LTC4413EDD-2#PBF - ANALOG DEVICES

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

Typical applicaTion

FeaTures

applicaTions

DescripTion

Dual 2.6A, 2.5V to 5.5V

Fast Ideal Diodes

in 3mm × 3mm DFN

The LT C

4413-1 and LTC4413-2 each contain two mono-

lithic ideal diodes, each capable of supplying up to 2.6A

from input voltages between 2.5V and 5.5V. The ideal

diodes use a 100mΩ P-channel MOSFET to independently

connect INA to OUTA and INB to OUTB. During normal

forward operation, the voltage drops across each of

these diodes are regulated to as low as 18mV. Quiescent

current is less than 80µA for diode currents up to 1A. If

either of the output voltages exceeds its respective input

voltage, that MOSFET is turned off and less than 1µA of

reverse current flows from OUT to IN. Maximum forward

current in each MOSFET is limited to a constant 2.6A and

internal thermal limiting circuits protect the part during

fault conditions. An internal overvoltage protection sensor

detects when a voltage exceeds the LTC4413-2 absolute

maximum voltage tolerance.

Two active-high control pins independently turn off the two

ideal diodes contained within the LTC4413-1/LTC4413-2.

When the selected channel is reverse biased, or the

LTC4413-1/LTC4413-2 is put into low power standby, the

status signal is pulled low by an 11µA open drain.

The LTC4413-1/LTC4413-2 are housed in a 10-lead 3mm

× 3mm DFN package.

L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and

ThinSOT and PowerPath are trademarks of Analog Devices, Inc. All other trademarks are the

property of their respective owners.

n 2-Channel Ideal Diode OR’ing or Load Sharing

n Low Loss Replacement for PowerPath™ OR’ing

Diodes

n Fast Response Replacement for LTC4413

n Low Forward On-Resistance (140mΩ Max at 3.6V)

n Low Reverse Leakage Current

n Low Regulated Forward Voltage (18mV Typ)

n Overvoltage Protection Sensor with Drive Output for

an External P-Channel MOSFET (LTC4413-2 Only)

n 2.5V to 5.5V Operating Range

n 2.6A Maximum Forward Current

n Internal Current Limit Protection

n Internal Thermal Protection

n Status Output to Indicate if Selected Channel is

Conducting

n Programmable Channel On/Off

n Low Proﬁle (0.75mm) 10-Lead 3mm

3mm DFN

Package

n Battery and Wall Adapter Diode OR’ing in Handheld

Products

n Backup Battery Diode OR’ing

n Power Switching

n USB Peripherals

n Uninterruptable Supplies

INA

IDEAL

FDR8508

LTC4413-2

INB

IDEAL

BAT

ENBA

GND

ENBB

OUTA

OUTB

STAT

470k

4.7µF

441312 TA01a

STAT

STAT IS HIGH WHEN WALL ADAPTER IS

SUPPLYING LOAD CURRENT

OVP IS HIGH WHEN WALL ADAPTER VOLTAGE > 6V

OVP

TO LOAD

VCC

OVI

OVP

10µF

0.1µF

WALL

ADAPTER

INPUT

1Ω

Automatic Switchover from a Battery to a Wall Adapter

LOAD (mA)

700

600

500

400

300

200

100

01500 2500

441312 TA01b

500 1000 2000 3000

POWER LOSS (mW)

1N5817

LTC4413-1

Power Loss vs Load

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

pin conFiguraTion

absoluTe MaxiMuM raTings

INA, INB, OUTA, OUTB, STAT,

ENBA, ENBB Voltage .................................... –0.3V to 6V

OVI, OVP Voltage ........................................–0.3V to 13V

Operating Temperature Range .................–40°C to 85°C

(Note 1)

LTC4413-1 LTC4413-2

TOP VIEW

DD PACKAGE

10-LEAD (3mm × 3mm) PLASTIC DFN

1OUTA

STAT

OUTB

INA

ENBA

GND

ENBB

INB

TJMAX = 125°C, θJA = 43°C/W

EXPOSED PAD (PIN 11) IS SGND, MUST BE SOLDERED TO PCB

TOP VIEW

DD PACKAGE

10-LEAD (3mm × 3mm) PLASTIC DFN

1OUTA

STAT

OVI

OVP

OUTB

INA

ENBA

GND

ENBB

INB

TJMAX = 125°C, θJA = 43°C/W

EXPOSED PAD (PIN 11) IS SGND, MUST BE SOLDERED TO PCB

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

Continuous Power Dissipation ..........................1500mW

(Derate 25mW/°C Above 70°C)

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

LTC4413EDD-1#PBF LTC4413EDD-1#TRPBF LCPP 10-Lead (3mm × 3mm) Plastic DFN –40°C to 85°C

LTC4413EDD-2#PBF LTC4413EDD-2#TRPBF LCPQ 10-Lead (3mm × 3mm) Plastic DFN –40°C to 85°C

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

LTC4413EDD-1 LTC4413EDD-1#TR LCPP 10-Lead (3mm × 3mm) Plastic DFN –40°C to 85°C

LTC4413EDD-2 LTC4413EDD-2#TR LCPQ 10-Lead (3mm × 3mm) Plastic DFN –40°C to 85°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.

orDer inForMaTion

http://www.linear.com/product/LTC4413-1#orderinfo

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

elecTrical characTerisTics

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

VIN, VOUT Operating Supply Range for Channel A

or B

VIN and/or VOUT Must be in This Range for Proper

Operation

l2.5 5.5 V

UVLO UVLO Turn-On Rising Threshold Max (VINA, VINB, VOUTA, VOUTB)l2.45 V

UVLO Turn-Off Falling Threshold Max (VINA, VINB, VOUTA, VOUTB)l1.7 V

IQF Quiescent Current in Forward Regulation,

Measured via GND

VINA = 3.6V, IINA = 100mA, VINB = 0V,

IINB = 0mA (Note 3)

l40 58 µA

IQRIN Current Drawn from or Sourced into IN

When VOUT is Greater than VIN

VIN = 3.6V, VOUT = 5.5V (Note 6) l–1 2.5 4.5 µA

IQRGND Quiescent Current While in Reverse

Turn-Off, Measured via GND

VINA = VINB = 0V, VOUTB = VOUTA = 5.5V,

VSTAT = 0V

28 36 µA

IQROUTB Quiescent Current While in Reverse

Turn-Off. Current Drawn from VOUTA

When OUTB Supplies Chip Power

VINA = VINB = 0V, VOUTA = 3.6V, VOUTB = 5.5V l3.5 6.5 µA

IQOFF Quiescent Current with Both ENBA and

ENBB High

VINA = VINB = 3.6V, VENBA = VENBB = 1V l28 38 µA

VRTO Reverse Turn-Off Voltage (VOUT – VIN) VIN = 3.6V l–5 10 mV

VFWD Forward Voltage Drop (VIN – VOUT)

at IOUT = –1mA

VIN = 3.6V l18 24 mV

RFWD On-Resistance, RFWD Regulation

(Measured as ΔV/ΔI)

VIN = 3.6V, IOUT = –100mA to –500mA (Note 5) 100 140 mΩ

RON On-Resistance, RON Regulation

(Measured as V/I at IIN = 1A)

VIN = 3.6V, IIN = 1A (Note 5) 140 200 mΩ

tON PowerPath Turn-On Time VIN = 3.6V, from ENBA, ENBB Falling to IOUT Ramp

Starting

11 µs

tOFF PowerPath Turn-Off Time VIN = 3.6V, from ENBA, ENBB Rising with IIN =

100mA Falling to 0mA

2 µs

Short-Circuit Response

IOC Current Limit VINA OR B = 3.6V (Note 5) 1.8 A

IQOC Quiescent Current While in Overcurrent

Operation

VINA OR B = 3.6V, IOUT = 1.8A (Note 5) 100 130 µA

STAT Output

ISOFF STAT Off Current Shut Down l–1 0 1 µA

ISON STAT Sink Current VIN > VOUT, VENB > VENBIH, TJ < 135°C, IOUT < IMAX l7 11 15 µA

tS(ON) STAT Pin Current Turn-On Time VIN = 3.6V, from ENBA, ENBB Falling 1.8 µs

tS(OFF) STAT Pin Current Turn-Off Time VIN = 3.6V, from ENBA, ENBB Rising 0.8 µs

ENB Inputs

VENBIH ENB Inputs Rising Threshold Voltage VENBA, VENBB Rising l540 600 mV

VENBIL ENB Inputs Falling Threshold Voltage VENBA, VENBB Falling l400 460 mV

VENBHYST ENB Input Hysteresis VENBHYST = (VENBIH – VENBIL) 90 mV

IENB ENB Inputs Pull-Down Current VOUT < VIN = 3.6V, VENBA < VENBIL, VENBB < VENBIL l2 3 4 µA

The l denotes the specifications which apply over the full operating

temperature range, otherwise specifications are at TA = 25°C. (Notes 2, 6)

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

elecTrical characTerisTics

The l denotes the specifications which apply over the full operating

temperature range, otherwise specifications are at TA = 25°C. (Notes 2, 6)

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

OVI Input (LTC4413-2 Only)

VOVIH OVI Input Rising Threshold Voltage VOVI Rising 5.9 6.2 V

VOVIL OVI Input Falling Threshold Voltage VOVI Falling 5.4 5.6 V

VOVID OVI-OVP Voltage Drop VOVI = 8V, No Load at OVP 100 mV

IOVI OVI Bias Current VOVI = 8V 80 µA

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 LTC4413-1/LTC4413-2 are guaranteed to meet performance

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

operating temperature range are assured by design, characterization and

correlation with statistical process controls.

Note 3: Quiescent current increases with diode current: refer to plot of

IQF vs IOUT.

Note 4: This IC includes overtemperature protection that is intended

to protect the device during momentary overload conditions.

Overtemperature protection will become active at a junction temperature

greater than the maximum operating temperature. Continuous operation

above the specified maximum operating junction temperature may impair

device reliability.

Note 5: Specification is guaranteed by correlation to wafer-level

measurements.

Note 6: Unless otherwise specified, current into a pin is positive and

current out of a pin is negative. All voltages referenced to GND.

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

Typical perForMance characTerisTics

IQF vs ILOAD (Log) IQF vs ILOAD (Linear) IQF vs Temperature

IOC vs Temperature UVLO Thresholds vs Temperature

UVLO Hysteresis vs Temperature

ENBA, ENBB Thresholds vs

Temperature

ENBA, ENBB Hysteresis vs

Temperature

LOAD (mA)

IQF (µA)

120

100

1 100 1000

10000

441312 G01

120°C

–40°C

80°C

40°C

0°C

LOAD (mA)

(µA)

120

500 1000 1500 2000

441312 G02

2500 3000

100

120°C

80°C

40°C

–40°C

0°C

TEMPERATURE (°C)

–40

IQF (µA)

500mA

100mA

1mA

100

120

0 40 80 120

441312 G03

VIN (V)

IQF (µA)

441312 G04

0345

2.5 3.5 4.5 5.5

80 IQF = 1A

IQF = 100mA

IQF vs VIN

TEMPERATURE (°C)

–40

2000

2500

3500

441312 G05

1500

1000

0 40 120

500

3000

(mA)

TEMPERATURE (°C)

–40

2.05

2.10

2.20

441312 G06

2.00

1.95

0 40 120

1.90

1.85

2.15

RISING

FALLING

UVLO THRESHOLDS (V)

TEMPERATURE (°C)

–40

UVLO HYSTERESIS (mV)

150

200

250

20 60 120

441312 G07

100

–20 0 40 80 100

TEMPERATURE (°C)

–40

ENBIH/ENBIL (mV)

100

200

300

400

500

ENBIH

ENBIL

600

0 40 80

120

441312 G08

TEMPERATURE (°C)

–40

ENBA, ENBB HYSETERSIS (mV)

0 40 80 120

441312 G09

100

120

–20 20 60 100

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

RFWD vs VIN and ILOAD = 500mA

Typical perForMance characTerisTics

VFWD and RFWD vs ILOAD (Linear) RFWD and VFWD vs ILOAD (Log)

VFWD vs ILOAD (Log) RFWD vs Temperature

ILEAK vs Temperature at

VREVERSE = 5.5V

ILEAK vs VREVERSE

Response to 800mA Load Step

in <16µs

ENBA, ENBB Turn-On, 30µs to

Turn On with 180mA Load

CH1 = IN 100mV/DIV

4µs/DIV 441312 G17

CH2 OUT

100mV/DIV

CH4 IOUT

200mV/DIV

CH1 INA, INB 1V/DIV

CH3 ENBA, ENBB

1V/DIV

10µs/DIV 441312 G18

CH2 OUTA, OUTB

1V/DIV

CH4 IOUTA, IOUTB

200mV/DIV

VIN (V)

RFWD 500mA (mΩ)

344.5

441312 G10

2.5 3.5 55.5 6

LOAD (mA)

RFWD (mΩ)

FWD

(mV)

100

200

300

400

500

100

150

200

250

500 1000 1500 2000

441312 G11

2500 3000

120°C

80°C

40°C

0°C

–40°C VFWD

RFWD

LOAD (mA)

RFWD (mΩ)

FWD

(mV)

100

200

300

400

500

600

100

150

200

250

300

10 100 1000 10000

441312 G12

120°C

80°C

40°C

0°C

–40°C

RFWD VFWD

LOAD (mA)

VFWD (mV)

100

150

200

250

1 100 1000

10000

441312 G13

120°C

80°C

40°C

0°C

–40°C

TEMPERATURE (°C)

–40

RFWD (mΩ)

100

100mA

500mA

120

0 40 80 120

441312 G14

TEMPERATURE (°C)

0.001

ILEAK (µA)

0.01

–40 40 80

441312 G15

0.0001

0–20 60 10020

120

0.00001

0.1

5.5V

3.6V

VREVERSE (V)

0.00001

LEAK

(µA)

100

2 41 3 5 6

441312 G16

0.1

0.01

0.001

0.0001

120°C

80°C

40°C

0°C

–40°C

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

Typical perForMance characTerisTics

Efficiency vs Load Current Power Loss vs Load Current

Overvoltage Thresholds

vs Temperature (LTC4413-2 Only)

Overvoltage Hysteresis

vs Temperature (LTC4413-2 Only)

OVI Current vs Voltage

(LTC4413-2 Only)

OVI-OVP Voltage Drop

vs OVI Voltage (LTC4413-2 Only)

IQ OVI vs Temperature

(LTC4413-2 Only)

OVI-OVP vs Temperature

(LTC4413-2 Only)

ENBA, ENBB Turn-Off, 2µs to

Disconnect IN from 180mA Load

CH1 INA, INB 1V/DIV

CH3 ENBA, ENBB

1V/DIV

4µs/DIV 441312 G19

CH2 OUTA, OUTB

1V/DIV

CH4 IINA, IINB

100mV/DIV

LOAD (mA)

EFFICIENCY (%)

100

1 100 1000 10000

441312 G20

120°C

80°C

40°C

0°C

–40°C

LOAD (mA)

POWER LOSS (mW)

1000

100 10 1000

10000

441312 G21

100

120°C

80°C

40°C

0°C

–40°C

TEMPERATURE (°C)

–40

5.8

6.0

6.4

441312 G22

5.6

5.4

0 40 120

5.2

5.0

6.2

OVPIH/OVPIL (V)

OVP RISING

OVP FALLING

TEMPERATURE (°C)

–40

OVP HYSTERESIS (mV)

200

250

300

120

441312 G23

150

100

0040 80

400

350

VOVI (V)

100

140

6 10

441312 G24

2 4 8 12

120

IOVI (µA)

TA = 25°C

OVI (V)

6 10

441312 G25

2 4 8 12

OVI-OVP (V)

TA = 25°C

TEMPERATURE (°C)

–40

IQ OVI (µA)

100

120

140

120

441312 G26

0040 80

180

160 IQ OVI = 13V

IQ OVI = 6.5V

TEMPERATURE (°C)

–40

OVI-OVP (mV)

120

441312 G27

0040 80

–20 20 60 100

160

100

140

VOHOVP = 13V

VOHOVP = 6.5V

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

pin FuncTions

INA (Pin 1): Primary Ideal Diode Anode and Positive Power

Supply for LTC4413-1/LTC4413-2. Bypass INA with a ce-

ramic capacitor of at least 1µF. (Series 1Ω snub resistors

and higher valued capacitances are recommended when

large inductances are in series with this input.) This pin

can be grounded when not used. Limit slew rate on this

pin to less than 2.5V/µs.

ENBA (Pin 2): Enable Low for Diode A. Pull this pin high to

shut down this power path. Tie to GND to enable. Refer to

Table 1 for mode control functionality. This pin can be left

floating, a weak (3.5µA) pull-down internal to LTC4413-1/

LTC4413-2 is included.

GND (Pin 3): Power Ground for the IC.

ENBB (Pin 4): Enable Low for Diode B. Pull this pin high to

shut down this power path. Tie to GND to enable. Refer to

Table 1 for mode control functionality. This pin can be left

floating, a weak (3.5µA) pull-down internal to LTC4413-1/

LTC4413-2 is included.

INB (Pin 5): Secondary Ideal Diode Anode and Positive

Power Supply for LTC4413-1/LTC4413-2. Bypass INB

with a ceramic capacitor of at least 1µF. (Series 1Ω snub

resistors and higher valued capacitances are recommended

when large inductances are in series with this input.) This

pin can be grounded when not used. Limit slew rate on

this pin to less than 2.5V/µs.

OUTB (Pin 6): Secondary Ideal Diode Cathode and Output

of the LTC4413-1/LTC4413-2. Bypass OUTB with a high

(1mΩ min) ESR ceramic capacitor of at least 4.7µF. This

pin must be left floating when not in use. Limit slew rate

on this pin to less than 2.5V/µs.

OVP (Pin 7, LTC4413-2 Only): Drive Output for an Exter-

nal OVP Switch PMOS Transistor (To Inhibit Overvoltage

Wall Adapter Voltages from Damaging Device.) During

overvoltage conditions, this output will remain high so

long as an overvoltage condition persists. This pin must

be left floating when not in use.

OVI (Pin 8, LTC4413-2 Only): Sense Input for Overvoltage

Protection Block. This pin can be left floating or grounded

when not used.

STAT (Pin 9): Status Condition Indicator. Weak (11µA)

pull-down current output. When terminated, high indicates

diode conducting. Refer to Table 2 for the operation of this

pin. This pin can also be left floating or grounded.

OUTA (Pin 10): Primary Ideal Diode Cathode and Output

of the LTC4413-1/LTC4413-2. Bypass OUTA with a high

(1mΩ min) ESR ceramic capacitor of at least 4.7µF. This

pin must be left floating when not in use. Limit slew rate

on this pin to less than 2.5V/µs.

SGND (Exposed Pad Pin 11): Signal Ground. This pin

must be soldered to PCB ground to provide both electri-

cal contact to ground and good thermal contact to PCB.

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

block DiagraM

–

1 10

–

OVER CURRENT

INA

ENBA

–

VOFF

AENA

VGATEA

AENA

OVER TEMP

OUTA

STAT

+–

0.5V ENA

3GND

BENA

11µA

3µA

OVER TEMP

STB

UVLO

ENA

ENB

OUTA (MAX)

OUTB (MAX)

–

5 6

–

ENB

OVER CURRENT

INB

4ENBB

–

VOFF

BENA

VGATEB

OUTB

OVI

441312 BD

LTC4413-2 ONLY

OVERVOLTAGE PROTECTION

OVP

+–

0.5V

–

3µA

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

operaTion

The LTC4413-1/LTC4413-2 are described with the aid of the

Block Diagram. Operation begins when the power source at

VINA or VINB rises above the undervoltage lockout (UVLO)

voltage of 2.4V and the corresponding control pin ENBA or

ENBB is low. If only the voltage at the VINA pin is present,

the internal power source (VDD) is supplied from the VINA

pin. The amplifier (A) pulls a current proportional to the

difference between VINA and VOUTA from the gate (VGATEA)

of the internal PFET (PA), driving this gate voltage below

VINA. This turns on PA. As VOUTA pulls up to a forward

voltage drop (VFWD) of 15mV below VINA, the LTC4413

regulates VGATEA to maintain the small forward voltage

drop. The system is now in forward regulation and the

load at VOUTA is powered from the supply at VINA. As the

load current varies, VGATEA is controlled to maintain VFWD

until the load current exceeds the transistor’s (PA) ability

to deliver the current as VGATEA approaches GND. At this

point, the PFET behaves as a fixed resistor, RON, whereby

the forward voltage increases slightly with increased load

current. As the magnitude of IOUT increases further, (such

that ILOAD > IOC) the LTC4413-1/LTC4413-2 fixes the load

current to the constant value IOC to protect the device.

The characteristics for parameters RFWD, RON, VFWD and

IOC are specified with the aid of Figure 1, illustrating the

LTC4413-1/LTC4413-2 forward voltage drop versus that

of a Schottky.

If another supply is provided at VINB, the LTC4413-1/

LTC4413-2 likewise regulate the gate voltage on PB to

maintain the output voltage, VOUTB, just below the input

voltage VINB. If this alternate supply, VINB, exceeds the

voltage at VINA, the LTC4413-1/LTC4413-2 selects this

input voltage as the internal supply (VDD). This second

ideal diode operates independently of the first ideal diode

function.

When an alternate power source is connected to the load

at VOUTA (or VOUTB), the LTC4413-1/LTC4413-2 sense the

increased voltage at VOUTA, and amplifier A increases the

voltage VGATEA, reducing the current through PA. When

VOUTA is higher than VINA + VRTO, VGATEA will be pulled up

to VDD, turning off PA. The internal power source for the

LTC4413-1/LTC4413-2 (VDD) then diverts to draw current

from the VOUTA pin, only if VOUTA is larger than VINB (or

VOUTB). The system is now in the reverse turn-off mode.

Power to the load is being delivered from an alternate

supply, and only a small current (ILEAK) is drawn from or

sourced to VINA to sense the potential at VINA.

When the selected channel of the LTC4413-1/LTC4413-2

is in reverse turn-off mode or both channels are disabled,

the STAT pin sinks 11µA of current (ISON) if connected.

Channel selection is accomplished using the two pins,

ENBA and ENBB. For example with channel A, when the

ENBA input is asserted (high), PA has its gate voltage

pulled to VDD, turning off PA. A 3.5µA pull-down current

on the ENBA, ENBB pins ensures a low level at these

inputs if left floating.

FORWARD VOLTAGE (V)

CURRENT (A)

IFWD

LTC4413-1

LT C 4413-2

SLOPE: 1/RON

VFWD

441312 F01

SLOPE: 1/RFWD

1N5817

Figure 1. The LTC4413 vs the 1N5817

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

operaTion

Overcurrent and Short-Circuit Protection

During an overcurrent condition, the output voltage droops

as the load current exceeds the amount of current that the

LTC4413-1/LTC4413-2 can supply. At the time when an

overcurrent condition is first detected, the LTC4413-1/

LTC4413-2 take some time to detect this condition before

reducing the current to IOC. For short durations after the

output is shorted, until TOC, the current may exceed IOC.

The magnitude of this peak short-circuit current can be

large depending on the load current immediately before

the short-circuit occurs. During overcurrent operation, the

power consumption of the LTC4413-1/LTC4413-2 is large,

and is likely to cause an overtemperature condition as the

internal die temperature exceeds the thermal shutdown

temperature.

Overtemperature Protection

The overtemperature condition is detected when the

internal die temperature increases beyond 150°C. An

overtemperature condition will cause the gate amplifiers

(A and B) as well as the two P-channel MOSFETs (PA

and PB) to shut off. When the internal die temperature

cools to below 140°C, the amplifiers turn on and the

LTC4413-1/LTC4413-2 reverts to normal operation. Note

that prolonged operation under overtemperature conditions

degrades reliability.

Overvoltage Protection (LTC4413-2 Only)

An overvoltage condition is detected whenever the over-

voltage input (OVI) pin is pulled above 6V. The condition

persists until the OVI voltage falls below 5.6V. The overvolt-

age protection (OVP) output is low unless an overvoltage

condition is detected. If an overvoltage condition is present,

the OVP output is pulled up to the voltage applied to the

OVI input. This output signal can be used to enable or

disable an external PFET that is placed between the input

that is the source of the excessive voltage and the input to

the LTC4413-2, thus eliminating the potential damage that

may occur to the LTC4413-2 if its input voltage exceeds

the absolute maximum voltage of 6V. See the Applica-

tions Information section

Dual Battery Load Sharing with

Automatic Switchover to a Wall Adapter with Overvoltage

Protection

for more information on using the overvoltage

protection function within the LTC4413-2.

Channel Selection and Status Output

Two active-high control pins independently turn off the two

ideal diodes contained within the LTC4413-1/LTC4413-2,

controlling the operation mode as described by Table 1.

When the selected channel is reverse biased, or the

LTC4413-1/LTC4413-2 is put into low power standby, the

status signal indicates this condition with a low voltage.

Table 1. Mode Control

ENBA ENBB STATE

Low Low Diode’OR NB: The Two Outputs are not Connected

Internal to the Device

Low High Diode A = ENABLED, Diode B = DISABLED

High Low Diode A = DISABLED, Diode B = ENABLED

High High All Off (Low Power Standby)

The function of the STAT pin depends on the mode that

has been selected. Table 2 describes the STAT pin output

current, as a function of the mode selected as well as the

conduction state of the two diodes.

Table 2. STAT Output Pin Function

ENBA ENBB CONDITIONS STAT

Low Low Diode A Forward Bias,

Diode B Forward Bias

ISNK = 0µA

Diode A Forward Bias,

Diode B Reverse Bias

ISNK = 0µA

Diode A Reverse Bias,

Diode B Forward Bias

ISNK = 11µA

Diode A Reverse Bias,

Diode B Reverse Bias

ISNK = 11µA

Low High Diode A Forward Bias,

Diode B Disabled

ISNK = 0µA

Diode A Reverse Bias,

Diode B Disabled

ISNK = 11µA

High Low Diode A Disabled,

Diode B Forward Bias

ISNK = 0µA

Diode A Disabled,

Diode B Reverse Bias

ISNK = 11µA

High High Diode A Disabled,

Diode B Disabled

ISNK = 11µA

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

applicaTions inForMaTion

Introduction

The LTC4413-1/LTC4413-2 are intended for power control

applications that include low loss diode OR’ing, fully au-

tomatic switchover from a primary to an auxiliary source

of power, microcontroller controlled switchover from

a primary to an auxiliary source of power, load sharing

between two or more batteries, charging of multiple bat-

teries from a single charger and high side power switching.

Dual Battery Load Sharing with Automatic Switchover

to a Wall Adapter with Overvoltage Protection

(LTC4413-2 Only)

An application circuit for dual battery load sharing with

automatic switchover of load from batteries to a wall

adapter is shown in Figure 2. When the wall adapter is not

present, whichever battery has the higher voltage provides

the load current until it has discharged to the voltage of the

other battery. The load is shared between the two batter-

ies according to the capacity of each battery. The higher

capacity battery provides proportionally higher current to

the load. When a wall adapter input is applied, the output

voltage rises as the body diode in MP2 conducts. When

the output voltage is larger than the battery voltages, the

LTC4413 turns off and very little load current is drawn

from the batteries. At this time, the STAT pin pulls down

the gate voltage of MP2, causing it to conduct. This status

signal can be used to provide information as to whether

the wall adapter (or BATB) is supplying the load current.

If the wall adapter voltage exceeds the OVI trip threshold

(VOVIH) then the wall adapter is disconnected via the

external PFET, MP1. The OVI voltage can be monitored

(through a voltage divider if necessary) to determine if

an overvoltage condition is present.

Capacitor C2 is required to dynamically pull up on the

gate of PFET MP1 if a fast edge occurs at the wall adapter

input during a hot plug. In the event that capacitor C2 (or

the gate-to-source of MP1) is precharged below the OVI

rising threshold. When a high voltage spike occurs, the

OVP output cannot guarantee turning off MP1 before the

load voltage exceeds the absolute maximum voltage for

the LTC4413-2. This may occur in the event that the wall

adapter suddenly steps from 5.5V to a much higher value.

In this case, a Zener diode is recommended to keep the

output voltage to a safe level.

Automatic PowerPath Control

Figure 3 illustrates an application circuit for microcon-

troller monitoring and control of two power sources. The

microcontroller’s analog inputs (perhaps with the aid of

a resistor voltage divider) monitor each supply input and

the LTC4413-1 status, and then commands the LTC4413-1

through the two ENBA/ENBB control inputs.

INA

IDEAL

MP1

IRLML6402

MP2

IRLML6402

LTC4413-2

INB

IDEAL

BATB

ENBA

C1: C1206C106K8PAC

C2: C0403C103K8PAC

COUT: C1206C475K8PAC

GND

ENBB

OUTA

OUTB

STAT

COUT

4.7µF

10nF OPTIONAL

6.2V

DFLZ6V2-7

441312 F02

STAT

RSTAT

470k

OVP

TO LOAD

OVI

OVP

BATA

10nF

0.10µF

WALL

ADAPTER

INPUT

JACK R1

1Ω

INA

IDEAL

LTC4413-1

INB

IDEAL

ENBA

GND

ENBB

OUTA

OUTB

STAT STAT

441312 F03

LOAD

10µF

PRIMARY

POWER

SOURCE

AUXILIARY

POWER

SOURCE

1Ω

RSTAT

470k

10µF

4.7µF

1Ω

MICROCONTROLLER

Figure 2 Figure 3

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

Automatic Switchover from a Battery to an Auxiliary

Supply, or a Wall Adapter with Overvoltage Protection

Figure 4 illustrates an application circuit where the

LTC4413-2 is used to automatically switch over between

a battery, an auxiliary power supply and a wall adapter.

When the battery is supplying load current, OVP is at GND

and STAT is high. If a higher supply is applied to AUX, the

BAT will be disconnected from the load and the load is

powered from AUX. When a wall adapter is applied, the

body diode of MP2 forward biases. When the load voltage

exceeds the AUX (or BAT) voltage, the LTC4413-2 senses

this higher voltage and disconnects AUX (or BAT) from

the load. At the same time it pulls the STAT voltage to

GND, thereby turning on MP2. The load current is now

supplied from the wall adapter. If the wall adapter voltage

exceeds the OVI rising threshold, the OVP voltage rises

and turns off MP1, disconnecting the wall adapter from

the load. The output voltage collapses down to the AUX

(or BAT) voltage and the LTC4413-2 reconnects the load

to AUX (or BAT).

applicaTions inForMaTion

Capacitor C2 is required to dynamically pull up on the

gate of MP1 if a fast edge occurs at the wall adapter input

during a hot plug. If the wall adapter voltage is precharged

when an overvoltage spike occurs, the OVP voltage may

not discharge capacitor C2 in time to protect the output.

In this event, a Zener diode is recommended to protect

the output node until MP1 is turned off.

Multiple Battery Charging

Figure 5 illustrates an application circuit for automatic dual

battery charging from a single charger. Whichever battery

has the lower voltage will receive the larger charging cur-

rent until both battery voltages are equal, then both are

charged. While both batteries are charging simultaneously,

the higher capacity battery gets proportionally higher cur-

rent from the charger. For Li-Ion batteries, both batteries

achieve the float voltage minus the forward regulation

voltage of 15mV. This concept can apply to more than

two batteries. The STAT pin provides information as to

when the battery at OUTA is being charged. For intelligent

control, the ENBA/ENBB input pins can be used with a

microcontroller as shown in Figure 3.

INA

IDEAL

MP1

IRLML6402

MP2

IRLML6402

LTC4413-2

INB

IDEAL

ENBA C1: C1206C106K8PAC

C2: C0403C103K8PAC

COUT: C1206C475K8PAC

GND

ENBB

OUTA

AUX

470k

OUTB

STAT

COUT

4.7µF

10nF

441312 F04

STAT

RSTAT

560k

OVP

TO LOAD

OVI

OVP

BAT

0.10µF

WALL

ADAPTER

INPUT

JACK R1

1Ω

OPTIONAL

6.2V

DFLZ6V2-7

10nF

INA

IDEAL

LTC4413-1

INB

IDEAL

ENBA

GND

ENBB

OUTA

STAT IS HIGH

WHEN BAT1 IS

CHARGING

VCC

9470k

BAT2

OUTB

STAT

BATTERY

CHARGER

INPUT

441312 F05

LOAD

BAT1

Figure 4 Figure 5

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

applicaTions inForMaTion

Automatic Switchover from a Battery to a Wall

Adapter and Charger with Overvoltage Protection

Figure 6 illustrates the LTC4413-2 performing the function

of automatically switching a load over from a battery to a

wall adapter while controlling an LTC4059 battery charger.

When no wall adapter is present, the LTC4413-2 connects

the load at OUTA from the Li-Ion battery at INA. In this

condition, the STAT voltage is high, thereby disabling

the battery charger. If a wall adapter of a higher voltage

than the battery is connected to MP1 (but below the OVI

threshold), the load voltage rises as the second ideal di-

ode conducts. As soon as the OUTA voltage exceeds the

INA voltage, the BAT is disconnected from the load and

the STAT voltage falls, turning on the LTC4059 battery

charger and beginning a charge cycle. If a high voltage

wall adapter is inadvertently attached above the OVI rising

threshold, the OVP pin voltage rises, disconnecting both

the LTC4413-2 and the LTC4059 from potentially hazard-

ous voltages. When this occurs, the load voltage collapses

until it is below the BAT voltage causing the STAT voltage

to rise, disabling the battery charger. At the same time,

the LTC4413-2 automatically reconnects the battery to the

load. One major benefit of this circuit is that when a wall

adapter is present, the user may remove the battery and

replace it without disrupting the load.

Capacitor C2 is required to dynamically pull up on the

gate of MP1 if a fast edge occurs at the wall adapter input

during a hot plug. If the wall adapter voltage is precharged

when an overvoltage spike occurs, the OVP voltage may

not discharge capacitor C2 in time to protect the output.

In this event, a Zener diode is recommended to protect

the output node until MP1 is turned off.

INA

IDEAL

LTC4413-2

INB

OVP

OVI

IDEAL

ENBA

ENBB

GND

100k

OPTIONAL

DFLZ6V2-7

OUTA

Li-Ion

RSTAT

560k

OUTB

STAT

441312 F06

LOAD

STAT

COUT

4.7µF

10µF

1µF

10nF

BAT

PROG

GND

ENB

VCC

LTC4059

Li/CC

MP1

IRLML6402

WALL

ADAPTER

INPUT

JACK

Figure 6

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

Soft-Start Overvoltage Protection

In the event that a low power external PFET is used for

the external overvoltage protection device, care must be

taken to limit the power dissipation in the external PFET.

The operation of this circuit is identical to the “Automatic

Switchover from a Battery to a Wall Adapter” application

shown on the first page of this data sheet. Here, however,

the ideal diode from INA to INB is disabled by pulling up

on ENBA whenever an overvoltage condition is detected.

This channel is turned-off using a resistor connected to

OVP along with a 5.6V Zener diode, ensuring the abso-

lute maximum voltage at ENBA is not exceeded during

an overvoltage event. When the overvoltage condition

ends, the OVP voltage drops slowly, depending on the

gate charge of the external PFET. This causes the external

PFET to linger in a high RDS(ON) region where it can dis-

sipate a significant amount of heat depending on the load

current. To avoid dissipating heat in the external PFET

, this

application delays turning on the ideal diode from INA to

OUTA, until the gate voltage of the external PFET drops

below VENBIL, where the external PFET should safely be

out of the high RDS(ON) region. This soft-start scheme can

be used on either channel of the LTC4413-2.

applicaTions inForMaTion

INA

IDEAL

FDR8508

LTC4413-2

INB

IDEAL

BAT

5.6V

ENBA

GND

ENBB

OUTA

OUTB

STAT

RSTAT

470k

COUT

4.7µF

441312 F07

STAT

STAT IS HIGH WHEN WALL ADAPTER IS

SUPPLYING LOAD CURRENT

OVP IS HIGH WHEN WALL ADAPTER

VOLTAGE > 6V

C1: C0805C106K8PAC

C2: C0403C103K8PAC

COUT: C1206C475K8PAC

OVP

TO LOAD

VCC

OVI

OVP

10µF

10nF

OPTIONAL

WALL

ADAPTER

INPUT

1Ω

0.1µF

RENBA

560k

Figure 7

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

3.00 ±0.10

(4 SIDES)

NOTE:

1. DRAWING TO BE MADE A JEDEC PACKAGE OUTLINE M0-229 VARIATION OF (WEED-2).

CHECK THE LTC WEBSITE DATA SHEET FOR CURRENT STATUS OF VARIATION ASSIGNMENT

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

0.40 ±0.10

BOTTOM VIEW—EXPOSED PAD

1.65 ±0.10

(2 SIDES)

0.75 ±0.05

R = 0.125

TYP

2.38 ±0.10

(2 SIDES)

106

PIN 1

TOP MARK

(SEE NOTE 6)

0.200 REF

0.00 – 0.05

(DD) DFN REV C 0310

0.25 ±0.05

2.38 ±0.05

(2 SIDES)

RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS

1.65 ±0.05

(2 SIDES)2.15 ±0.05

0.50

BSC

0.70 ±0.05

3.55

±0.05

PACKAGE

OUTLINE

0.25 ±0.05

0.50 BSC

DD Package

10-Lead Plastic DFN (3mm × 3mm)

(Reference LTC DWG # 05-08-1699 Rev C)

PIN 1 NOTCH

R = 0.20 OR

0.35 × 45°

CHAMFER

package DescripTion

Please refer to http://www.linear.com/product/LTC4413-1#packaging for the most recent package drawings.

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

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 begins at Rev E)

REV DATE DESCRIPTION PAGE NUMBER

E 07/15 Changed GND to SGND in Pin Configuration

Changed VENB to VENBA,B in electrical characteristics

Changed ENB to ENBA,B last two plots

Changed ENB to ENBA,B last plot

Changed ENB to ENBA,B first plot and changed IN to INA,B

Changed exposed pad/SGND label

Added sentence to final paragraph and added A,B references

Changed to ENBA and ENBB on Tables 1 and 2

Added LTC4415 to Related Parts table

F 09/16 Changed y-axis on graph G27 to OVI-OVP 7

G 09/17 Changed MP2 diode connection Figures 2, 4 12, 13

revision hisTory

LTC4413-1/LTC4413-2

441312fg

For more information www.linear.com/LTC4413-1

 LINEAR TECHNOLOGY CORPORATION 2006

LT 0917 REV G • PRINTED IN USA

www.linear.com/LTC4413-1

relaTeD parTs

PART NUMBER DESCRIPTION COMMENTS

LTC1558/LTC1559 Backup Battery Controller with Programmable Output Adjustable Backup Voltage from 1.2V NiCd Button Cell, Includes Boost

Converter

LTC1998 2.5µA, 1% Accurate Programmable Battery Detector Adjustable Trip Voltage/Hysteresis, ThinSOT™

LTC4054 800mA Standalone Linear Li-Ion Battery Charger with

Thermal Regulation in ThinSOT

No External MOSFET, Sense Resistor or Blocking Diode Required,

Charge Current Monitor for Gas Gauging, C/10 Charge Termination

LTC4350 Hot Swappable Load Share Controller Allows N + 1 Redundant Supply, Equally Loads Multiple Power

Supplies Connected in Parallel

LTC4411 2.6A Low Loss Ideal Diode in ThinSOT No External MOSFET, Automatic Switching Between DC Sources,

Simplified Load Sharing

LTC4412/

LTC4412HV

PowerPath Controller in ThinSOT More Efficient than Diode OR’ing, Automatic Switching Between DC

Sources, Simplified Load Sharing, 3V ≤ VIN ≤ 28V, 3V ≤ VIN ≤ 36V

(HV)

LTC4413 Dual 2.6A, 2.5V to 5.5V, Ideal Diodes in 3mm × 3mm DFN Lower Quiescent Current with Slower Response Time

LTC4414 36V, Low Loss PowerPath Controller for Large PFETs Drives Large QG PFETs, Very Low Loss Replacement for Power Supply

O’Ring Diodes, 3.5V to 36V AC/DC Adapter Voltage Range, 8-Lead

MSOP Package

LTC4415 Dual 4A Ideal Diodes with Adjustable Current Limit 1.7V to 5.5V Operating Range, 50mΩ PMOS, Soft-Start, 15mV

Forward Drop, MSOP-16 and 3mm × 5mm DFN-16 Packages

Typical applicaTion

INA

IDEAL

FDR8508

LTC4413-2

INB

IDEAL

BAT

5.6V

ENBA

GND

ENBB

OUTA

OUTB

STAT

RSTAT

470k

COUT

4.7µF

441312 F07

STAT

STAT IS HIGH WHEN WALL ADAPTER IS

SUPPLYING LOAD CURRENT

OVP IS HIGH WHEN WALL ADAPTER

VOLTAGE > 6V

C1: C0805C106K8PAC

C2: C0403C103K8PAC

COUT: C1206C475K8PAC

OVP

TO LOAD

VCC

OVI

OVP

10µF

10nF

OPTIONAL

WALL

ADAPTER

INPUT

1Ω

0.1µF

RENBA

560k

Automatic Switchover from a Battery to a Wall Adapter with Soft-Start Overvoltage Protection