUD-4.2#PBF - ANALOG DEVICES

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

TYPICAL APPLICATION

FEATURES DESCRIPTION

40V 400mA Synchronous

Step-Down Battery Charger

The LT C

4121 is a 400mA constant-current/constant-

voltage (CC/CV) synchronous step-down battery charger.

In addition to CC/CV operation, the LTC4121 regulates its

input voltage to a programmable percentage of the input

open-circuit voltage. This technique maintains maximum

power transfer with high impedance input sources such

as solar panels.

An external resistor programs the charge current up to

400mA. The LTC4121-4.2 is suitable for charging Li-Ion/

Polymer batteries, while the programmable float voltage

of the LTC4121 is suitable for several battery chemistries.

The LTC4121 and LTC4121-4.2 include an accurate RUN

pin threshold, low voltage battery preconditioning and bad

battery fault detection, timer termination, auto-recharge,

and NTC temperature qualified charging. The FAULT pin

provides an indication of bad battery or temperature faults.

Once charging is terminated, the LTC4121 signals end-of-

charge via the CHRG pin, and enters a low current SLEEP

mode. An auto-restart feature starts a new charging cycle

if the battery voltage drops by 2.2%.

LTC4121 Efficiency vs VIN at VFLOAT = 8.4V

APPLICATIONS

n Wide Input Voltage Range: 4.4V to 40V

n Temperature Compensated Input Voltage

Regulation for Maximum Power Point Tracking

(MPPT)

n Adjustable Float Voltage 3.5V to 18V (LTC4121)

n Fixed 4.2V Float Voltage Option (LTC4121-4.2)

n High Efficiency: Up to 95%

n 50mA to 400mA Programmable Charge Current

n ±1% Feedback Voltage Accuracy

n Programmable 5% Accurate Charge Current

n Thermally Enhanced, Low Profile (0.75mm)

16-Lead (3mm × 3mm) QFN Package

n Handheld Instruments

n Solar Powered Devices

n Industrial/Military Sensors and Devices

L, LT , LT C , LT M , Linear Technology, the Linear logo and Burst Mode are registered trademarks

of Linear Technology Corporation. All other trademarks are the property of their respective

owners.

INTVCC

BOOST

CHGSNS

BAT

FBG

RUN

MPPT

PROG

LTC4121

GND

10k

10µF

RPROG

VIN

VBAT + 200mV

TO 40V

22nF

SLF6025T-470MR48

2.2µF

FREQ +

22µF

1.96M

787k

4121 TA01a

Li-Ion

–

High Efficiency, Wide Input Voltage Range Charging with LTC4121

VIN (V)

EFFICIENCY (%)

10 15 20

4121 TA01b

25 30 35 40

200mA, RPROG = 6.04k

400mA, RPROG = 3.01k

VBAT = 8.3V

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

ABSOLUTE MAXIMUM RATINGS

IN, RUN, CHRG, FA U LT, MPPT ................... –0.3V to 43V

BOOST ................................... VSW – 0.3V to (VSW + 6V)

SW (DC) ........................................ –0.3V to (VIN + 0.3V)

SW (Pulsed <100ns) ......................–1.5V to (VIN + 1.5V)

CHGSNS, BAT, FB/BATSNS, FBG ................ –0.3V to 18V

FREQ, NTC, PROG, INTVCC .......................... –0.3V to 6V

ICHGSNS, IBAT ..................................................... ±600mA

(Note 1)

ORDER INFORMATION

LEAD FREE FINISH TAPE AND REEL PART MARKING PACKAGE DESCRIPTION TEMPERATURE RANGE

LTC4121EUD#PBF LTC4121EUD#TRPBF LGHC 16-Lead (3mm × 3mm) Plastic QFN –40°C to 125°C

LTC4121IUD#PBF LTC4121IUD#TRPBF LGHC 16-Lead (3mm × 3mm) Plastic QFN –40°C to 125°C

LTC4121EUD-4.2#PBF LTC4121EUD-4.2#TRPBF LGMV 16-Lead (3mm × 3mm) Plastic QFN –40°C to 125°C

LTC4121IUD-4.2#PBF LTC4121IUD-4.2#TRPBF LGMV 16-Lead (3mm × 3mm) Plastic QFN –40°C to 125°C

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

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/. Some packages are available in 500 unit reels through

designated sales channels with #TRMPBF suffix.

LTC4121 LTC4121-4.2

16 15 14 13

5678

TOP VIEW

GND

UD PACKAGE

16-LEAD (3mm × 3mm) PLASTIC QFN

1INTVCC

BOOST

NTC

FBG

BAT

RUN

FAULT

CHRG

PROG

GND

MPPT

FREQ

CHGSNS

TJMAX = 125°C, θJA = 54°C/W

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

16 15 14 13

5678

TOP VIEW

GND

UD PACKAGE

16-LEAD (3mm × 3mm) PLASTIC QFN

1INTVCC

BOOST

NTC

BATSNS

BAT

RUN

FAULT

CHRG

PROG

GND

MPPT

FREQ

CHGSNS

TJMAX = 125°C, θJA = 54°C/W

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

PIN CONFIGURATION

ICHRG, IFAU LT, ........................................................±5mA

IFB, IFBG (LTC4121) .................................................±5mA

IBATSNS (LTC4121-4.2) ...........................................±5mA

IINTVCC .................................................................. –5mA

Operating Junction Temperature Range

(Note 2) .................................................. –40°C to 125°C

Storage Temperature Range .................... –65°C to 150°

LTC4121 Options

PART NUMBER FLOAT VOLTAGE

LTC4121 Programmable

LTC4121-4.2 4.2V Fixed

(http://www.linear.com/product/LTC4121#orderinfo)

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

ELECTRICAL CHARACTERISTICS

The l denotes the specifications which apply over the specified operating

junction temperature range, otherwise specifications are at TA = 25°C. VIN = VRUN = 15V, VCHGSNS = VBAT = 4V, RPROG = 3.01k,

VFB = 2.29V (LTC4121), VBATSNS = 4V (LTC4121-4.2). Current into a pin is positive out of a pin is negative. (Note 2)

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

Operating Input Supply Range l4.4 40 V

Battery Voltage Range LTC4121 (Note 3) 0 18 V

LTC4121-4.2 0 4.2 V

IIN DC Supply Current Switching: FREQ = GND 3.5 mA

Standby Mode: (Note 4) l142 260 µA

Sleep Mode: (Note 4)

LTC4121-4.2: VBATSNS =

4.4V

LTC4121: VFB = 2.51V (Note

110

µA

Disabled Mode: VSD < VRUN < VEN (Note 4) l37 80 µA

Shutdown Mode: (Note 4) l20 40 µA

∆VDUVLO Differential Undervoltage Lockout VIN – VBAT Falling, VIN = 5V (LTC4121)

VIN – VBATSNS Falling, VIN = 5V (LTC4121-4.2)

l20 80 160 mV

Hysteresis VIN – VBAT Rising, VIN = 5V (LTC4121)

VIN – VBATSNS Rising, VIN = 5V (LTC4121-4.2)

115 mV

UVINTVCC INTVCC Undervoltage Lockout (Note 5) INTVCC Rising, VIN = INTVCC + 100mV l4.00 4.15 4.26 V

Hysteresis INTVCC Falling 220 mV

Battery Charger

IBAT BAT Standby Current Standby Mode (LTC4121) (Notes 4, 8, 9)

Standby Mode (LTC4121-4.2) (Notes 4, 8, 9)

2.5

4.5

1000

µA

BAT Shutdown Current Shutdown Mode (LTC4121) (Notes 4, 8, 9)

Shutdown Mode (LTC4121-4.2) (Notes 4, 8, 9)

1100

2000

1000

IBATSNS BATSNS Standby Current (LTC4121-4.2) Standby Mode (Notes 4, 8, 9) l5.4 10 µA

BATSNS Shutdown Current (LTC4121-4.2) Shutdown Mode (Notes 4, 8, 9) l1100 2000 nA

IFB Feedback Pin Bias Current (LTC4121) VFB = 2.5V (Note 6) l25 60 nA

IFBG_LEAK Feedback Ground Leakage Current

(LTC4121)

Shutdown Mode (Note 4) l1 µA

RFBG Feedback Ground Return Resistance

(LTC4121)

l1000 2000 Ω

VFB(REG) Feedback Pin Regulation Voltage

(LTC4121)

(Note 6) 2.393 2.400 2.407 V

l2.370 2.418 V

VFLOAT Regulated Float Voltage (LTC4121-4.2) 4.188 4.200 4.212 V

l4.148 4.231 V

ICHG Battery Charge Current RPROG = 3.01k l383 402 421 mA

RPROG = 24.3k l45 50 55 mA

VRCHG Battery Recharge Threshold VFB Falling Relative to VFB(REG) (LTC4121) l–38 –49 –62 mV

VRCHG_4.2 VBATSNS Falling Relative to VFLOAT (LTC4121-4.2) l–70 –93 –114 mV

hPROG Ratio of BAT Current to PROG Current VTRKL < VFB < VFB(REG) (LTC4121),

VTRKL_42 < VBATSNS < VFLOAT (LTC4121-4.2)

988 mA/mA

VPROG PROG Pin Servo Voltage l1.206 1.227 1.248 V

RSNS CHGSNS-BAT Sense Resistor IBAT = –100mA 300 mΩ

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

ELECTRICAL CHARACTERISTICS

The l denotes the specifications which apply over the specified operating

junction temperature range, otherwise specifications are at TA = 25°C. VIN = VRUN = 15V, VCHGSNS = VBAT = 4V, RPROG = 3.01k,

VFB = 2.29V (LTC4121), VBATSNS = 4V (LTC4121-4.2). Current into a pin is positive out of a pin is negative. (Note 2)

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

ILOWBAT Low Battery Linear Charge Current VFB < VTRKL, VBAT = 2.6V (LTC4121) (Note 6) 6 9 16 mA

VBATSNS < VTRKL_4.2, VBAT = 2.6V (LTC4121-4.2)

VLOWBAT Low Battery Threshold Voltage VBAT Rising (LTC4121)

VBATSNS Rising (LTC4121-4.2)

l2.15 2.21 2. 28 V

Hysteresis 147 mV

ITRKL Switch Mode Trickle Charge Current VLOWBAT < VBAT, VFB < VTRKL (LTC4121) (Note 6) ICHG/10 mA

VLOWBAT < VBATSNS < VTRKL_42 (LTC4121-4.2)

PROG Pin Servo Voltage in Trickle Charge VLOWBAT < VBAT, VFB > VTRKL (LTC4121) (Note 6) 122 mV

VLOWBAT < VBATSNS < VTRKL_42 (LTC4121-4.2)

VTRKL Trickle Charge Threshold (LTC4121) VFB Rising (Note 6) l1.65 1.68 1.71 V

Hysteresis (LTC4121) VFB Falling (Note 6) 50 mV

VTRKL_4.2 Trickle Charge Threshold (LTC4121-4.2) VBATSNS Rising l2.86 2.91 2.98 V

Hysteresis (LTC4121-4.2) VBATSNS Falling 88 mV

hC/10 End of Charge Indication Current Ratio (Note 7) 0.1 mA/mA

Safety Timer Termination Period 1.3 2.0 2.8 hrs

Bad Battery Termination Timeout 19 30 42 min

Switcher

fOSC Switching Frequency FREQ = INTVCC l1.0 1.5 2.0 MHz

FREQ = GND l0.5 0.75 1.0 MHz

tMIN_ON Minimum Controllable On-Time 120 ns

Duty Cycle Maximum 94 %

Top Switch RDSON ISW = –100mA 0.8 Ω

Bottom Switch RDSON ISW = 100mA 0.5 Ω

IPEAK Peak Inductor Current Limit Measured Across RSNS with a 15µH Inductor in

Series with RSNS (Note 10)

585 1050 1250 mA

ISW Switch Pin Current (Note 9) IN Open-Circuit, VBAT = VSW = 4.2V (LTC4121-4.2) l 7 15 µA

IN Open-Circuit, VBAT = VSW = 8.4V (LTC4121) l15 30 µA

Status Pins FAULT, CHRG

Pin Output Voltage Low I = 2mA 550 mV

Pin Leakage Current V = 43V, Pin High-Impedance 0 1 µA

NTC

Cold Temperature VNTC/VINTVCC Fault Rising VNTC Threshold l73 74 75 %INTVCC

Falling VNTC Threshold 72 %INTVCC

Hot Temperature VNTC/VINTVCC Fault Falling VNTC Threshold l35.5 36.5 37.5 %INTVCC

Rising VNTC Threshold 37.5 %INTVCC

NTC Disable Voltage Falling VNTC Threshold l1 2 3 %INTVCC

Rising VNTC Threshold 3 %INTVCC

NTC Input Leakage Current VNTC = VINTVCC –50 50 nA

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

RUN

VEN Enable Threshold VRUN Rising l2.35 2.45 2.55 V

Hysteresis VRUN Falling 200 mV

Run Pin Input Current VRUN = 40V 0.01 0.1 µA

VSD Shutdown Threshold VRUN Falling l0.4 1.2 V

Hysteresis 220 mV

FREQ

FREQ Pin Input Low l0.4 V

FREQ Pin Input High l3.6 V

FREQ Pin Input Current 0 < VFREQ < VINTVCC ±1 µA

MPPT

IMPPT MPPT Pin Leakage Current VMPPT = 4.2V l15 1000 nA

TMP MPPT Sample Period Period Between Charger Disabled Events 28 s

PWMP MPPT Sample Pulse Width Charger Disabled Pulse Width 36 ms

KFInternal Divider Gain Internal DAC Voltage as a Ratio to VIN 0.098 0.1 0.102 V/V

VMP(OS) MPPT Error Amp Gain Offset VMPPT – VDAC, IBAT = 50%• ICHG 10 –45 –100 mV

ELECTRICAL CHARACTERISTICS

The l denotes the specifications which apply over the specified operating

junction temperature range, otherwise specifications are at TA = 25°C. VIN = VRUN = 15V, VCHGSNS = VBAT = 4V, RPROG = 3.01k,

VFB = 2.29V (LTC4121), VBATSNS = 4V (LTC4121-4.2). Current into a pin is positive out of a pin is negative. (Note 2)

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.

Note 2: The LTC4121 is tested under pulsed load conditions such that

TJ ≈ TA. The LTC4121E is guaranteed to meet performance specifications

for junction temperatures from 0°C to 85°C. Specifications over the

–40°C to 125°C operating junction temperature range are assured by

design, characterization and correlation with statistical process controls.

The LTC4121I is guaranteed over the full –40°C to 125°C operating

junction temperature range. Note that the maximum ambient temperature

consistent with these specifications is determined by specific operating

conditions in conjunction with board layout, the rated package thermal

impedance, and other environmental factors.

Note 3: If a battery voltage greater than 11V can be hot plugged to the

LTC4121 a reverse blocking diode is required in series with the BAT pin to

prevent large inrush current into the low impedance BAT pin.

Note 4: Standby mode occurs when the LTC4121/LTC4121-4.2 stops

switching due to an NTC fault, MPPT pause, or when the charge current

has dropped low enough to enter Burst Mode operation. Disabled mode

occurs when VRUN is between VSD and VEN. Shutdown mode occurs

when VRUN is below VSD or when the differential undervoltage lockout

is engaged. Sleep mode occurs after a timeout while the battery voltage

remains above the VRCHG or VRCHG_42 threshold.

Note 5: The internal supply INTVCC should only be used for the NTC

divider, it should not be used for any other loads

Note 6: For the LTC4121, the FB pin is measured with a resistance of 588k

in series with the pin.

Note 7: hC/10 is expressed as a fraction of measured full charge current as

measured at the PROG pin voltage when the CHRG pin de-asserts.

Note 8: In an application circuit with an inductor connected from SW to

CHGSNS, the total battery leakage current when disabled is the sum of

IBATSNS and ISW (LTC4121-4.2) or IBAT and IFBG_LEAK and ISW (LTC4121).

Note 9: When no supply is present at IN, the SW powers IN through the

body diode of the top side switch. This may cause additional SW pin

current depending on the load present at IN.

Note 10: Guaranteed by design and/or correlation to static test.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

TYPICAL PERFORMANCE CHARACTERISTICS

IN Pin Sleep/Disabled/Shutdown

Current vs Temperature

BAT Pin Sleep/Shutdown Current

vs Temperature

Feedback Pin Standby or Sleep/

Disabled Current vs Temperature

BATSNS Pin Sleep/Standby or

Shutdown/Disabled Current

vs Temperature

BAT Pin Standby/Sleep/Shutdown

Current vs Temperature

Typical VFB(REG) vs Temperature Typical VFLOAT vs Temperature

IN Pin Standby Current

vs Temperature

TEMPERATURE (°C)

–40

4.15

VFLOAT (V)

4.16

4.17

4.23

4.22

4.21

4.20

4.18

4.19

4.25

4.24

–25 –10 5 20

4121 G02

35 50 65 80 95 110 125

3 UNITS TESTED

LTC4121-4.2

VIN = 5V

HIGH LIMIT

DUT1 VFLOAT

DUT2 VFLOAT

DUT3 VFLOAT

LOW LIMIT

TEMPERATURE (°C)

–40

IIN (µA)

–25 –10 5 20

4121 G04

35 50 65 80 95 110 125

SLEEP

DIS

VIN = 15V

TEMPERATURE (°C)

–40

2.36

VFB(REG) (V)

2.37

2.38

2.41

2.40

2.39

2.43

2.42

–25 –10 5 20

4121 G01

35 50 65 80 95 110 125

4 UNITS TESTED

HIGH LIMIT

DUT1

DUT2

DUT3

DUT4

LOW LIMIT

LTC4121

VIN = 15V

TEMPERATURE (°C)

–40

IIN (µA)

100

160

150

140

130

110

120

180

170

–25 –10 5 20

4121 G03

35 50 65 80 95 110 125

STANDBY FREQ HIGH

STANDBY FREQ LOW

VIN = 15V

TEMPERATURE (°C)

–40

IBAT (µA)

–25 –10 5 20

4121 G05

35 50 65 80 95 110 125

SLEEP VBAT = 8.4V

SLEEP VBAT = 4.2V

SHUTDOWN VBAT = 8.4V

SHUTDOWN VBAT = 4.2V

LTC4121

TEMPERATURE (°C)

–40

IFB (nA)

–25 –10 5 20

4121 G06

35 50 65 80 95 110 125

STANDBY VFB = 2.51V

SLEEP/DIS VFB = 2.51V

LTC4121

TEMPERATURE (°C)

–40

IBATSNS (µA)

–25 –10 5 20

4121 G07

35 50 65 80 95 110 125

SLEEP/STANDBY VBATSNS = 4.25V

SHUTDOWN/DIS VBATSNS = 4.25V

LTC4121-4.2

TEMPERATURE (°C)

–40

IBAT (nA)

600

500

400

300

100

200

800

700

–25 –10 5 20

4121 G08

35 50 65 80 95 110 125

SHUTDOWN VBAT = 4.25V

STANDBY VBAT = 4.25V

SLEEP VBAT = 4.25V

LTC4121-4.2

Typical RSNS Current Limit IPEAK

vs Temperature

TEMPERATURE (°C)

–40

920

IPEAK (mA)

1080

1040

1020

1000

940

960

980

1120

1100

–25 –10 5 20

4121 G09

35 50 65 80 95 110 125

DUT1

DUT2

DUT3

3 UNITS TESTED

TA = 25°C, unless otherwise noted.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

TYPICAL PERFORMANCE CHARACTERISTICS

Typical Burst Mode Waveforms

IN Pin Shutdown Current

vs Input Voltage

Burst Mode Trigger Current

Typical Battery Charge Current

vs Temperature

Typical Solar Charging Cycle

Efficiency vs IBAT

IBAT (mA)

EFFICIENCY (%)

100

4121 G10

200 300 400

VIN = 9V

VIN = 14V

VIN = 19V

VIN = 24V

LTC4121-42

VBAT = 4.2V

FREQ = LOW

LSW = SLF12575T-470M2R7

TEMPERATURE (°C)

–40

ICHG (mA)

150

100

250

200

450

350

300

400

–25

4121 G11

–10 5 20 35 50 65 80 95 110 125

VIN = 15V

VBAT = 3.8V

RPROG = 3.01k

RPROG = 6.04k

RPROG = 12.1k

RPROG = 24.3k

TIME (HR)

BATTERY CURRENT (mA)

VBAT, VCHRG (V)

150

100

250

200

450

350

300

400

1.5

1.0

2.5

2.0

0.5

4.5

3.5

3.0

4.0

0.5

4121 G12

1 1.5 2 2.5 3 3.5

BAT = 500mAHr

LSW = TDK SLF7045

47µH

RFB1 = 732k,

RFB2 = 976k

RPROG = 3.01k

VCHRG

IBAT

VBAT

VIN (V)

IIN (µA)

4121 G15

15 20 25 30 35 40

SHUTDOWN 130°C

SHUTDOWN 25°C

SHUTDOWN –45°C

IN Pin Disabled Current

vs Input Voltage

VIN (V)

IIN (µA)

4121 G16

15 20 25 30 35 40

DISABLED 130°C

DISABLED 25°C

DISABLED –45°C

VIN (V)

IBAT (mA)

100

4121 G13

15 20 25 30 35 40

RPROG = 3.01kΩ

RPROG = 6.04kΩ

VSW

5V/DIV

VPROG

200mV/DIV

ISW

200mA/DIV

4121 G14

4µs/DIV

VIN = 15V

VBAT = 4.2V

IBAT = 38mA

FREQ = GND

TA = 25°C, unless otherwise noted.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

PIN FUNCTIONS

INTVCC (Pin 1): Internal Low Drop Out (LDO) Regulator

Output Pin. This pin is the output of an internal linear

regulator that generates the internal INTVCC supply from

IN. It also supplies power to the switch gate drivers and

the low battery linear charge current ILOWBAT. Connect

a 2.2µF low ESR capacitor from INTVCC to GND. Do not

place any external load on INTVCC other than the NTC bias

network. Overloading this pin can disrupt internal operation.

When the RUN pin is above VEN, and INTVCC rises above

the UVLO threshold and IN rises above BAT by ∆VDUVLO

and its hysteresis, the charger is enabled.

BOOST (Pin 2): Boosted Supply Pin. Connect a 22nF boost

capacitor from this pin to the SW pin.

IN (Pin 3): Positive Input Power Supply. Decouple to GND

with a 10µF or larger low ESR capacitor. The input supply

impedance and the input decoupling capacitor form an RC

network that must settle during the MPPT sample pulse

width of about 36ms. This allows the LTC4121 to sample

the open-circuit voltage.

SW (Pin 4): Switch Pin. The SW pin delivers power from

IN to BAT via the step-down switching regulator. An in-

ductor should be connected from SW to CHGSNS. See

the Applications Information section for a discussion of

inductor selection.

GND (Pin 5, Exposed Pad Pin 17): Ground Pin. Connect to

Exposed Pad. The Exposed Pad must be soldered to PCB

GND to provide a low electrical and thermal impedance

connection to ground.

MPPT (Pin 6): Maximum Power Point Tracking Pin. This

pin is used to program an input voltage regulation loop.

Connect an external resistive divider from VIN to MPPT to

GND. This divider programs the maximum power point

voltage as percentage of the input open-circuit voltage.

For more information on programming the MPPT resis-

tive divider refer to the Application Information section. If

the input voltage regulation feature is not used, connect

MPPT to either INTVCC or IN with a minimum 10k resistor.

Keep parasitic capacitance at the MPPT pin to a minimum

as capacitance at this pin forms a pole that may interfere

with switching regulator stability.

FREQ (Pin 7): Step-Down Regulator Switching Frequency

Select Input Pin. Connect to INTVCC to select a 1.5MHz

switching frequency or GND to select a 750kHz switching

frequency. Do not float.

CHGSNS (Pin 8): Battery Charge Current Sense Pin. An

internal current sense resistor between CHGSNS and BAT

pins monitors battery charge current. An inductor should

be connected from SW to CHGSNS.

IN Pin Switching Current

vs Input Voltage

IN Pin Sleep Current

vs Input Voltage

IN Pin Standby Current

vs Input Voltage

VIN (V)

IIN(SWITCHING) (mA)

4121 G17

15 20 25 30 35 40

FREQ = INTVCC

IBAT = 0

FREQ = GND 130°C

25°C

–45°C

VIN (V)

IIIN (µA)

140

120

100

4121 G18

15 20 25 30 35 40

SLEEP 130°C

SLEEP 25°C

SLEEP –45°C

VIN (V)

IIIN (µA)

100

120

110

180

170

130

150

140

160

4121 G19

15 20 25 30 35 40

STANDBY FREQ HIGH 25°C

STANDBY FREQ LOW 25°C

TYPICAL PERFORMANCE CHARACTERISTICS

TA = 25°C, unless otherwise noted.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

PIN FUNCTIONS

BAT (Pin 9): Battery Output Pin. Battery charge current

is delivered from this pin through the internal charge

current sense resistor. In low battery conditions a small

linear charge current, ILOWBAT, is sourced from this pin

to precondition the battery. Decouple the BAT pin with a

low ESR 22µF ceramic capacitor to GND.

BATSNS (Pin 10, LTC4121-4.2 Only): Battery Voltage

Sense Pin. For proper operation, this pin must always be

connected physically close to the positive battery terminal.

FB (Pin 10, LTC4121 Only): Battery Voltage Feedback

Reference Pin. The charge function operates to achieve a

final float voltage of 2.4V at this pin. Battery float voltage

is programmed using a resistive divider from BAT to FB

to FBG, and can be programmed from 3.5V up to 18V.

The feedback pin input bias current, IFB, is 25nA. Using a

resistive divider with a Thevenin equivalent resistance of

588k compensates for input bias current error.

FBG (Pin 11, LTC4121 Only): Feedback Ground Pin. This

pin disconnects the external FB divider load from the battery

when it is not needed. When sensing the battery voltage

this pin presents a low resistance, RFBG, to GND. When in

disabled or shutdown modes this pin is high impedance.

NTC (Pin 12): Input to the Negative Temperature Coefficient

Thermistor Monitoring Circuit. The NTC pin connects to

a negative temperature coefficient thermistor which is

typically co-packaged with the battery to determine if the

battery is too hot or too cold to charge. If the battery’s

temperature is out of range, the LTC4121 enters STANDBY

mode and charging is paused until the battery tempera-

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

required from INTVCC to NTC and a thermistor is required

from NTC to GND. Tie the NTC pin to GND, and omit the

NTC resistive divider to disable NTC qualified charging if

NTC functionality is not required.

PROG (Pin 13): Charge Current Program and Charge

Current Monitor Pin. Connect a 1% resistor between

3.01k (400mA) and 24.3k (50mA) from PROG to ground

to program the charge current. While in constant-current

mode, this pin regulates to 1.227V. The voltage at this pin

represents the average charge current using the following

formula:

ICHG =hPROG •

PROG

RPROG

where hPROG is typically 988. Keep parasitic capacitance

on the PROG pin to a minimum. If monitoring charge cur-

rent via the voltage at the PROG pin add a series resistor

of at least 2k to isolate stray capacitance from this node.

CHRG (Pin 14): Open-drain Charge Status Output Pin.

Typically pulled up through a resistor to a reference

voltage, the CHRG pin indicates the status of the battery

charger. The pin can be pulled up to voltages as high as

IN when disabled, and can sink currents up to 5mA when

enabled. When the battery is being charged, the CHRG

pin is pulled low. When the termination timer expires or

the charge current drops below 10% of the programmed

value, the CHRG pin is forced to a high impedance state.

FAULT (Pin 15): Open-drain Fault Status Output Pin. Typi-

cally pulled up through a resistor to a reference voltage,

this status pin indicates fault conditions during a charge

cycle. The pin can be pulled up to voltages as high as IN

when disabled, and can sink currents up to 5mA when

enabled. An NTC temperature fault causes this pin to be

pulled low. A bad battery fault also causes this pin to

be pulled low. If no fault conditions exist, the FAULT pin

remains high impedance.

RUN (Pin 16): Run Pin. When RUN is pulled below VEN

and its hysteresis, the device is disabled. In disabled

mode, battery charge current is zero and the CHRG and

FAULT pins assume high impedance states. If the voltage

at RUN is pulled below VSD, the device is in SHUTDOWN

mode. When the voltage at the RUN pin rises above VEN,

the INTVCC LDO turns on. When the INTVCC LDO rises

above its UVLO threshold the charger is enabled. The

RUN pin should be tied to a resistive divider from VIN to

program the input voltage at which charging is enabled.

Do not float the RUN pin.

LTC4121/LTC4121-4.2

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BLOCK DIAGRAM

IN INTVCC

LTC4121

ENABLE

CIN

10µF

4121 F01

BOOST

RUN

CBST

22nF

LSW

22µH

MPPT

NTC

FAULT

FREQ

–

2.45V

–

0.9

–

IN-80mV

BAT

SHUTDOWN

DUVLC

PWM

INTVCC

LDO

ENABLE

CHGSNS

BAT

GND

PROG

ENABLE

CHRG

CNTRL

INTVCC

ITH

NTC

INTVCC

ENABLE

LOWBAT

HOT

COLD

DISABLE

–

2.21V

BAT

–

IMPPT

RMPPT1

RMPPT2

KR • VIN

KF • VIN DAC

INTVCC

TMP KF • VIN

+VMP(OS)

INTVCC

–

INTVCC

C-EA

V-EA

588k

–

RFB1

RFB2

RPROG

3.01k

CBAT

22µF

FBG

RSNS

0.3Ω

VFB(REG) 10k

RNOM

10k

CINTVCC

2.2µF

RRUN1

RRUN2

Figure 1. Block Diagram

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BLOCK DIAGRAM

Figure 2. LTC4121-4.2 BATSNS Connections

4121 F02

CHGSNS

BAT

PROG

LOWBAT +

–

2.21V

BATSNS

DUVLO

LTC4121-4.2

–

INTVCC

–

INTVCC

C-EA

V-EA

588k

–

CBAT

22µF Li-Ion

BATSNS

RSNS

0.3Ω

2.4V

BATSNS

IN-80mV

ENABLE

ITH

MPPT

INTVCC

–

IMPPT

RMPPT1

RMPPT2

KR • VIN

KF • VIN

VIN

DAC

INTVCC

TMP KF • VIN

+VMP(OS)

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OPERATION

Overview

The LTC4121 is a synchronous step-down (buck)

monolithic battery charger with maximum power-point

tracking (MPPT) control of the source voltage. The

LTC4121/LTC4121-4.2 serves as a constant-current/

constant-voltage battery charger with the following built-in

charger functions: programmable charge current, battery

precondition with ½ hour timeout, precision shutdown/

run control, NTC thermal protection, a 2-hour safety ter-

mination timer, and automatic recharge. The LTC4121/

LTC4121-4.2 also provides output pins to indicate state

of charge and fault status.

Maximum Power Point Tracking

The LTC4121 employs an MPPT algorithm that compares a

stored open-circuit input voltage measurement against the

instantaneous input voltage while charging. The LTC4121

automatically reduces the charge current if the input voltage

falls below the user defined percentage of the open-circuit

voltage. This algorithm lets the LTC4121 optimize power

transfer for a variety of different input sources including

first order temperature compensation of a solar panel.

The LTC4121 periodically pauses charging to measure

the open-circuit voltage allowing the LTC4121 to track

fluctuations in the available power. About once every 30

seconds the LTC4121 pauses charging and waits about

36ms (PWMP) for the input voltage to recover to its

open-circuit potential. At the end of this recovery time,

the LTC4121 samples the input voltage divided by 10 (1/

KF), and stores this value on a digital to analog converter

(DAC). When charging resumes, the DAC voltage is com-

pared against the MPPT pin voltage that is programmed

with a resistive divider. If the MPPT voltage falls below

the DAC voltage, the charge current is reduced to regulate

the input voltage at that level. This regulation loop serves

to maintain the input voltage at or above a user defined

level that corresponds to the peak power available from

the applied source.

A timing diagram illustrating the sampling of the open-

circuit voltage is shown below. The charge current drops

to zero and the LTC4121 waits PWMP and then samples

the open-circuit voltage. When charging resumes the

input voltage collapses if the source cannot support the

demanded charge current. When the input voltage drops

to VMP, the charge current is reduced so as to maintain

VIN at VMP.

Figure 3. MPPT Timing Diagram

4121 F03

TIME

TMP = 30s

PWMP = 36ms SAMPLE VIN(OC) STORE

IN DAC: 23µs

VIN RECOVERS

PAUSE CHARGER

ICHG

VOC

VIN

IBAT

VMP

Connect the MPPT pin to a resistive input voltage divider,

as shown in Figure 4, to program the fraction (KR) of the

input voltage where the input voltage regulation loop

reduces available charge current. The LTC4121 reduces

charge current if the MPPT pin voltage falls below the fixed

fraction (KF) of the open-circuit voltage (VOC). The ratio of

(KF/KR) defines the maximum power voltage (VMP) of the

applied power source as a ratio to the open-circuit voltage

(VOC) following the relation:

VMP

=KF

=0.1

=0.1• RMPPT1 +RMPPT2

( )

MPPT2

where the MPPT pin resistive divider gain is KR = RMPPT2/

(RMPPT1 + RMPPT2). These equations can be rearranged to

solve for RMPPT2 in terms of KF (0.1) and the maximum power

voltage divided by the open circuit voltage, (VMP/VOC) as:

RMPPT2 =

0.1

VMP

VOC









−0.1

•RMPPT

This function serves to maintain the input voltage at or

above the peak power voltage while the LTC4121 charges

a battery.

Because MPPT operation involves large changes of input

voltage, it is important to ensure that the programmed

maximum power voltage does not violate minimum input

operating conditions: 4.4V or 160mV above the battery

voltage, whichever is higher.

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OPERATION

When no power source is applied to VIN, for example when

using a solar panel source and the panel is in the dark, the

MPPT pin divider drains power from the battery through the

body diode of the top side switch of the switching regula-

tor. To eliminate this leakage path, the MPPT divider may

be connected to the anode of the Schottky diode that is in

series with the panel, for examples see Figures 1, 9, or 10.

For example, consider charging a battery from a source

with an open-circuit voltage of 30V and a source impedance

of 120Ω. This resistive supply has a short circuit current

of 250mA, and the peak available power of 1.875W oc-

curs with a load of 125mA at 50% of VOC. To program the

LTC4120 to optimize the available power for this source

simply program VMP/VOC to 50% by selecting the MPPT

resistive divider gain KR = 0.2. This is obtained with a resis-

tive divider as shown in Figure 4 with RMPPT2 = RMPPT1/4.

With standard 1% resistors this is approximated with

RMPPT1 = 402k, and RMPPT2 = 100k.

If the MPPT pin sees excess capacitance to GND, this may

affect switching regulator stability. In such cases, one may

optionally add a 50pF to 150pF lead capacitor (CMPPT) as

shown in Figure 4.

The sampling of VOC is done at an extremely low duty

cycle so as to have minimum impact on the average

charge current. The time between sample events, TMP,

is typically about 30 seconds, with an idle time, PWMP,

of about 36ms to allow the source to recover to its

open-circuit voltage through the time constant associ-

ated with the input decoupling capacitor CIN. The time

constant for the source to recover to its open-circuit

voltage must be kept below the idle period. Limit the

input capacitor to 10µF to avoid increasing the source

recovery time.

Programming the Battery Float Voltage

For the LTC4121, the battery float voltage is programmed

by placing a resistive divider from the battery to FB and

FBG as shown in Figure 5. The battery float voltage is

programmable anywhere from 3.5V up to 18V. The pro-

grammable battery float voltage, VFLOAT, is then governed

by the following equation:

VFLOAT =VFB(REG) •RFB1

RFB2

( )

RFB2

where VFB(REG) is typically 2.4V.

Due to the input bias current (IFB) of the voltage error amp

(V-EA), care must also be taken to select the Thevenin

equivalent resistance of RFB1//RFB2 close to 588kΩ. Start

by calculating RFB1 to satisfy the following relations:

RFB1 =

FLOAT

• 588k

VFB(REG)

Find the closest 0.1% or 1% resistor to the calculated

value. With RFB1 calculate:

RFB2 =

FB(REG)

•R

FB1

VFLOAT −V

FB(REG)

−1000Ω

Where 1000Ω represent the typical value of RFBG. This is

the resistance of the FBG pin which serves as the ground

return for the battery float voltage divider.

Once RFB1 and RFB2 are selected re-calculate the value of

VFLOAT obtained with the resistors available. If the error

Figure 4. MPPT Resistive Divider Figure 5. Programming the Float Voltage with LTC4121

4121 F05

BAT

22µF

RFB1

VFLOAT

RFB2

Li-Ion

FBG

ENABLE

IFB

LTC4121

4121 F04

RMPPT1

CMPPT

(OPTIONAL)

RMPPT2

IMPPT

MPPT

GND

LTC4121

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OPERATION

is too large substitute another standard resistor value for

RFB1 and recalculate RFB2. Repeat until the float voltage

error is acceptable.

Table 1 and Table 2 below list recommended standard 0.1%

and 1% resistor values for common battery float voltages.

Table 1. Recommended 0.1% Resistors for Common VFLOAT

VFLOAT (V) RFB1 (kΩ) RFB2 (kΩ) TYPICAL ERROR (%)

3.6 887 1780 –0.13

4.1 1010 1420 0.15

4.2 1010 1350 –0.13

7.2 1800 898 0.08

8.2 2000 825 0.14

8.4 2050 816 0.27

Table 2 Recommended 1% Resistors for Common VFLOAT

VFLOAT (V) RFB1 (kΩ) RFB2 (kΩ) TYPICAL ERROR (%)

3.6 887 1780 –0.13

4.1 1000 1430 0.26

4.2 1020 1370 –0.34

7.2 1780 887 0.16

8.2 2000 825 0.14

8.4 2100 845 –0.50

Programming the Charge Current

The current-error amp (C-EA) measures the current

through an internal 0.3Ω current sense resistor between

the CHGSNS and BAT pins. The C-EA outputs a fraction

of the charge current, 1/hPROG, to the PROG pin. The

voltage-error amp (V-EA) and PWM control circuitry can

limit the PROG pin voltage to control charge current. An

internal clamp (DZ) limits the PROG pin voltage to VPROG,

which in turn limits the charge current to:

ICHG =

PROG

• V

PROG

RPROG

1212V

RPROG

ICHG _ TRKL =120V

RPROG

where hPROG is typically 988, VPROG is either 1.227V or

122mV during trickle charge, and RPROG is the resistance

of the grounded resistor applied to the PROG pin. The

PROG resistor sets the maximum charge current, or

the current delivered while the charger is operating in

constant-current (CC) mode.

Analog Charge Current Monitor

The PROG pin provides a voltage signal proportional

to the actual charge current. Care must be exercised in

measuring this voltage as any capacitance at the PROG pin

forms a pole that may cause loop instability. If observing

the PROG pin voltage, add a series resistor of at least 2k

and limit stray capacitance at this node to less than 50pF.

In the event that the input voltage cannot support the

demanded charge current, the PROG pin voltage may not

represent the actual charge current. In cases such as this,

the PWM switch frequency drops as the charger enters

dropout operation where the top switch remains on for

more than one clock cycle as the inductor current attempts

to ramp up to the desired current. If the top switch remains

on in dropout for 8 clock cycles a dropout detector forces

the bottom switch on for the remainder of the 8th cycle.

In such a case, the PROG pin voltage remains at 1.227V,

but the charge current may not reach the desired level.

NTC Thermal Battery Protection

The LTC4121 monitors battery temperature using a therm-

istor during the charging cycle. If the battery temperature

moves outside a safe charging range, the IC suspends

charging and signals a fault condition until the tempera-

Figure 6. NTC Connection

4121 F06

BAT

TOO COLD

RBIAS

74% INTVCC RADJ

OPT

Li-Ion

INTVCC

NTC

RNTC T

LTC4121

–

TOO HOT 37% INTVCC

–

IGNORE NTC

2% INTVCC

–

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OPERATION

ture returns to the safe charging range. The safe charging

range is determined by two comparators that monitor the

voltage at the NTC pin. NTC qualified charging is disabled

if the NTC pin is pulled below about 85mV (VDIS).

Thermistor manufacturers usually include either a tem-

perature lookup table identified with a characteristic curve

number, or a formula relating temperature to the resistor

value. Each thermistor is also typically designated by a

thermistor gain value B25/85.

The NTC pin should be connected to a voltage divider

from INTVCC to GND as shown in Figure 6. In the simple

application (RADJ = 0) a 1% resistor, RBIAS, with a value

equal to the resistance of the thermistor at 25°C is con-

nected from INTVCC to NTC, and a thermistor is connected

from NTC to GND. With this setup, the LTC4121 pauses

charging when the resistance of the thermistor increases

to 285% the RBIAS resistor as the temperature drops. For

a Vishay Curve 2 thermistor with B25/85 = 3490 and 25°C

resistance of 10kΩ, this corresponds to a temperature

of about 0°C. The LTC4121 also pauses charging if the

thermistor resistance decreases to 58.8% of the RBIAS

resistor. For the same Vishay Curve 2 thermistor, this

corresponds to approximately 40°C. With a Vishay Curve

2 thermistor, the hot and cold comparators both have

about 2°C of hysteresis to prevent oscillations about the

trip points. The NTC comparator trip points are ratio metric

to the INTVCC voltage, so NTC trip points are defined as a

percentage of INTVCC. The HOT threshold is calculated as

285%/385% = 74% of INTVCC and the COLD threshold is

calculated as 58.8%/158% = 37% of INTVCC.

The hot and cold trip points may be adjusted using a differ-

ent type of thermistor, or a different RBIAS resistor, or by

adding a desensitizing resistor, RADJ, or by a combination

of these measures as shown in Figure 6. For example, by

increasing RBIAS to 12.4kΩ, with the same thermistor as

before, the cold trip point moves down to –5°C, and the

hot trip point moves down to 34°C. If a Vishay Curve 1

thermistor with B25/85 = 3964 and resistance of 100kΩ

at 25°C is used, a 1% RBIAS resistor of 118kΩ and a 1%

RADJ resistor of 12.1kΩ results in a cold trip point of 0°C,

and a hot trip point of 39°C.

End-of-Charge Indication and Safety Timeout

The LTC4121 uses a safety timer to terminate charging.

Whenever the LTC4121 is in constant current mode the

timer is paused, and when FB rises or falls through the

VRCHG threshold the timer is reset. When the battery

voltage reaches the float voltage, the safety timer begins

counting down a 2-hour timeout. If charge current falls

below one tenth of the programmed maximum charge cur-

rent (hC/10), the CHRG status pin rises, but top-off charge

current continues to flow until the timer finishes. After the

timeout, the LTC4121 enters a low-power sleep mode.

Automatic Recharge

In sleep mode, the IC continues to monitor battery voltage.

If the battery falls 2.2% (VRCHG or VRCHG_42) from the full-

charge float voltage, the LTC4121 engages an automatic

recharge cycle as the safety timer is reset. Automatic

recharge has a built in delay of about 0.5ms to prevent

triggering a new charge cycle if a load transient causes

the battery voltage to drop temporarily.

State of Charge and Fault Status Pins

The LTC4121 contains two open-drain outputs which

provide charge status and signal fault indications. The

CHRG pin pulls low to indicate charging at a rate higher

than C/10. The FAULT pin pulls low to indicate a bad bat-

tery timeout, or to indicate an NTC thermal fault condition.

During NTC faults the CHRG pin remains low, but when

a bad-battery timeout occurs the CHRG pin de-asserts.

When the open drain outputs are pulled up with a resistor,

Table 3 summarizes the charger state that is indicated by

the pin voltages.

Table 3 LTC4121 Open-Drain Indicators with Resistor Pull-Ups

FAULT CHRG CHARGER STATE

High High Off or Topping-Off Charge at a Rate Less Than C/10.

High Low Charging at Rate Higher Than C/10

Low High Bad Battery Fault

Low Low NTC Thermal Fault, Charging Paused

Low Battery Voltage Operation

The LTC4121 automatically preconditions heavily dis-

charged batteries. If the battery voltage is below VLOWBAT

minus its hysteresis (typically 2.05V - e.g. battery pack

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protection has been engaged) a DC current, ILOWBAT, is

applied to the BAT pin from the INTVCC supply. When

the battery voltage rises above VLOWBAT, the switching

regulator is enabled and charges the battery at a trickle

charge level of 10% of the full scale charge current (in

addition to the DC ILOWBAT current). Trickle charging of

the battery continues until the sensed battery voltage rises

above the trickle charge threshold, VTRKL, or VTRKL_42.

When the battery rises above the trickle charge threshold

the full scale charge current is applied and the DC trickle

charge current is turned off. If the battery remains below

the trickle charge threshold for more than 30 minutes,

charging terminates and the fault status pin is asserted

to indicate a bad battery. After a bad battery fault, the

LTC4121 automatically restarts a new charge cycle once

the failed battery is removed and replaced with another

battery. The LTC4121-4.2 monitors the BATSNS pin volt-

age to sense LOWBAT and TRKL conditions.

Precision Run/Shutdown Control

The LTC4121 remains in a low power disabled mode until

the RUN pin is driven above VEN (typically 2.45V). While

the LTC4121 is in disabled mode, current drain from the

battery is reduced to extend battery lifetime, the status pins

are both de-asserted, and the FBG pin is high impedance.

Charging can be stopped at any time by pulling the RUN

pin below 2.25V. The LTC4121 also offers an extremely

low operating current shutdown mode when the RUN pin

is pulled below VSD (typically about 0.7V). In this condition

less than 20µA is pulled from the supply at IN. Tie the RUN

pin to a resistive divider from the IN supply to program

the voltage where the LTC4121 turns on. Examples are

shown in Figures 9 and 10.

Differential Under Voltage Lockout

The LTC4121 monitors the difference between the battery

voltage, VBAT, and the input supply voltage, VIN. If the

difference (VIN – VBAT) falls to ∆VDUVLO, all functions are

disabled and the part is forced into shutdown mode until

(VIN – VBAT) rises above the ∆VDUVLO rising threshold. The

LTC4121-4.2 monitors the VBATSNS and VIN pin voltages

to sense DUVLO condition.

OPERATION

User Selectable Switching Regulator Operating

Frequency

The LTC4121 uses a constant-frequency synchronous

step-down switching regulator architecture to pro-

duce high operating efficiency. The nominal operating

frequency, fOSC, is programmed by pulling the FREQ pin to

either INTVCC or to GND to obtain a switching frequency

of 1.5MHz or 750kHz, respectively. The high operating

frequency allows the use of smaller external components.

Selection of the operating frequency is a trade-off between

efficiency, component size, and margin from the minimum

on-time of the switcher. Operation at lower frequency

improves efficiency by reducing internal gate charge and

switching losses, but requires larger inductance values to

maintain low output ripple. Operation at higher frequency

allows the use of smaller components, but may require

sufficient margin from the minimum on-time at the lowest

duty cycle if fixed-frequency switching is required.

PWM Dropout Detector

If the input voltage approaches the battery voltage, the

LTC4121 may require duty cycles approaching 100%. This

mode of operation is known as dropout. In dropout, the

operating frequency may fall well below the programmed

fOSC value. If the top switch remains on for eight clock

cycles, the dropout detector activates and forces the

bottom switch on for the remainder of that clock cycle

or until the inductor current decays to zero. This avoids

a potential source of audible noise when using ceramic

input or output capacitors and prevents the boost sup-

ply capacitor for the top gate drive from discharging. In

dropout operation, the actual charge current may not be

able to reach the full-scale programmed value. In such a

scenario the analog charge current monitor function does

not represent actual charge current being delivered.

Burst Mode

Operation

At low charge currents, for example during constant-

voltage mode, the LTC4121 automatically enters Burst

Mode operation. In Burst Mode operation the switcher is

periodically forced into standby mode in order to improve

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OPERATION

efficiency. The LTC4121 automatically enters Burst Mode

operation after it exits constant-current (CC) mode and as

the charge current drops below about 80mA. Burst Mode

operation is triggered at lower currents for larger PROG

resistors, and depends on the input supply voltage, the

battery voltage, and the selected inductor. Refer to the Burst

Mode Trigger Current and Typical Burst Mode Waveforms

graphs in the Typical Performance Characteristics section

for more information on Burst Mode operation. Burst Mode

operation has some hysteresis and remains engaged for

battery current up to about 150mA, depending on LSW,VIN

and VBAT. When operating in Burst Mode, the PROG pin

voltage to average charge current relationship is not well

defined. This may cause the CHRG pin to de-assert early

depending on the amplitude of the burst ripple.

Boost Supply Refresh

The BOOST supply for the top gate drive in the LTC4121

switching regulator is generated by bootstrapping the

BOOST flying capacitor to INTVCC whenever the bottom

switch is turned on. This technique provides a voltage of

INTVCC from the BOOST pin to the SW pin. In the event

that the bottom switch remains off for a prolonged period

of time, e.g. during Burst Mode operation, the BOOST

supply may require a refresh. Similar to the PWM dropout

timer, the LTC4121 counts the number of clock cycles

since the last BOOST refresh. When this count reaches

32 the next PWM cycle begins by turning on the bottom

side switch first. This pulse refreshes the BOOST flying

capacitor to INTVCC and ensures that the top-side gate

driver has sufficient voltage to turn on the top side switch

at the beginning of the next cycle.

Operation without an Input Supply or Shaded Panel

When a battery is the only available power source, care

should be taken to eliminate loading of the IN pin. Load

current on IN drains the battery voltage through the body

diode of the top side power switch as VIN falls below VSW.

A diode inserted in series with the solar panel, as shown

on the front page schematic, eliminates this discharge

path. Alternatively, a diode may be placed in series with

the BAT pin (as shown in Figure 8).

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APPLICATIONS INFORMATION

MPPT Programming

The maximum power-point tracking loop is programmed

by selecting a resistive divider from IN to MPPT to GND

as shown in Figure 4. This user programmable voltage

divider (KR) serves to define a fraction of the input voltage

that appears at the MPPT pin:

KR=

MPPT2

RMPPT1 +RMPPT2

MPPT

This fraction of VIN is continuously compared against

a fixed fraction of the open-circuit input voltage that is

stored within the LTC4121. A fixed internal resistive divider

(0.1•VIN) is periodically sampled to compare the open-

circuit input voltage against the user defined fraction of

the loaded input voltage (KR • VIN). On an interval of TMP,

the LTC4121 turns off all charger functions reverting to

STANDBY mode. The LTC4121 then waits for a delay, of

about 36ms, PWMP, after turning off the charge current to

allow the input supply to recover to its open-circuit volt-

age. Finally, the LTC4121 samples the open-circuit input

voltage VOC through a fixed internal divider; KF = 1/10.

After sampling the open-circuit voltage, the LTC4121 turns

on all functions and reverts to normal operation. During

normal operation, the stored 0.1•VOC voltage is compared

against the instantaneous MPPT pin voltage: KR • VIN. If

the MPPT voltage falls below the stored level, the charge

current is reduced to maintain the input voltage. The ratio

of 0.1/KR defines the percentage below the open-circuit

voltage where charge current is reduced to maintain the

maximum input power.

Because MPPT operation involves large changes of input

voltage, it is important to ensure that the programmed

maximum power voltage does not violate minimum input

operating conditions: 4.4V or 160mV above the battery

voltage, whichever is higher.

For example, to select an MPPT set point, VMP, at 75%

of the open-circuit voltage, VOC, select ratio KR using the

following relation:

KR=

75%

0.1

0.75

=0.1333

Using the schematic of Figure 4, this ratio is obtained by

selecting:

RMPPT1 =

1−

75%













75%











•RMPPT2

RMPPT1 = 6.5 • RMPPT2

Using standard 1% resistors, this is obtained with:

RMPPT1 = 787k and RMPPT2 = 121k.

MPPT Error Terms

Uncertainty in programming the MPPT set point is bound

by three error terms: MPPT pin leakage, DAC quantization

error, and the finite offset error in the MPPT error amp. All

error terms are lumped into VMP(OS), with a typical value

of –45mV. This offset at the input to the MPPT error amp

is multiplied by 1/KR when observed at the IN regulation

point, VMP.

For example, with the same KR = 0.1333 (RMPPT1 = 787k

and RMPPT2 = 121k) the –45mV VMP(OS) error gets am-

plified to –45mV/0.1333 = –338mV at VIN from the VMP

set point of 75% of VOC. If VOC is 30V, the minimum VMP

regulation point is about 22.16V, or 73.9% of the open-

circuit voltage.

For solar panel sources, the available power drops off

quickly on the high side, and relatively slowly on the low

side, this is illustrated in the curve in Figure 7. For these

types of sources, it is usually better to err on the low side

when programming the VMP voltage. This is what the

LTC4121 does normally, so most users can simply design

for a VMP voltage at (or just below) the level specified by

the solar panel manufacturer. For more information on

solar panels, refer to the panel’s data sheet.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

Figure 7. Typical 3W Panel Power vs Voltage

PANEL VOLTAGE (V)

POWER (W)

15 25

4121 F07

5 10 20

75°C

50°C

25°C

APPLICATIONS INFORMATION

The maximum input voltage allowed to maintain constant

frequency operation is:

VIN(MAX) =

LOWBAT

fOSC • tMIN(ON)

where VLOWBAT, is the lowest battery voltage where the

switcher is enabled.

Exceeding the minimum on-time constraint does not affect

charge current or battery float voltage, so it may not be

of critical importance in most cases and high switching

frequencies may be used in the design without any fear of

severe consequences. As the sections on Inductor Selection

and Capacitor Selection show, high switching frequencies

allow the use of smaller board components, thus reducing

the footprint of the applications circuit.

Fixed-frequency operation may also be influenced by

dropout and burst mode operation as discussed previously.

Switching Inductor Selection

The primary criterion for switching inductor value selection

in an LTC4121 charger is the ripple current created in that

inductor. Once the inductance value is determined, the

saturation current rating for that inductor must be equal

to or exceed the maximum peak current in the inductor,

IL(PEAK). The peak value of the inductor current is the sum

of the programmed charge current, ICHG, plus one half of

the ripple current, ∆IL. The peak inductor current must

also remain below the current limit of the LTC4121, IPEAK.

IL(PEAK) =ICHG +

∆I

<IPEAK

The current limit of the LTC4121, IPEAK, is at least 585mA

(and at most 1250mA). The typical value of IPEAK is illus-

trated in a graph in the Typical Performance Characteristics,

RSNS Current Limit vs Temperature.

Input Voltage and Minimum On-Time

The LTC4121 maintains constant frequency operation un-

der most operating conditions. Under certain situations with

high input voltage and high switching frequency selected

and a low battery voltage, the LTC4121 may not be able

to maintain constant frequency operation. These factors,

combined with the minimum on-time of the LTC4121,

impose a minimum limit on the duty cycle to maintain

fixed-frequency operation. The on-time of the top switch

is related to the duty cycle (VBAT/VIN) and the switching

frequency, fOSC in Hz:

tON =

BAT

fOSC • VIN

When operating from a high input voltage with a low

battery voltage, the PWM control algorithm may attempt

to enforce a duty cycle which requires an on-time lower

than the LTC4121 minimum, tMIN(ON). This minimum

duty cycle is approximately 18% for 1.5MHz operation

or 9% for 750kHz operation. If this occurs, the charge

current and battery voltage remains in regulation, but the

switching duty cycle may not remain fixed, or the switch-

ing frequency may decreases to an integer fraction of its

programmed value.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

APPLICATIONS INFORMATION

For a given input and battery voltage, the inductor value

and switching frequency determines the peak-to-peak

ripple current amplitude according to the following formula:

∆IL=V

IN −V

BAT

( )

• VBAT

fOSC • V

IN •LSW

Ripple current is typically set to be within a range of 20%

to 40% of the programmed charge current, ICHG. To obtain

a ripple current in this range, select an inductor value us-

ing the nearest standard inductance value available that

obeys the following formula:

LSW ≥VIN(MAX) −VFLOAT

( )

• VFLOAT

fOSC • VIN(MAX) • 30% •ICHG

( )

Then select an inductor with a saturation current rating

greater than IL(PEAK).

Input Capacitor

The LTC4121 charger is biased directly from the input

supply at the VIN pin. This supply provides large switched

currents, so a high-quality, low ESR decoupling capacitor

is recommended to minimize voltage glitches at VIN. Bulk

capacitance is a function of the desired input ripple voltage

(∆VIN), and follows the relation:

CIN(BULK) =

ICHG •

BAT

VIN

∆VIN

(µF)

Input ripple voltages (∆VIN) above 0.01V are not recom-

mended. 10µF is typically adequate for most charger

applications, with a voltage rating of 40V.

The input capacitor also forms a pole with the source

impedance that supplies power to VIN. This R-C network

must settle within the 36ms PWMP period for the LTC4121

to accurately sample the open-circuit voltage at VIN.

Adequate settling is usually achieved in 3 to 5 R-C time

constants. To allow the LTC4121 to correctly sample the

open-circuit voltage, limit CIN to:

CIN < PWMP / (5 • RSOURCE),

where RSOURCE is the impedance of the power source.

For a solar panel this is the impedance of the panel at the

open-circuit voltage. Looking at a panel's I-V curve, the

source impedance is approximated by (VOC – VMP)/IMP.

Typically VMP is about 80% of VOC, so the solar panels

source impedance can be approximated as:

RSOURCE ≈ VOC / (5 • IMP).

Reverse Blocking

When a fully charged battery is suddenly applied to the

BAT pin, a large in-rush current charges the CIN capacitor

through the body diode of the LTC4121 topside power

switch. While the amplitude of this current can exceed

several Amps, the LTC4121 will survive provided the bat-

tery voltage is below about 11V. To completely eliminate

this in-rush current, a blocking P-channel MOSFET should

be placed in series with the BAT pin. When the battery is

the only source of power, this PMOS also serves to de-

crease battery drain current due to any load placed at VIN,

conducted through the body diode of the topside power

switch on the LTC4121. The PMOS body diode shown in

Figure8 serves as the blocking component since CHRG is

high impedance when the battery voltage is greater than

the input voltage. When CHRG pulls low, i.e. during most

of a normal charge cycle, the PMOS is on to reduce power

dissipation. The PMOS requires a forward current rating

equal to the programmed charge current and a reverse

breakdown voltage equal to the programmed float voltage.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

APPLICATIONS INFORMATION

BAT Capacitor and Output Ripple: CBAT

The LTC4121 charger output requires bypass capacitance

connected from BAT to GND (CBAT). A 22µF ceramic ca-

pacitor is required for all applications. In systems where

the battery can be disconnected from the charger output,

additional bypass capacitance may be desired. In this

type of application, excessive ripple and/or low amplitude

oscillations can occur without additional output bulk

capacitance. For optimum stability, the additional bulk

capacitance should also have a small amount of ESR. For

these applications, place a 100µF low ESR non-ceramic

capacitor (chip tantalum or organic semiconductor capaci-

tors such as Sanyo OS-CONs or POSCAPs) from BAT to

GND, in parallel with the 22µF ceramic bypass capacitor,

or use large ceramic capacitors with an additional small

series ESR resistor of less than 1Ω. This additional bypass

capacitance may also be required in systems where the

battery is connected to the charger with long wires. The

voltage rating of all capacitors applied to CBAT must meet

or exceed the battery float voltage.

Boost Supply Capacitor

The BOOST pin provides a bootstrapped supply rail that

provides power to the top gate drivers. The operating volt-

age of the BOOST pin is internally generated from INTVCC

whenever the SW pin pulls low. This provides a floating

voltage of INTVCC above SW that is held by a capacitor

tied from BOOST to SW. A low ESR ceramic capacitor

of 10nF to 33nF is sufficient, with a voltage rating of 6V.

INTVCC Supply and Capacitor

Power for the top and bottom gate drivers and most other

internal circuitry is derived from the INTVCC pin. A low

ESR ceramic capacitor of 2.2µF is required on the INTVCC

pin. The INTVCC supply has a relatively low current limit

(about 20mA) that is dialed back when INTVCC is low to

reduce power dissipation. Do not use the INTVCC voltage

to supply power for any external circuitry except for the

NTCBIAS network. When the RUN pin is above VEN, the

INTVCC supply is enabled, and when INTVCC rises above

UVINTVCC, the charger is enabled.

Figure 8. Reverse Blocking with a P-Channel MOSFET in Series with the BAT Pin

BAT

22µF

10µF

4.7µF

2.2µF

RPROG

RFB1

49.9k

4.99k*

470k

*ADD 4.99k WHEN MAX BAT VOLTAGE APPROACHES 85%

OF VGS LIMIT FOR Si2343.

RFB2

Li-Ion

FBG

GND

CHRG

RUN

INTVCC

VIN

LTC4121 SI2343DS

PROG

BAT

22µF

10µF

4.7µF

2.2µF

RPROG

49.9k

470k

Li-Ion

BATSNS

GND

CHRG

RUN

INTVCC

VIN

LTC4121-4.2 SI2343DS

PROG 4121 F08

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

Calculating IC Power Dissipation

The user should ensure that the maximum rated junction

temperature is not exceeded under all operating conditions.

The thermal resistance of the LTC4121 package (θJA) is

54°C/W; provided that the Exposed Pad is in good thermal

contact with the PCB. The actual thermal resistance in the

application will depend on the forced air cooling and other

heat sinking means, especially the amount of copper on

the PCB to which the LTC4121 is attached. The actual

power dissipation while charging is approximated by the

following formula:

PD=VIN −V

BAT

( )

•ITRKL

IN •IIN(SWITCHING)

+RSNS •I2

CHG

+RDSON(TOP) •VBAT









•I2

CHG

+RDSON(BOT) • 1−V

BAT









•I2

CHG

During trickle charge (VBAT < VTRKL) the power dissipation

may be significant as ITRKL is typically 10mA, however

during normal charging the ITRKL term is zero. ITRKL is

also zero if VBAT approaches INTVCC, since ITRKL is sourced

from the INTVCC LDO.

The junction temperature can be estimated using the fol-

lowing formula:

TJ = TA + PD • ΘJA.

where TA is the ambient operating temperature.

APPLICATIONS INFORMATION

PCB Layout

To prevent magnetic and electrical field radiation and

high frequency resonant problems, proper layout of the

components connected to the LTC4121 is essential. For

maximum efficiency, the switch node rise and fall times

should be minimized. The following PCB design priority

list will help insure proper topology. Layout the PCB using

the guidelines listed below in this specific order:

1. VIN input capacitor should be placed as close as possible

to the IN pin with the shortest copper traces possible.

The ground return of the input capacitor should be

connected to a solid ground plane.

2. Place the inductor as close as possible to the SW

pin. Minimize the surface area of the SW pin node.

Make the trace width the minimum needed to support

the programmed charge current, and ensure that the

spacing to other copper traces be maximized to reduce

capacitance from the SW node to any other node.

3. Place the BAT capacitor adjacent to the BAT pin and

ensure that the ground return feeds to the solid ground

plane.

4. Route analog ground (RUN pin divider grounded resistor,

the MPPT pin divider, and INTVCC capacitor ground) to

the solid ground plane.

5. It is important to minimize parasitic capacitance on

the PROG pin. The trace connecting to this pin should

be as short as possible with extra wide spacing from

adjacent copper traces.

6. Keep the GND capacitance of the MPPT pin to a mini-

mum, and reduce coupling from the MPPT pin to any

of the switching pins (SW, BOOST, and CHGSNS) by

routing the MPPT trace away from these signals.

Maximize the copper area connected to the exposed pad.

Place via connections directly under the exposed pad to

connect a large copper ground plane to the LTC4121 to

improve heat transfer.

Example PCB layout files of the LTC4121 are available at

the following link:

http://www.linear.com/product/LTC4121#demoboards.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

APPLICATIONS EXAMPLES

Design Example 1

Consider the design example, shown in Figure 14 on the

last page, for the LTC4121-4.2. Input power is from a

solar panel that has an open-circuit voltage VOC = 21.6V,

and maximum power voltage VMP = 17V, or 79% of the

open-circuit voltage. The battery float voltage is 4.2V, and

the desired charge current is 400mA. The application has

a minimum battery voltage of 2.5V.

There is no requirement given for the input voltage where

the LTC4121-4.2 should turn on. Given that the MPPT set

point, VMP, is at 79% of the open-circuit voltage of 21.6V,

one may elect to turn-on the LTC4121-4.2 at an input

voltage anywhere below this set point. A level of 60% of

the open-circuit voltage is selected, or 13V. This selection

results in a RUN pin divider of RRUN1 = 464kΩ, and RRUN2

= 107kΩ. With this RUN pin divider, the LTC4121-4.2 en-

ters DISABLED mode if the input supply drops below 12V.

Now select the MPPT resistive divider to obtain a maxi-

mum power point of 17V. The maximum power point of

17V is at 79% of the open-circuit voltage. This is used to

calculate the ratio

0.1

Select

KR = 0.1/0.79 = 0.1266

This ratio is obtained by selecting RMPPT1 and RMPPT2

following:

RMPPT1 =

(1−0.1266)

0.1266

RMPPT2 =6.9 •RMPPT2

Using standard 1% resistors, select RMPPT1 = 698kΩ and

RMPPT2 = 100kΩ to obtain a KR of 0.1253, and an MPPT

set point of 17.24V.

As described in the MPPT Error Terms section, the actual

regulation voltage will vary from the programmed voltage

down to 45mV/KR = 359mV below the programmed voltage.

In this example, the expected regulation voltage is 16.88V

to 17.24V, or 78.2% to 80.1% of the open-circuit voltage.

The switching frequency of 750kHz is selected to achieve

an on-time of 154ns which is greater than tMIN(ON) at the

maximum input supply, and minimum battery voltage of

2.5V.

tON =

2.5V

750kHz • 21.6V

=154.3 >tMIN(ON)

Next, the minimum standard inductance value is found

that maintains an inductor ripple current 30% of ICHG, at

the peak power input voltage of 17V using the following

formula:

LSW >

(17V −4.2V) • 4.2V

750kHz • 17V • (30% • 400mA) =35µH

The next largest standard inductance value is 47µH. This

inductor selection results in a ripple current of 90mA and

peak inductor current IL(PEAK) of:

IL(PEAK) =400mA +

(17V −4.2V) • 4.2V

2 • 750kHz • 17V • 47µH

IL(PEAK) =444mA

The saturation current of the switch inductor needs to be

greater than IL(PEAK).

Now select RPROG for the desired average charge current

during constant-current operation. The nearest standard

1% resistor to satisfy the following relation:

RPROG =

PROG

• 1.227V

400mA

=3.01kΩ

Select CIN = 10µF for the input decoupling capacitor,

achieving an input voltage ripple of 10mV.

∆V

IN =400mA •

4.2V

17V

10µF =10mV

The minimum standard voltage rating for CIN is 50V.

Select CINTVCC = 2.2µF, and CBST = 22nF, and finally the

battery capacitor should be 22µF. The lowest standard

voltage rating for these capacitors is 6V.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

APPLICATIONS EXAMPLES

In this design example, maximum power dissipation is

calculated during trickle charge as:

=(17V −2.5V) • 10mA

+17V • 2.5mA

+0.3Ω• 0.04A2

+0.8Ω•4.2V

17V 0.04A2

+0.5Ω• 1−2.5V

17V









• 0.04A2

=0.19W

This dissipated power results in a junction temperature

rise of:

PD • ΘJA = 0.19W • 54C°/W = 10.2°C

Estimating IIN(SWITCHING) at 2.5mA from the IIN(SWITCHING)

Current vs Input Voltage graph at VIN = 17V, during

regular charging with VBAT > VTRKL, the power dissipation

reduces to:

=17V • 2.5mA

+0.3Ω• 0.4A2

+0.8Ω•4.2V

17V 0.4A2

+0.5Ω• 1−4.2V

17V









• 0.4A2

=0.18W

This dissipated power results in a junction temperature

rise of 9.8°C over ambient.

Design Example 2

Consider the design with a 3.5W or greater solar panel with

a maximum input voltage of VOC = 22.4V and a maximum

power voltage of VMP = 18V or 80.3% of the open-circuit

voltage. The minimum battery voltage is 5V, and the float

voltage is 8.2V, with a charge current of 400mA.

The MPPT set point is at 80.3% of the open-circuit volt-

age. So select

KR = 0.1/0.803 = 0.1245

This ratio is obtained by selecting RMPPT1 and RMPPT2

following:

RMPPT1 =

(1−0.1245)

0.1245

RMPPT2 =7.03 •RMPPT2

Using standard 1% resistors, select RMPPT1 = 715kΩ and

RMPPT2 = 102kΩ to obtain a KR of 0.1248 and nominal

MPPT set point of 17.94V. Including the effect of MPPT

error terms, the expected MPPT regulation voltage will

vary between 17.58V to 17.94V or 78.5% to 80.1% of the

open-circuit voltage.

Next, the external feedback divider, RFB1/RFB2, is found

using standard 1% values listed in Table 2.

RFB1 = 2.05MΩ

RFB2 = 845kΩ

With these resistors, and including the resistance of the

FBG pin, the battery float voltage is 8.22V.

Select the RUN pin divider to turn on the charger when

the solar-cell output reaches 14.7V. This is obtained by

selecting RRUN1 = 536kΩ, and RRUN2 = 107kΩ. This selec-

tion turns off the charger if the input falls below 13.52V.

The switching frequency is selected at 1.5MHz which meets

the minimum on-time requirement for battery voltages

as low as 5V.

tON =

1.5MHz • 17.94V

=186ns >tMIN(ON)

The minimum standard inductance value for a 30% ripple

current is

LSW >

(17.94V −8.2V) • 8.2V

1.5MHz • 17.94V • (30% • 400mA) =24.8µH

The nearest standard inductor value greater than this is

33µH. With an inductor of 33µH, the peak inductor current

is 445mA and the ripple current amplitude, ∆IL, is 90mA.

Select an inductor with a saturation current greater than

the peak inductor current.

Select RPROG = 3.01k, as the nearest standard 1% value

to provide a charge current of 403mA during constant-

current operation.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

Select a 50V rated capacitor for CIN = 10µF to achieve an

input voltage ripple of 10mV. And select 6V rated capaci-

tors for CINTVCC = 2.2µF, CBOOST = 22nF, and a 10V rated

CBAT = 22µF.

Due to the large float voltage diode D7 is placed in series

with the BAT pin to prevent exceeding the ABS MAX cur-

rent rating on the RSNS resistor in the event that a fully

charged battery may be connected.

In this design example, maximum power dissipation is

calculated during trickle charge with the following as-

sumptions: VBAT = 5.7V, VIN is 19V, and IIN(SWITCHING) is

estimated from the IIN(SWITCHING) Current vs Input Voltage

graph in the Typical Performance Characteristics section

at VIN = 19V and FREQ = INTVCC as 4mA.

=19V • 4mA

+0.3Ω• 0.04A2

+0.8Ω•5.7V

19V 0.04A2

+0.5Ω• 1−5.7V

19V









• 0.04A2

=77mW

APPLICATIONS EXAMPLES

This dissipated power results in a junction temperature

rise of:

PD • ΘJA = 0.077W • 54°C/W = 4.2°C

During regular charging with VBAT = 8.2V, and assuming

VIN is at the MPPT voltage of 17.94V, the power dissipa-

tion increases to:

=18V • 4mA

+0.3Ω• 0.4A2

+0.8Ω•8.2V

19V 0.4A2

+0.5Ω• 1−8.2V

19V









• 0.4A2

=0.22W

This dissipated power results in a junction temperature

rise of 12°C over ambient.

INTVCC

FREQ

BOOST

CHGSNS

BAT

FBG

NTC

RUN

MPPT

FAULT

LTC4121

BAT54

GND

470k

RRUN1

536k

CIN

10µF

RRUN2

107k

RMPPT2

102k

RMPPT1

715k

RFB1

2.05M

RFB2

845k

CBST

22nF LSW

33µH

10k

PROG

CBAT

22µF

4121 F09

Li-Ion

T = NTHS0805N02N1002F

RPROG

3.01k

CINTVCC

2.2µF

VOC = 22.4V, VMP = 18V INTVCC

VFLOAT = 8.2V

49.9k

470k

SI2343DS

4.7µF

CHRG

Figure 9. Design Example 2 with LTC4121

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

APPLICATIONS EXAMPLES

Design Example 3

Consider the design of a sealed lead acid charger with

temperature compensation of the float voltage. Sealed Lead

Acid batteries require the float voltage be decreased as

cell temperature rises. With the LTC4121 this is achieved

using an NTC thermistor in the feedback pin divider as

shown in Figure 10.

Using the circuit of Figure 10 above, the float voltage

automatically decreases with temperature as shown in

Figure 11. The NTC pin is grounded in this example to

Figure 10. Design Example 3, SLA Charging with LTC4121

disable NTC qualified charging and highlight the float volt-

age programming over a wide temperature range. With an

NTC pin network connected, as in example 1 or example 4,

the charger would be disabled below 0°C or above 40°C.

The sealed lead acid charger of example 3 is configured

to charge from a variable supply that can range from 6.2V

up to 40V. The switch frequency is selected at 750kHz to

meet minimum on time requirements at VBAT = 4.2V. And

a 47µH switch inductor is selected to keep ripple current

below 30% of ICHG at VIN = 40V.

Figure 11. Sealed Lead Acid Float Voltage

INTVCC

BOOST

CHGSNS

BAT

FBG

RUN

MPPT

NTC

FREQ

LTC4121

GND

CIN

10µF

VIN

RMPPT1

10k

RFB1A

866k

RFB1B

464k

CBST

22nF

LSW

47µH

RFB2

698k

RT1

100k

RFB1C

102k

CFF

1nF

PROG

CBAT

22µF

4121 F10

SLA

RT1 = NTHS0402E3104FHT

RPROG

3.01k

CINTVCC

2.2µF

INTVCC

VFLOAT = 6V

–

TEMPERATURE (°C)

–40

5.0

VFLOAT (V)

6.6

6.4

6.2

6.0

5.6

5.8

5.2

5.4

7.0

6.8

–25 –10 205 35

4121 F11

50 95 11065 80 125

NTC = GND

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

Figure 12. Design Example 4, LTC4121 2-Cell Li-Ion Charger with MPPT Tracking for a Resistive Supply

Figure 13. VMP/VOC and IBAT vs VIN(OC)

APPLICATIONS EXAMPLES

Design Example 4

Consider the design of a Li-Ion charger from a resistive

supply. With a resistive supply voltage, the maximum

power point is at 50% of the open-circuit voltage. Program

a 50% peak power point using KR = 0.199 with RMPPT1 =

332k and RMPPT2 = 82.5k. This network keeps the input

voltage at the peak power point for any input resistance

so long as the R-C time constant of RIN • CIN does not

exceed PWMP/5, here CIN is 22µF.

With 100Ω of source impedance, the input voltage regu-

lation loop holds the ratio of (VMP/VIN) at about 49% for

VIN ranging from 9V up to 28.3V. For lower input voltages

than 8.7V, the MPPT set point is below DUVLO when

VBAT = 4.2V. And above 28.3V, the charger attains the full

programmed charge current of 400mA so MPPT regula-

tion lets go. While the LTC4121 regulates VIN, the battery

charge current is automatically scaled to track available

input power. Figure 13 illustrates the circuit performance

measured with VBAT held at 4.0V, showing the ratio of

VMP/VOC and IBAT versus VOC with RIN = 100Ω in series

with the supply.

LSW is sized to maintain ripple current below 30% of ICHG

at VIN = 16V. The FB pin network is programmed to set

VFLOAT = 4.2V. An NTC network is configured to enable

charging when the battery temperature is between 0°C

and 40°C.

INTVCC

BOOST

CHGSNS

BAT

FBG

NTC

RUN

MPPT

LTC4121

GND

CIN

22µF

RMPPT2

82.5k

RIN

RMPPT1

332k

–

RFB1

1.01M

RFB2

1.35M

CBST

22nF

LSW

33µH

FREQ PROG +

CBAT

22µF

4121 F12

T = NTCS0402E3103FHT

RPROG

3.01k

10k

Li-Ion

CINTVCC

2.2µF

VMP INTVCC

VFLOAT = 4.2V

VIN

VIN(OC) (V)

VMP/VOC (%)

IBAT (mA)

100

150

100

250

200

450

350

300

400

4121 F13

15 20 25 30 35 40

VBAT = 4V

RIN = 100Ω

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

PACKAGE DESCRIPTION

Please refer to http://www.linear.com/product/LTC4121#packaging for the most recent package drawings.

3.00 ±0.10

(4 SIDES)

RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS

1.45 ±0.05

(4 SIDES)

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

PIN 1

TOP MARK

(NOTE 6)

0.40 ±0.10

BOTTOM VIEW—EXPOSED PAD

1.45 ± 0.10

(4-SIDES)

0.75 ±0.05 R = 0.115

TYP

0.25 ±0.05

PIN 1 NOTCH R = 0.20 TYP

OR 0.25 × 45° CHAMFER

15 16

0.50 BSC

0.200 REF

2.10 ±0.05

3.50 ±0.05

0.70 ±0.05

0.00 – 0.05

(UD16) QFN 0904

0.25 ±0.05

0.50 BSC

PACKAGE OUTLINE

UD Package

16-Lead Plastic QFN (3mm × 3mm)

(Reference LTC DWG # 05-08-1691 Rev Ø)

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

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.

REVISION HISTORY

REV DATE DESCRIPTION PAGE NUMBER

A 05/15 Clarified device options.

Clarified Note 4.

Modified End-of-Charge Indication section.

Enhanced Reverse Blocking section.

Modified Related Parts list.

20-21

B 11/15 Added Note 5 reference to INTVCC UVLO spec.

Expanded INTVCC Pin Function description.

Enhanced Figure 8.

Enhanced Figure 9.

Enhanced Figure 10.

C 02/16 Modified Figure 1.

Modified Figure 9. Made all GND symbols the same.

Modified Figure 14. Added LTC4070 to Related Parts.

LTC4121/LTC4121-4.2

4121fc

For more information www.linear.com/LTC4121

 LINEAR TECHNOLOGY CORPORATION 2014

LT 0216 REV C • PRINTED IN USA

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com/LTC4121

RELATED PARTS

TYPICAL APPLICATION

Figure 14. Design Example 1 with LTC4121-4.2

INTVCC

BOOST

CHGSNS

BAT

BATSNS

NTC

RUN

MPPT

LTC4121-4.2

CHRG FAULT

GND

470k

RRUN1

464k

CIN

10µF

+RRUN2

107k

10k

RMPPT1

698k

RMPPT1

100k

CINTVCC

2.2µF

CBST

22nF LSW

47µH

FREQPROG

4121 TA02

VOC = 21.6V, VMP = 17V INTVCC

CBAT

22µF

VFLOAT = 4.2V

T+

Li-Ion

T = NTHS0805N02N1002F

RPROG

3.01k

PART NUMBER DESCRIPTION COMMENTS

LT3650-4.1/

LT3650-4.2

Monolithic 2A Switch Mode

Non-Synchronous 1-Cell Li-Ion Battery

Charger

Standalone 4.75V < VIN < 32V (40V Absolute Maximum), 1MHz, 2A Programmable Charge

Current, Timer or C/10 Termination, Small and Few External Components 3mm × 3mm DFN-12

Package “-4.1” for 4.1V Float Voltage Batteries, “-4.2” for 4.2V Float Voltage Batteries.

LT3652HV Power Tracking 2A Battery Charger Input Supply Voltage Regulation Loop for Peak Power Tracking in (MPPT) Solar Applications,

4.95V < VIN < 34V (40V Absolute Maximum), 1MHz, 2A Charge Current, 3.3V < VOUT < 18V.

Timer or C/10 Termination, 3mm × 3mm DFN-12 Package and MSOP-12 Packages.

LTC4070 Li-Ion/Polymer Shunt Battery Charger Low 450nA Operating Current, 50mA Internal Shunt Current (500mA with External PFET)

LTC4071 Li-Ion/Polymer Shunt Battery Charger

System with Low Battery Disconnect

Integrated Pack Protection, < 10nA Low Battery Disconnect Protects Battery from

Over-Discharge. Low Operating Current (550nA), 1% Float Voltage Accuracy Over Full

Temperature and Shunt Current Range, 50mA Maximum Internal Shunt Current, Pin Selectable

Float Voltages: 4.0V, 4.1V, 4.2V. Ultralow Power Pulsed NTC Float Conditioning for Li-Ion/

Polymer Protection, 8-Lead (2mm × 3mm) DFN and MSOP.

LTC4065/

LTC4065A

Standalone Li-Ion Battery Charger in

2mm × 2mm DFN

4.2V ±0.6% Float Voltage, Up to 750mA Charge Current; “A” Version Has /ACPR Function.

2mm × 2mm DFN Package.

LTC4079 60V 250mA Multi-Chemistry Linear

Battery Charger

2.7V – 60V Input Voltage range, 1.2V – 60V Adjustable Battery Voltage Range and 10mA

– 250mA Charge Current Range. Low 4µA Quiescent Current. Input Voltage and Thermal

Regulation. 10-pin 3mm x 3mm DFN package.

LTC4015 Multi-Chemistry Buck Battery Charger

Controller with Digital Telemetry System

Multi-Chemistry Li-Ion/Polymer, LiFePO4, or Lead-Acid Battery Charger with Termination, Digital

Telemetry System Monitors VBAT, IBAT, RBAT,NTC Ratio (Battery Temperature), VIN, IIN, VSYSTEM,

Die Temperature, Coulomb Counter and Integrated 14-Bit ADC, Wide Charging Input Voltage

Range: 4.5V to 35V, Wide Battery Voltage Range: Up to 35V, 5mm × 7mm QFN-38 Package

LTC4020 55V Buck-Boost Multi-Chemistry Battery

Charger

Wide Voltage Range: 4.5V to 55V Input, Up to 55V Output (60V Absolute Maximums),

Synchronous Buck-Boost DC/DC Controller, Li-Ion and Lead-Acid Charge Algorithms, Input

Voltage Regulation for High Impedance Input Supplies and Solar Panel Peak Power Operation,

Low Profile (0.75mm) 38-Pin 5mm × 7mm QFN Package

LTC4001 2A Synchronous Buck Li-Ion Charger Low Power Dissipation, 2A Maximum Charge Current, No External MOSFETs, Sense Resistor

or Blocking Diode Required, Programmable Charge Termination Timer, Preset 4.2V Float

Voltage with ±0.5% Accuracy, Low Profile 16-Lead (4mm × 4mm) QFN Package