LTC4412ES6#TRMPBF - ANALOG DEVICES

LTC4412

4412fb

For more information www.linear.com/LTC4412

Typical applicaTion

DescripTion

Low Loss PowerPath™

Controller in ThinSOT

The LT C

4412 controls an external P-channel MOSFET to

create a near ideal diode function for power switchover

or load sharing. This permits highly efficient OR’ing of

multiple power sources for extended battery life and low

self-heating. When conducting, the voltage drop across

the MOSFET is typically 20mV. For applications with a

wall adapter or other auxiliary power source, the load is

automatically disconnected from the battery when the

auxiliary source is connected. Tw o or more LTC4412s

may be interconnected to allow load sharing between

multiple batteries or charging of multiple batteries from

a single charger.

The wide supply operating range supports operation

from one to six Li-Ion cells in series. The low quiescent

current (11µA typical) is independent of the load current.

The gate driver includes an internal voltage clamp for

MOSFET protection.

The STAT pin can be used to enable an auxiliary P-channel

MOSFET power switch when an auxiliary supply is

detected. This pin may also be used to indicate to a mi-

crocontroller that an auxiliary supply is connected.

The

control (CTL) input enables the user to force the primary

MOSFET off and the STAT pin low.

The LTC4412 is available in a low profile (1mm) ThinSOT

package.

LTC4412 vs Schottky Diode

Forward Voltage Drop

FeaTures

applicaTions

n Very Low Loss Replacement for Power Supply

OR’ing Diodes

n Minimal External Components

n Automatic Switching Between DC Sources

n Simpliﬁes Load Sharing with Multiple Batteries

n Low Quiescent Current: 11µA

n 3V to 28V AC/DC Adapter Voltage Range

n 2.5V to 28V Battery Voltage Range

n Reverse Battery Protection

n Drives Almost Any Size MOSFET for Wide Range of

Current Requirements

n MOSFET Gate Protection Clamp

n Manual Control Input

n Low Proﬁle (1mm) ThinSOT™ Package

n Cellular Phones

n Notebook and Handheld Computers

n Digital Cameras

n USB-Powered Peripherals

n Uninterruptible Power Supplies

n Logic Controlled Power Switch

Figure 1. Automatic Switchover of Load Between a Battery and a Wall Adapter

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412 COUT

TO LOAD

STATUS OUTPUT

LOW WHEN WALL

ADAPTER PRESENT

470k

4412 F01

VCC

BATTERY

CELL(S)

WALL

ADAPTER

INPUT

FORWARD VOLTAGE (V)

0.02

CURRENT (A)

CONSTANT

RON

4412 F01b

0.5

CONSTANT

VOLTAGE SCHOTTKY

DIODE

LTC4412

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

PowerPath and ThinSOT are trademarks of Linear Technology Corporation. All other trademarks

are the property of their respective owners.

LTC4412

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For more information www.linear.com/LTC4412

pin conFiguraTionabsoluTe MaxiMuM raTings

Supply Voltage (VIN) .................................. –14V to 36V

Voltage from VIN to SENSE ........................ – 28V to 28V

Input Voltage

CTL ........................................................–0.3V to 36V

SENSE .................................................... –14V to 36V

Output Voltage

GATE ..................... –0.3V to the Higher of VIN + 0.3V

or SENSE + 0.3V

STAT ......................................................–0.3V to 36V

Operating Junction Temperature Range

(Note 2) ........................................... – 55°C to 150°C

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

Lead Temperature (Soldering, 10 sec) .................. 300°C

(Note 1)

VIN 1

GND 2

CTL 3

6 SENSE

5 GATE

4 STAT

TOP VIEW

S6 PACKAGE

6-LEAD PLASTIC TSOT-23

TJMAX = 150°C, θJA = 230°C/W

orDer inForMaTion

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

LTC4412ES6#PBF LTC4412ES6#TRPBF LTA 2 6-Lead Plastic TSOT-23 –40°C to 85°C

LTC4412IS6#PBF LTC4412IS6#TRPBF LTA 2 6-Lead Plastic TSOT-23 –40°C to 85°C

LTC4412HS6#PBF LTC4412HS6#TRPBF LTA 2 6-Lead Plastic TSOT-23 –40°C to 150°C

LTC4412MPS6#PBF LTC4412MPS6#TRPBF LTA 2 6-Lead Plastic TSOT-23 –55°C to 150°C

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

LTC4412ES6 LTC4412ES6#TR LTA 2 6-Lead Plastic TSOT-23 –40°C to 85°C

LTC4412IS6 LTC4412IS6#TR LTA 2 6-Lead Plastic TSOT-23 –40°C to 85°C

LTC4412HS6 LTC4412HS6#TR LTA 2 6-Lead Plastic TSOT-23 –40°C to 150°C

LTC4412MPS6 LTC4412MPS6#TR LTA 2 6-Lead Plastic TSOT-23 –55°C to 150°C

Consult LT C Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.

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/

LTC4412

4412fb

For more information www.linear.com/LTC4412

elecTrical characTerisTics

The l denotes the specifications which apply over the full operating

junction temperature range, unless otherwise noted specifications are at TA = 25°C, VIN = 12V, CTL and GND = 0V. Current into a pin is

positive and current out of a pin is negative. All voltages are referenced to GND, unless otherwise specified.

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

VIN,

VSENSE

Operating Supply Range VIN and/or VSENSE Must Be in This Range

for Proper Operation

l2.5 28 V

IQFL Quiescent Supply Current at Low Supply

While in Forward Regulation

VIN = 3.6V. Measure Combined Current

at VIN and SENSE Pins Averaged with

VSENSE = 3.5V and VSENSE = 3.6V (Note 3)

l11 19 µA

IQFH Quiescent Supply Current at High Supply

While in Forward Regulation

VIN = 28V. Measure Combined Current

at VIN and SENSE Pins Averaged with

VSENSE = 27.9V and VSENSE = 28V (Note 3)

l15 26 µA

IQRL Quiescent Supply Current at Low Supply

While in Reverse Turn-Off

VIN = 3.6V, VSENSE = 3.7V. Measure

Combined Current of VIN and SENSE Pins

10 19 µA

IQRH Quiescent Supply Current at High Supply

While in Reverse Turn-Off

VIN = 27.9V, VSENSE = 28V. Measure

Combined Current of VIN and SENSE Pins

16 28 µA

IQCL Quiescent Supply Current at Low Supply

with CTL Active

VIN = 3.6V, VSENSE = 0V, VCTL = 1V 7 13 µA

IQCH Quiescent Supply Current at High Supply

with CTL Active

VIN = 28V, VSENSE = 0V, VCTL = 1V 12 20 µA

ILEAK VIN and SENSE Pin Leakage Currents

When Other Pin Supplies Power

VIN = 28V, VSENSE = 0V; VSENSE = 28V, VIN = 0V

VIN = 14V, VSENSE = –14V; VSENSE = 14V, VIN = –14V

–3 0 1 µA

PowerPath Controller

VFR PowerPath Switch Forward Regulation

Voltage

VIN – VSENSE, 2.5V ≤ VIN ≤ 28V l10 20 32 mV

VRTO PowerPath Switch Reverse Turn-Off

Threshold Voltage

VSENSE – VIN, 2.5V ≤ VIN ≤ 28V l10 20 32 mV

GATE and S TAT Outputs

IG(SRC)

IG(SNK)

GATE Active Forward Regulation

Source Current

Sink Current

(Note 4)

–1

–2.5

–5

µA

VG(ON) GATE Clamp Voltage Apply IGATE = 1µA, VIN = 12V,

VSENSE = 11.9V, Measure VIN – VGATE

6.3 7 7.7 V

VG(OFF) GATE Off Voltage Apply IGATE = –5µA, VIN = 12V,

VSENSE = 12.1V, Measure VSENSE – VGATE

0.13 0.25 V

tG(ON) GATE Turn-On Time VGS < –3V, CGATE = 1nF (Note 5) 110 175 µs

tG(OFF) GATE Turn-Off Time VGS > –1.5V, CGATE = 1nF (Note 6) 13 22 µs

IS(OFF) STAT Off Current 2.5V ≤ VIN ≤ 28V (Note 7) l–1 0 1 µA

IS(SNK) STAT Sink Current 2.5V ≤ VIN ≤ 28V (Note 7) l6 10 17 µA

tS(ON) STAT Turn-On Time (Note 8) 4.5 25 µs

tS(OFF) STAT Turn-Off Time (Note 8) 40 75 µs

CTL Input

VIL CTL Input Low Voltage 2.5V ≤ VIN ≤ 28V l0.5 0.35 V

VIH CTL Input High Voltage 2.5V ≤ VIN ≤ 28V l0.9 0.635 V

ICTL CTL Input Pull-Down Current 0.35V ≤ VCTL ≤ 28V 1 3.5 5.5 µA

HCTL CTL Hysteresis 2.5V ≤ VIN ≤ 28V 135 mV

LTC4412

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For more information www.linear.com/LTC4412

elecTrical characTerisTics

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 LTC4412 is tested under pulsed load conditions such that TJ ≈

TA. The LTC4412E is guaranteed to meet performance speciﬁcations from

0°C to 85°C operating junction temperature range. Speciﬁcations over

the –40°C to 85°C operating junction temperature range are assured by

design, characterization and correlation with statistical process controls.

The LTC4412I is guaranteed over the –40°C to 85°C operating junction

temperature range. The LTC4412MP is tested and guaranteed over the

–55°C to 150°C operating junction temperature range. High junction

temperatures degrade operating lifetimes; operating lifetime is degraded

for junction temperatures greater than 125°C. 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. TJ

is calculated from the ambient temperature TA and power dissipation PD

according to the following formula: TJ = TA + (PD • ΘJA), where ΘJA =

230°C/W for the TSOT-23 package.

Note 3: This results in the same supply current as would be observed with

an external P-channel MOSFET connected to the LTC4412 and operating in

forward regulation.

Note 4: VIN is held at 12V and GATE is forced to 10.5V. SENSE is set at

12V to measure the source current at GATE. SENSE is set at 11.9V to

measure sink current at GATE.

Note 5: VIN is held at 12V and SENSE is stepped from 12.2V to 11.8V to

trigger the event. GATE voltage is initially VG(OFF).

Note 6: VIN is held at 12V and SENSE is stepped from 11.8V to 12.2V to

trigger the event. GATE voltage is initially internally clamped at VG(ON).

Note 7: STAT is forced to VIN – 1.5V. SENSE is set at VIN – 0.1V to

measure the off current at STAT. SENSE is set VIN + 0.1V to measure the

sink current at STAT.

Note 8: STAT is forced to 9V and VIN is held at 12V. SENSE is stepped

from 11.8V to 12.2V to measure the STAT turn-on time deﬁned when ISTAT

reaches one half the measured IS(SNK). SENSE is stepped from 12.2V to

11.8V to measure the STAT turn-off time deﬁned when ISTAT reaches one

half the measured IS(SNK) .

LTC4412

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Typical perForMance characTerisTics

TEMPERATURE (°C)

–75

–25

125

175

(mV)

Supply Voltage

vs Temperature and

4412 G01

= 2.5V

= 28V

TEMPERATURE (°C)

–75

–25

125

175

RTO

(mV)

Supply Voltage

RTO

vs Temperature and

4412 G02

= 2.5V

= 28V

TEMPERATURE (°C)

–75

–25

125

175

0.95

1.00

1.05

1.10

1.15

CURRENT (µA)

Current vs Temperature

Normalized Quiescent Supply

4412 G03

3.6V ≤ V

≤ 28V

TEMPERATURE (°C)

–75

–25

125

175

–0.4

–0.35

–0.3

–0.25

–0.2

CURRENT (µA)

LEAK

vs Temperature

4412 G04

TEMPERATURE (°C)

–75

–25

125

175

6.85

6.95

7.05

VOLTAGE (V)

G(ON)

vs Temperature

4412 G05

8V ≤ V

≤ 28V

GATE

= 1µA

TEMPERATURE (°C)

–75

–25

125

175

0.00

0.10

0.20

0.30

VOLTAGE (V)

G(OFF)

vs Temperature and I

GATE

4412 G06

GATE

= –10µA

GATE

= –5µA

GATE

= 0µA

2.5V ≤ V

≤ 28V

TEMPERATURE (°C)

–75

–25

125

175

100

106

TIME (µs)

G(ON)

vs Temperature

4412 G07

3.6V ≤ V

≤ 28V

GATE

= 1nF

TEMPERATURE (°C)

–75

–25

125

175

12.0

12.5

13.0

TIME (µs)

G(OFF)

vs Temperature

4412 G08

3.6V ≤ V

≤ 28V

GATE

= 1nF

TEMPERATURE (°C)

–75

–25

125

175

10.0

10.5

11.0

11.5

CURRENT (µA)

S(SNK)

vs Temperature and V

4412 G09

STAT

= V

– 1.5V

= 28V

= 2.5V

LTC4412

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pin FuncTions

VIN (Pin 1): Primary Input Supply Voltage. Supplies power

to the internal circuitry and is one of two voltage sense

inputs to the internal analog controller (The other input

to the controller is the SENSE pin). This input is usually

supplied power from a battery or other power source which

supplies current to the load. This pin can be bypassed to

ground with a capacitor in the range of 0.1µF to 10µF if

needed to suppress load transients.

GND (Pin 2): Ground. Provides a power return for all the

internal circuits.

CTL (Pin 3): Digital Control Input. A logical high input

(VIH) on this pin forces the gate to source voltage of the

primary P-channel MOSFET power switch to a small voltage

(VGOFF). This will turn the MOSFET off and no current will

flow from the primary power input at VIN if the MOSFET

is configured so that the drain to source diode does not

forward bias. A high input also forces the STAT pin to

sink 10µA of current (IS(SNK)). If the STAT pin is used to

control an auxiliary P-channel power switch, then a second

active source of power, such as an AC wall adaptor, will

be connected to the load (see Applications Information).

An internal current sink will pull the CTL pin voltage to

ground (logical low) if the pin is open.

STAT (Pin 4): Open-Drain Output Status Pin. When the

SENSE pin is pulled above the VIN pin with an auxiliary

power source by about 20mV or more, the reverse turn-

off threshold (VRTO) is reached. The STAT pin will then go

from an open state to a 10µA current sink (IS(SNK)). The

STAT pin current sink can be used, along with an external

resistor, to turn on an auxiliary P-channel power switch

and/or signal the presence of an auxiliary power source

to a microcontroller.

GATE (Pin 5): Primary P-Channel MOSFET Power Switch

Gate Drive Pin. This pin is directed by the power controller

to maintain a forward regulation voltage (VFR) of 20mV

between the VIN and SENSE pins when an auxiliary power

source is not present. When an auxiliary power source

is connected, the GATE pin will pull up to the SENSE pin

voltage, turning off the primary P-channel power switch.

SENSE (Pin 6): Power Sense Input Pin. Supplies power

to the internal circuitry and is a voltage sense input to the

internal analog controller (The other input to the controller

is the VIN pin). This input is usually supplied power from

an auxiliary source such as an AC adapter or back-up

battery which also supplies current to the load.

block DiagraM

–

1 6

SOURCE

POWER

VOLTAGE/CURRENT

REFERENCE

0.5V

POWER

LINEAR GATE

DRIVER AND

VOLTAGE CLAMP

VIN SENSE

ANALOG CONTROLLER

–

CTL

3.5µA

ON/OFF

10µA

*DRAIN-SOURCE DIODE OF MOSFET

STATUS

OUTPUT

4412 BD

ON/OFF

STAT

VCC

GATE

GND

OUTPUT

TO LOAD

SELECTOR

–

PRIMARY

SUPPLY

–

AUXILIARY

SUPPLY

–

LTC4412

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operaTion

Operation can best be understood by referring to the Block

Diagram, which illustrates the internal circuit blocks along

with the few external components, and the graph that

accompanies Figure 1. The terms primary and auxiliary

are arbitrary and may be changed to suit the application.

Operation begins when either or both power sources are

applied and the CTL control pin is below the input low

voltage of 0.35V (VIL). If only the primary supply is pres-

ent, the Power Source Selector will power the LTC4412

from the VIN pin. Amplifier A1 will deliver a current to

the Analog Controller block that is proportional to the

voltage difference in the VIN and SENSE pins. While the

voltage on SENSE is lower than VIN – 20mV (VFR), the

Analog Controller will instruct the Linear Gate Driver and

Voltage Clamp block to pull down the GATE pin voltage

and turn on the external P-channel MOSFET. The dynamic

pull-down current of 50µA (IG(SNK)) stops when the GATE

voltage reaches ground or the gate clamp voltage. The

gate clamp voltage is 7V (VG(ON)) below the higher of VIN

or VSENSE. As the SENSE voltage pulls up to VIN – 20mV,

the LTC4412 will regulate the GATE voltage to maintain

a 20mV difference between VIN and VSENSE which is also

the VDS of the MOSFET. The system is now in the forward

regulation mode and the load will be powered from the

primary supply. As the load current varies, the GATE volt-

age will be controlled to maintain the 20mV difference. If

the load current exceeds the P-channel MOSFET’s ability

to deliver the current with a 20mV VDS the GATE voltage

will clamp, the MOSFET will behave as a fixed resistor

and the forward voltage will increase slightly. While the

MOSFET is on the STAT pin is an open circuit.

When an auxiliary supply is applied, the SENSE pin will be

pulled higher than the VIN pin through the external diode.

The Power Source Selector will power the LTC4412 from

the SENSE pin. As the SENSE voltage pulls above VIN –

20mV, the Analog Controller will instruct the Linear Gate

Driver and Voltage Clamp block to pull the GATE voltage

up to turn off the P-channel MOSFET. When the voltage

on SENSE is higher than VIN + 20mV (VRTO), the Analog

Controller will instruct the Linear Gate Driver and Voltage

Clamp block to rapidly pull the GATE pin voltage to the

SENSE pin voltage. This action will quickly finish turning

off the external P-channel MOSFET if it hasn’t already

turned completely off. For a clean transition, the reverse

turn-off threshold has hysteresis to prevent uncertainty.

The system is now in the reverse turn-off mode. Power to

the load is being delivered through the external diode and

no current is drawn from the primary supply. The external

diode provides protection in case the auxiliary supply is

below the primary supply, sinks current to ground or is

connected reverse polarity. During the reverse turn-off

mode of operation the STAT pin will sink 10µA of current

(IS(SNK)) if connected. Note that the external MOSFET is

wired so that the drain to source diode will momentarily

forward bias when power is first applied to VIN and will

become reverse biased when an auxiliary supply is applied.

When the CTL (control) input is asserted high, the external

MOSFET will have its gate to source voltage forced to a

small voltage VG(OFF) and the STAT pin will sink 10µA of

current if connected. This feature is useful to allow control

input switching of the load between two power sources

as shown in Figure 4 or as a switchable high side driver

as shown in Figure 7. A 3.5µA internal pull-down current

(ICTL) on the CTL pin will insure a low level input if the pin

should become open.

LTC4412

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For more information www.linear.com/LTC4412

applicaTions inForMaTion

Introduction

The system designer will find the LTC4412 useful in a

variety of cost and space sensitive power control applica-

tions that include low loss diode OR’ing, fully automatic

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 batteries from a

single charger and high side power switching.

External P-Channel MOSFET Transistor Selection

Important parameters for the selection of MOSFETs are

the maximum drain-source voltage VDS(MAX), threshold

voltage VGS(VT) and on-resistance RDS(ON).

The maximum allowable drain-source voltage, VDS(MAX),

must be high enough to withstand the maximum drain-

source voltage seen in the application.

The maximum gate drive voltage for the primary MOSFET is

set by the smaller of the VIN supply voltage or the internal

clamping voltage VG(ON).

A logic level MOSFET is commonly

used, but if a low supply voltage limits the gate voltage, a

sub-logic level threshold MOSFET should be considered.

The maximum gate drive voltage for the auxiliary MOSFET,

if used, is determined by the external resistor connected

to the STAT pin and the STAT pin sink current.

As a general rule, select a MOSFET with a low enough

RDS(ON) to obtain the desired VDS while operating at full

load current and an achievable VGS. The MOSFET nor-

mally operates in the linear region and acts like a voltage

controlled resistor. If the MOSFET is grossly undersized,

it can enter the saturation region and a large VDS may

result. However, the drain-source diode of the MOSFET,

if forward biased, will limit VDS. A large VDS, combined

with the load current, will likely result in excessively high

MOSFET power dissipation. Keep in mind that the LTC4412

will regulate the forward voltage drop across the primary

MOSFET at 20mV if RDS(ON) is low enough. The required

RDS(ON) can be calculated by dividing 0.02V by the load

current in amps. Achieving forward regulation will minimize

power loss and heat dissipation, but it is not a necessity.

If a forward voltage drop of more than 20mV is accept-

able then a smaller MOSFET can be used, but must be

sized compatible with the higher power dissipation. Care

should be taken to ensure that the power dissipated is

never allowed to rise above the manufacturer’s recom-

mended maximum level. The auxiliary MOSFET power

switch, if used, has similar considerations, but its VGS

can be tailored by resistor selection. When choosing the

resistor value consider the full range of STAT pin current

(IS(SNK) ) that may flow through it.

VIN and SENSE Pin Bypass Capacitors

Many types of capacitors, ranging from 0.1µF to 10µF and

located close to the LTC4412, will provide adequate VIN

bypassing if needed. Voltage droop can occur at the load

during a supply switchover because some time is required

to turn on the MOSFET power switch. Factors that determine

the magnitude of the voltage droop include the supply rise

and fall times, the MOSFET’s characteristics, the value of

COUT and the load current. Droop can be made insignificant

by the proper choice of COUT, since the droop is inversely

proportional to the capacitance. Bypass capacitance for

the load also depends on the application’s dynamic load

requirements and typically ranges from 1µF to 47µF. In all

cases, the maximum droop is limited to the drain source

diode forward drop inside the MOSFET.

Caution must be exercised when using multilayer ceramic

capacitors. Because of the self resonance and high Q

characteristics of some types of ceramic capacitors, high

voltage transients can be generated under some start-up

conditions such as connecting a supply input to a hot

power source. To reduce the Q and prevent these transients

from exceeding the LTC4412’s absolute maximum voltage

rating, the capacitor’s ESR can be increased by adding up

to several ohms of resistance in series with the ceramic

capacitor. Refer to Application Note 88.

The selected capacitance value and capacitor’s ESR can

be verified by observing VIN and SENSE for acceptable

voltage transitions during dynamic conditions over the

full load current range. This should be checked with each

power source as well. Ringing may indicate an incorrect

bypass capacitor value and/or too low an ESR.

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applicaTions inForMaTion

VIN and SENSE Pin Usage

Since the analog controller’s thresholds are small (±20mV),

the VIN and SENSE pin connections should be made in a

way to avoid unwanted I • R drops in the power path. Both

pins are protected from negative voltages.

GATE Pin Usage

The GATE pin controls the external P-channel MOSFET

connected between the VIN and SENSE pins when the

load current is supplied by the power source at VIN. In

this mode of operation, the internal current source, which

is responsible for pulling the GATE pin up, is limited to

a few microamps (IG(SRC)). If external opposing leakage

currents exceed this, the GATE pin voltage will reach the

clamp voltage (VGON) and VDS will be smaller. The internal

current sink, which is responsible for pulling the GATE pin

down, has a higher current capability (IG(SNK)). With an

auxiliary supply input pulling up on the SENSE pin and

exceeding the VIN pin voltage by 20mV (VRTO), the device

enters the reverse turn-off mode and a much stronger

current source is available to oppose external leakage

currents and turn off the MOSFET (VGOFF).

While in forward regulation, if the on resistance of the

MOSFET is too high to maintain forward regulation, the

GATE pin will maximize the MOSFET’s VGS to that of the

clamp voltage (VGON). The clamping action takes place

between the higher of VIN or VSENSE and the GATE pin.

Status Pin Usage

During normal operation, the open-drain STAT pin can be

biased at any voltage between ground and 28V regard-

less of the supply voltage to the LTC4412. It is usually

connected to a resistor whose other end connects to a

voltage source. In the forward regulation mode, the STAT

pin will be open (IS(OFF)). When a wall adaptor input or

other auxiliary supply is connected to that input, and the

voltage on SENSE is higher than VIN + 20mV (VRTO), the

system is in the reverse turn-off mode. During this mode of

operation the STAT pin will sink 10µA of current (IS(SNK)).

This will result in a voltage change across the resistor,

depending on the resistance, which is useful to turn on an

auxiliary P-channel MOSFET or signal to a microcontroller

that an auxiliary power source is connected. External

leakage currents, if significant, should be accounted for

when determining the voltage across the resistor when

the STAT pin is either on or off.

Control Pin Usage

This is a digital control input pin with low threshold voltages

(VIL,VIH) for use with logic powered from as little as 1V.

During normal operation, the CTL pin can be biased at any

voltage between ground and 28V, regardless of the supply

voltage to the LTC4412. A logical high input on this pin

forces the gate to source voltage of the primary P-channel

MOSFET power switch to a small voltage (VGOFF). This

will turn the MOSFET off and no current will flow from the

primary power input at VIN if the MOSFET is configured

so that the drain to source diode is not forward biased.

The high input also forces the STAT pin to sink 10µA of

current (IS(SNK)). See the Typical Applications for various

examples on using the STAT pin. A 3.5µA internal pull-

down current (ICTL) on the CTL pin will insure a logical

low level input if the pin should be open.

Protection

Most of the application circuits shown provide some

protection against supply faults such as shorted, low or

reversed supply inputs. The fault protection does not protect

shorted supplies but can isolate other supplies and the load

from faults. A necessary condition of this protection is for

all components to have sufficient breakdown voltages. In

some cases, if protection of the auxiliary input (sometimes

referred to as the wall adapter input) is not required, then

the series diode or MOSFET may be eliminated.

Internal protection for the LTC4412 is provided to prevent

damaging pin currents and excessive internal self heating

during a fault condition. These fault conditions can be

a result of any LTC4412 pins shorted to ground or to a

power source that is within the pin’s absolute maximum

voltage limits. Both the VIN and SENSE pins are capable

of being taken significantly below ground without current

drain or damage to the IC (see Absolute Maximum Voltage

Limits). This feature allows for reverse-battery condition

without current drain or damage. This internal protection

is not designed to prevent overcurrent or overheating of

external components.

LTC4412

4412fb

For more information www.linear.com/LTC4412

Typical applicaTions

Figure 2. Automatic Switchover of Load Between a Battery and a

Wall Adapter with Auxiliary P-Channel MOSFET for Lowest Loss

Figure 3. Automatic Switchover of Load Between

a Battery and a Wall Adapter in Comparator Mode

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412

PRIMARY

P-CHANNEL

MOSFET

COUT

TO LOAD

STATUS OUTPUT

DROPS WHEN A

WALL ADAPTER

IS PRESENT

470k

4412 F02

BATTERY

CELL(S)

WALL

ADAPTER

INPUT

AUXILIARY

P-CHANNEL

MOSFET

*DRAIN-SOURCE DIODE OF MOSFET

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412

BATTERY

CHARGER

P-CHANNEL

MOSFET

COUT

TO LOAD

STATUS OUTPUT

IS LOW WHEN A

WALL ADAPTER

IS PRESENT

470k

*DRAIN-SOURCE DIODE OF MOSFET

4412 F03

VCC

BATTERY

CELL(S)

WALL

ADAPTER

INPUT

Automatic PowerPath Control

The applications shown in Figures 1, 2 and 3 are automatic

ideal diode controllers that require no assistance from a

microcontroller. Each of these will automatically connect

the higher supply voltage, after accounting for certain

diode forward voltage drops, to the load with application

of the higher supply voltage.

Figure 1 illustrates an application circuit for automatic

switchover of a load between a battery and a wall adapter

or other power input. With application of the battery, the

load will initially be pulled up by the drain-source diode

of the P-channel MOSFET. As the LTC4412 comes into

action, it will control the MOSFET’s gate to turn it on and

reduce the MOSFET’s voltage drop from a diode drop to

20mV. The system is now in the low loss forward regula-

tion mode. Should the wall adapter input be applied, the

Schottky diode will pull up the SENSE pin, connected to

the load, above the battery voltage and the LTC4412 will

turn the MOSFET off. The STAT pin will then sink current

indicating an auxiliary input is connected. The battery is

now supplying no load current and all the load current

flows through the Schottky diode. A silicon diode could

be used instead of the Schottky, but will result in higher

power dissipation and heating due to the higher forward

voltage drop.

Figure 2 illustrates an application circuit for automatic

switchover of load between a battery and a wall adapter

that features lowest power loss. Operation is similar

to Figure 1 except that an auxiliary P-channel MOSFET

replaces the diode. The STAT pin is used to turn on the

MOSFET once the SENSE pin voltage exceeds the battery

voltage by 20mV. When the wall adapter input is applied,

the drain-source diode of the auxiliary MOSFET will turn

on first to pull up the SENSE pin and turn off the primary

MOSFET followed by turning on of the auxiliary MOSFE

Once the auxiliary MOSFET has turned on the voltage drop

across it can be very low depending on the MOSFE

T’s

characteristics.

Figure 3 illustrates an application circuit for the automatic

switchover of a load between a battery and a wall adapter

in the comparator mode. It also shows how a battery char-

ger can be connected. This circuit differs from Figure 1

in the way the SENSE pin is connected. The SENSE pin is

connected directly to the auxiliary power input and not the

load. This change forces the LTC4412’s control circuitry

to operate in an open-loop comparator mode. While the

battery supplies the system, the GATE pin voltage will be

forced to its lowest clamped potential, instead of being

regulated to maintain a 20mV drop across the MOSFET.

This has the advantages of minimizing power loss in the

MOSFET by minimizing its RON and not having the influence

of a linear control loop’s dynamics. A possible disadvantage

is if the auxiliary input ramps up slow enough the load

voltage will initially droop before rising. This is due to the

LTC4412

4412fb

For more information www.linear.com/LTC4412

Typical applicaTions

SENSE pin voltage rising above the battery voltage and

turning off the MOSFET before the Schottky diode turns

on. The factors that determine the magnitude of the voltage

droop are the auxiliary input rise time, the type of diode

used, the value of COUT and the load current.

Ideal Diode Control with a Microcontroller

Figure 4 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, monitors each supply input and

commands the LTC4412 through the CTL input. Back-to-

back MOSFETs are used so that the drain-source diode will

not power the load when the MOSFET is turned off (dual

MOSFETs in one package are commercially available).

With a logical low input on the CTL pin, the primary input

supplies power to the load regardless of the auxiliary

voltage. When CTL is switched high, the auxiliary input

will power the load whether or not it is higher or lower

than the primary power voltage. Once the auxiliary is

on, the primary power can be removed and the auxiliary

will continue to power the load. Only when the primary

voltage is higher than the auxiliary voltage will taking

CTL low switch back to the primary power, otherwise

the auxiliary stays connected. When the primary power

is disconnected and VIN falls below VLOAD, it will turn

on the auxiliary MOSFET if CTL is low, but VLOAD must

stay up long enough for the MOSFET to turn on. At a

minimum, COUT capacitance must be sized to hold up

VLOAD until the transition between the sets of MOSFETs

is complete. Sufficient capacitance on the load and low

or no capacitance on VIN will help ensure this. If desired,

this can be avoided by use of a capacitor on VIN to ensure

that VIN falls more slowly than VLOAD.

Load Sharing

Figure 5 illustrates an application circuit for dual battery

load sharing with automatic switchover of load from

batteries to wall adapter. Whichever battery can supply

the higher voltage will provide the load current until it is

discharged to the voltage of the other battery. The load will

then be shared between the two batteries according to the

capacity of each battery. The higher capacity battery will

provide proportionally higher current to the load. When

a wall adapter input is applied, both MOSFETs will turn

off and no load current will be drawn from the batteries.

The STAT pins provide information as to which input is

supplying the load current. This concept can be expanded

to more power inputs.

Figure 4. Microcontroller Monitoring and Control

of Tw o Power Sources

Figure 5. Dual Battery Load Sharing with Automatic

Switchover of Load from Batteries to Wall Adapter

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412

*DRAIN-SOURCE DIODE OF MOSFET

PRIMARY

P-CHANNEL MOSFETS

COUT

TO LOAD

4412 F04

AUXILIARY POWER

SOURCE INPUT

PRIMARY

POWER

SOURCE INPUT

AUXILIARY

P-CHANNEL MOSFETS

470k

MICROCONTROLLER

0.1µF

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412 COUT

TO LOAD

STATUS IS HIGH

WHEN BAT1 IS

SUPPLYING

LOAD CURRENT

WHEN BOTH STATUS LINES ARE

HIGH, THEN BOTH BATTERIES ARE

SUPPLYING LOAD CURRENTS. WHEN

BOTH STATUS LINES ARE LOW THEN

WALL ADAPTER IS PRESENT

STATUS IS HIGH

WHEN BAT2 IS

SUPPLYING

LOAD CURRENT

470k

4412 F05

VCC

BAT1

WALL

ADAPTER

INPUT

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412

470k

VCC

BAT2

*DRAIN-SOURCE DIODE OF MOSFET

LTC4412

4412fb

For more information www.linear.com/LTC4412

Typical applicaTions

Multiple Battery Charging

Figure 6 illustrates an application circuit for automatic

dual battery charging from a single charger. Whichever

battery has the lower voltage will receive the charging

current until both battery voltages are equal, then both

will be charged. When both are charged simultaneously,

the higher capacity battery will get proportionally higher

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

will achieve the float voltage minus the forward regulation

voltage of 20mV. This concept can apply to more than

two batteries. The STAT pins provide information as to

which batteries are being charged. For intelligent control,

the CTL pin input can be used with a microcontroller and

back-to-back MOSFETs as shown in Figure 4. This allows

complete control for disconnection of the charger from

either battery.

High Side Power Switch

Figure 7 illustrates an application circuit for a logic con-

trolled high side power switch.

When the CTL pin is a logical

low, the LTC4412 will turn on the MOSFET. Because the

SENSE pin is grounded, the LTC4412 will apply maximum

clamped gate drive voltage to the MOSFET. When the CTL

pin is a logical high, the LTC4412 will turn off the MOSFET

by pulling its gate voltage up to the supply input voltage

and thus deny power to the load. The MOSFET is con-

nected with its source connected to the power source. This

disables the drain-source diode from supplying voltage

to the load when the MOSFET is off. Note that if the load

is powered from another source, then the drain-source

diode can forward bias and deliver current to the power

supply connected to the VIN pin.

Figure 6. Automatic Dual Battery Charging

from Single Charging Source

Figure 7. Logic Controlled High Side Power Switch

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412

TO LOAD OR

PowerPath

CONTROLLER

TO LOAD OR

PowerPath

CONTROLLER

STATUS IS HIGH

WHEN BAT1 IS

CHARGING

STATUS IS HIGH

WHEN BAT2 IS

CHARGING

470k

4412 F06

VCC

BAT1

BATTERY

CHARGER

INPUT

470k

VCC

BAT2

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412

*DRAIN-SOURCE DIODE OF MOSFET

0.1µF

VIN

GND

CTL

SENSE

GATE

STAT

LTC4412

P-CHANNEL

MOSFET

SUPPLY

INPUT

LOGIC

INPUT

COUT

TO LOAD

4412 F07

*DRAIN-SOURCE DIODE OF MOSFET

0.1µF

LTC4412

4412fb

For more information www.linear.com/LTC4412

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

B 02/15 Added H and MP-grade options. Throughout

(Revision history begins at Rev B)

LTC4412

4412fb

For more information www.linear.com/LTC4412

 LINEAR TECHNOLOGY CORPORATION 2002

LT 0215 REV B • PRINTED IN USA

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com/LTC4412

relaTeD parTs

package DescripTion

PART NUMBER DESCRIPTION COMMENTS

LTC1473 Dual PowerPath Switch Driver Switches and Isolates Sources Up to 30V

LTC1479 PowerPath Controller for Dual Battery Systems Complete PowerPath Management for Tw o Batteries; DC Power Source,

Charger and Backup

LTC1558/LTC1559 Back-Up Battery Controller with Programmable Output Adjustable Backup Voltage from 1.2V NiCd Button Cell,

Includes Boost Converter

1579 300mA Dual Input Smart Battery Back-Up Regulator Maintains Output Regulation with Dual Inputs, 0.4V Dropout at 300mA

LTC1733/LTC1734 Monolithic Linear Li-Ion Chargers Thermal Regulation, No External MOSFET/Sense Resistor

LTC1960 Dual Battery Charger Selector with SPI Complete Dual Battery Charger/Selector System, 36-Lead SSOP

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

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

Connected in Parallel

LTC4410 USB Power Manager in ThinSOT Enables Simultaneous Battery Charging and

Operation of USB Component Peripheral Devices

S6 Package

6-Lead Plastic TSOT-23

(Reference LTC DWG # 05-08-1636)

1.50 – 1.75

(NOTE 4)

2.80 BSC

0.30 – 0.45

6 PLCS (NOTE 3)

DATUM ‘A’

0.09 – 0.20

(NOTE 3) S6 TSOT-23 0302

2.90 BSC

(NOTE 4)

0.95 BSC

1.90 BSC

0.80 – 0.90

1.00 MAX 0.01 – 0.10

0.20 BSC

0.30 – 0.50 REF

PIN ONE ID

NOTE:

1. DIMENSIONS ARE IN MILLIMETERS

2. DRAWING NOT TO SCALE

3. DIMENSIONS ARE INCLUSIVE OF PLATING

4. DIMENSIONS ARE EXCLUSIVE OF MOLD FLASH AND METAL BURR

5. MOLD FLASH SHALL NOT EXCEED 0.254mm

6. JEDEC PACKAGE REFERENCE IS MO-193

3.85 MAX

0.62

MAX

0.95

REF

RECOMMENDED SOLDER PAD LAYOUT

PER IPC CALCULATOR

1.4 MIN

2.62 REF

1.22 REF

S6 Package

6-Lead Plastic TSOT-23

(Reference LTC DWG # 05-08-1636)

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