LTC1624IS8 - Linear Technology

LTC1624

FEATURES

DESCRIPTION

■

N-Channel MOSFET Drive

■

Implements Boost, Step-Down, SEPIC

and Inverting Regulators

■

Wide V

Range: 3.5V to 36V Operation

■

Wide V

OUT

Range: 1.19V to 30V in Step-Down

Configuration

■

1% 1.19V Reference

■

Low Dropout Operation: 95% Duty Cycle

■

200kHz Fixed Frequency

■

Low Standby Current

■

Very High Efficiency

■

Remote Output Voltage Sense

■

Logic-Controlled Micropower Shutdown

■

Internal Diode for Bootstrapped Gate Drive

■

Current Mode Operation for Excellent Line and

Load Transient Response

■

Available in an 8-Lead SO Package

■

Notebook and Palmtop Computers, PDAs

■

Cellular Telephones and Wireless Modems

■

Battery-Operated Digital Devices

■

DC Power Distribution Systems

■

Battery Chargers

TYPICAL APPLICATION

The LTC

1624 is a current mode switching regulator

controller that drives an external N-channel power MOSFET

using a fixed frequency architecture. It can be operated in

all standard switching configurations including boost,

step-down, inverting and SEPIC. Burst Mode

operation

provides high efficiency at low load currents. A maximum

high duty cycle limit of 95% provides low dropout operation

which extends operating time in battery-operated systems.

The operating frequency is internally set to 200kHz, allowing

small inductor values and minimizing PC board space. The

operating current level is user-programmable via an external

current sense resistor. Wide input supply range allows

operation from 3.5V to 36V (absolute maximum).

A multifunction pin (I

/RUN) allows external

compensation for optimum load step response plus

shutdown. Soft start can also be implemented with the

/RUN pin to properly sequence supplies.

Figure 1. High Efficiency Step-Down Converter

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

100pF



470pF



6.8k

D1

MBRS340T3



0.1µF

R2

35.7k

R1

20k

OUT



100µF

10V

× 2

M1

Si4412DY

L1

10µH

SENSE



0.05Ω



22µF

35V

× 2

OUT



3.3V



4.8V TO 28V

1624 F01

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

Burst Mode is a trademark of Linear Technology Corporation.

High Efficiency SO-8

N-Channel Switching

Regulator Controller

APPLICATIONS

LTC1624

ABSOLUTE MAXIMUM RATINGS

Input Supply Voltage (V

).........................36V to –0.3V

Topside Driver Supply Voltage (BOOST)....42V to –0.3V

Switch Voltage (SW)..................................36V to –0.6V

Differential Boost Voltage

(BOOST to SW) ....................................7.8V to –0.3V

SENSE

–

Voltage

< 15V.................................. (V

+ 0.3V) to –0.3V

≥ 15V .......................... (V

+0.3V) to (V

–15V)

/RUN, V

Voltages ............................ 2.7V to – 0.3V

Peak Driver Output Current < 10µs (TG) .................... 2A

Operating Temperature Range

LTC1624CS ............................................ 0°C to 70°C

LTC1624IS......................................... –40°C to 85°C

Junction Temperature (Note 1)............................. 125°C

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

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

PACKAGE/ORDER INFORMATION

ORDER PART

NUMBER

S8 PART MARKING

TOP VIEW



BOOST

TG

SENSE

–



/RUN



GND

S8 PACKAGE

8-LEAD PLASTIC SO

1

2

3

8

7

6

JMAX

= 125°C, θ

= 110°C/ W

LTC1624CS8

LTC1624IS8

1624

1624I

Consult factory for Military grade parts.

ELECTRICAL CHARACTERISTICS

TA = 25°C, VIN = 15V, unless otherwise noted.

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

Main Control Loop

Feedback Current (Note 2) 10 50 nA

Feedback Voltage (Note 2) ●1.1781 1.19 1.2019 V

∆V

LINE REG

Reference Voltage Line Regulation V

= 3.6V to 20V (Note 2) 0.002 0.01 %/V

∆V

LOAD REG

Output Voltage Load Regulation (Note 2)

Sinking 5µA● 0.5 0.8 %

Sourcing 5µA●–0.5 –0.8 %

OVL

Output Overvoltage Lockout 1.24 1.28 1.32 V

Input DC Supply Current (Note 3)

Normal Mode 550 900 µA

Shutdown V

ITH/RUN

= 0V 16 30 µA

ITH/RUN

Run Threshold 0.6 0.8 V

ITH/RUN

Run Current Source V

ITH/RUN

= 0.3V –0.8 –2.5 –5.0 µA

Run Pullup Current V

ITH/RUN

= 1V –50 –160 –350 µA

∆V

SENSE(MAX)

Maximum Current Sense Threshold V

= 1.0V 145 160 185 mV

TG Transition Time

TG t

Rise Time C

LOAD

= 3000pF 50 150 ns

TG t

Fall Time C

LOAD

= 3000pF 50 150 ns

OSC

Oscillator Frequency ●175 200 225 kHz

BOOST

Boost Voltage SW = 0V, I

BOOST

= 5mA, V

= 8V 4.8 5.15 5.5 V

∆V

BOOST

Boost Load Regulation SW = 0V, I

BOOST

= 2mA to 20mA 3 5 %

= T

+ (P

• 110°C/W)

Note 2: The LTC1624 is tested in a feedback loop which servos V

the midpoint for the error amplifier (V

ITH

= 1.8V).

Note 3: Dynamic supply current is higher due to the gate charge being

delivered at the switching frequency. See Applications Information.

The ● denotes specifications which apply over the full operating

temperature range.

LTC1624CS: 0°C ≤ T

≤ 70°C

LTC1624IS: –40°C ≤ T

≤ 85°C

Note 1: T

is calculated from the ambient temperature T

and power

dissipation P

according to the following formula:

LTC1624

TYPICAL PERFORMANCE CHARACTERISTICS

Efficiency vs Load Current

VOUT = 3.3V

LOAD CURRENT (A)

EFFICIENCY (%)

100

95

90

85

80

75

0.001 0.1 1 10

1624 G08

0.01

VOUT = 5V

VIN = 10V

RSENSE = 0.033Ω



LOAD CURRENT (A)

EFFICIENCY (%)

100

95

90

85

80

75

0.001 0.1 1 10

1624 G07

0.01

VOUT = 3.3V

RSENSE = 0.033ΩVIN = 5V

VIN = 10V

Efficiency vs Input Voltage

VOUT = 3.3V

INPUT VOLTAGE (V)

EFFICIENCY (%)

100

95

90

85

80

75

70



15 25

1624 G09

510 20 30

LOAD

= 1A

OUT

= 3.3V

SENSE

= 0.033Ω

LOAD

= 0.1A

Efficiency vs Load Current

VOUT = 5V

Efficiency vs Input Voltage

VOUT = 5V Input Supply Current vs

Input Voltage

Boost Line Regulation

INPUT VOLTAGE (V)

BOOST VOLTAGE (V)

6

5

4

3

2

1

015 25

1624 G04

510 20 30 35

BOOST

= 1mA

= 0V

BOOST LOAD CURRENT (mA)

BOOST VOLTAGE (V)

6

5

4

3

2

1

015 25

1624 G06

510 20 30

= 0V

= 15V

= 5V

Boost Load Regulation

TEMPERATURE (°C)

–40

BOOST VOLTAGE (V)

6.0

5.5

5.0

4.5

4.0 35 85

1624 G15

–15 10 60 110 135

LOAD

= 1mA

LOAD CURRENT (A)

– V

OUT

(V)

0.7

0.6

0.5

0.4

0.3

0.2

0.1

0



1624 G11

00.5 1.0 1.5 2.0 2.5 3.0

SENSE

= 0.033Ω

OUT

DROP OF 5%

INPUT VOLTAGE (V)

SUPPLY CURRENT (µA)

700

600

500

400

300

200

100

015 25

1624 G05

510 20 30 35

SLEEP MODE

= 1.21V

SHUTDOWN

INPUT VOLTAGE (V)

EFFICIENCY (%)

100

95

90

85

80

75

70



15 25

1624 G10

510 20 30

LOAD

= 1A

OUT

= 5V

SENSE

= 0.033Ω

LOAD

= 0.1A

VIN – VOUT Dropout Voltage

vs Load Current

Boost Voltage vs Temperature

LTC1624

TYPICAL PERFORMANCE CHARACTERISTICS

/RUN (V)

1.2

0.8

2.4

00I

OUT(MAX)

OUT

(a) 1624 G01

OUT(MAX)

SHUTDOWN

ACTIVE

MODE

VITH vs Output Current

TEMPERATURE (°C)

–40

/RUN PIN SOURCE CURRENT WITH V

ITH

= 1V (µA)

/RUN PIN SOURCE CURRENT WITH V

ITH

= 0V (µA)

300

250

200

150

100

50

5

4

3

2

1

35 85

1624 G14

–15 10 60 110 135

/RUN = 1V

/RUN = 0V

ITH/RUN Pin Source Current vs

Temperature

IITH vs VITH

ITH

(µA)

200

150

ITH

(V)

1.2 2.40.8

(b)

1624 G02

SHUTDOWN

ACTIVE

MODE



Frequency vs Feedback Voltage

FEEDBACK VOLTAGE

FREQUENCY (kHz)

250

200

150

100

50

01.00

1624 G03

0.25 0.50 0.75 1.25

TEMPERATURE (°C)

–40

CURRENT SENSE THRESHOLD (mV)

170

168

166

164

162

160

158

156

154

152

150 10 60 85

1448 G13

–15 35 110 135

Maximum Current Sense

Threshold vs Temperature

TEMPERATURE (°C)

–40

FREQUENCY (kHz)

250

200

150

100

50

010 60 85

1448 G12

–15 35 110 135

OUT

IN REGULATION

= 0V

PIN FUNCTIONS

UUU

SENSE

–

(Pin 1): Connects to the (–) input for the current

comparator. Built-in offsets between the SENSE

–

and V

pins in conjunction with R

SENSE

set the current trip thresh-

olds. Do not pull this pin more than 15V below V

or more

than 0.3V below ground.

/RUN (Pin 2): Combination of Error Amplifier Compen-

sation Point and Run Control Inputs. The current com-

parator threshold increases with this control voltage.

Nominal voltage range for this pin is 1.19V to 2.4V. Forcing

this pin below 0.8V causes the device to be shut down. In

shutdown all functions are disabled and TG pin is held low.

(Pin 3): Receives the feedback voltage from an exter-

nal resistive divider across the output.

GND (Pin 4): Ground. Connect to the (–) terminal of C

OUT

the Schottky diode and the (–) terminal of C

SW (Pin 5): Switch Node Connection to Inductor. In step-

down applications the voltage swing at this pin is from a

Schottky diode (external) voltage drop below ground to

Operating Frequency vs

Temperature

LTC1624

TG (Pin 6): High Current Gate Drive for Top N-Channel

MOSFET. This is the output of a floating driver with a

voltage swing equal to INTV

superimposed on the

switch node voltage SW.

BOOST (Pin 7): Supply to Topside Floating Driver. The

bootstrap capacitor C

is returned to this pin. Voltage

swing at this pin is from INTV

to V

+ INTV

in step-

down applications. In non step-down topologies the volt-

age at this pin is constant and equal to INTV

if SW = 0V.

(Pin 8): Main Supply Pin and the (+) Input to the

Current Comparator. Must be closely decoupled to ground.

PIN FUNCTIONS

UUU

(Refer to Functional Diagram)

OPERATIO

Main Control Loop

The LTC1624 uses a constant frequency, current mode

architecture. During normal operation, the top MOSFET is

turned on each cycle when the oscillator sets the RS latch

and turned off when the main current comparator I

resets

the RS latch. The peak inductor current at which I

resets

the RS latch is controlled by the voltage on the I

/RUN

pin, which is the output of error amplifier EA. The V

pin,

described in the pin functions, allows EA to receive an

output feedback voltage from an external resistive divider.

When the load current increases, it causes a slight

decrease in V

relative to the 1.19V reference, which in

turn causes the I

/RUN voltage to increase until the

average inductor current matches the new load current.

While the top MOSFET is off, the internal bottom MOSFET

is turned on for approximately 300ns to 400ns to recharge

the bootstrap capacitor C

The top MOSFET driver is biased from the floating boot-

strap capacitor C

that is recharged during each off cycle.

The dropout detector counts the number of oscillator

cycles that the top MOSFET remains on and periodically

forces a brief off period to allow C

to recharge.

The main control loop is shut down by pulling the I

/RUN

pin below its 1.19V clamp voltage. Releasing I

/RUN

allows an internal 2.5µA current source to charge com-

pensation capacitor C

. When the I

/RUN pin voltage

reaches 0.8V the main control loop is enabled with the I

RUN voltage pulled up by the error amp. Soft start can be

implemented by ramping the voltage on the I

/RUN pin

from 1.19V to its 2.4V maximum (see Applications Infor-

mation section).

Comparator OV guards against transient output over-

shoots >7.5% by turning off the top MOSFET and keeping

it off until the fault is removed.

Low Current Operation

The LTC1624 is capable of Burst Mode operation in which

the external MOSFET operates intermittently based on

load demand. The transition to low current operation

begins when comparator B detects when the I

/RUN

voltage is below 1.5V. If the voltage across R

SENSE

does

not exceed the offset of I

(approximately 20mV) for one

full cycle, then on following cycles the top and internal

bottom drives are disabled. This continues until the I

voltage exceeds 1.5V, which causes drive to be returned to

the TG pin on the next cycle.

INTV

Power/Boost Supply

Power for the top and internal bottom MOSFET drivers is

derived from V

. An internal regulator supplies INTV

power. To power the top driver in step-down applications

an internal high voltage diode recharges the bootstrap

capacitor C

during each off cycle from the INTV

supply.

A small internal N-channel MOSFET pulls the switch node

(SW) to ground each cycle after the top MOSFET has

turned off ensuring the bootstrap capacitor is kept fully

charged.

LTC1624

FUNCTIONAL DIAGRA



(Shown in a step-down application)

–

8k 4k

3µA

RUN

OUT

BOOST

FLOATING

DRIVER TG

N-CHANNEL

MOSFET

N-CHANNEL

MOSFET

INTV

SENSE

–

5.6V

INTV



REG

0.8V

1.19V

200kHz

1.19V

/RUN

1.28V

1.19V

180k

1.5V

3µA

30k 8k

GND

1624 FD

2.5µA

SLOPE

COMP

SLOPE

COMP

–

OV OSC

DROP-

OUT

DET

1-SHOT

400ns

SWITCH

LOGIC

INTV

OSC

= 1m

Ω

1.19V

REF

LTC1624

APPLICATIONS INFORMATION

WUU U

The LTC1624 can be used in a wide variety of switching

regulator applications, the most common being the step-

down converter. Other switching regulator architectures

include step-up, SEPIC and positive-to-negative converters.

The basic LTC1624 step-down application circuit is shown

in Figure 1 on the first page. External component selection

is driven by the load requirement and begins with the

selection of R

SENSE

. Once R

SENSE

is known, the inductor

can be chosen. Next, the power MOSFET and D1 are

selected. Finally, C

and C

OUT

are selected. The circuit

shown in Figure 1 can be configured for operation up to an

input voltage of 28V (limited by the external MOSFETs).

Step-Down Converter: R

SENSE

Selection for

Output Current

SENSE

is chosen based on the required output current.

The LTC1624 current comparator has a maximum thresh-

old of 160mV/R

SENSE

. The current comparator threshold

sets the peak of the inductor current, yielding a maximum

average output current I

MAX

equal to the peak value less

half the peak-to-peak ripple current, ∆I

Allowing a margin for variations in the LTC1624 and

external component values yields:

RmV

SENSE MAX

=100

The LTC1624 works well with values of R

SENSE

from

0.005Ω to 0.5Ω.

Step-Down Converter: Inductor Value Calculation

With the operating frequency fixed at 200kHz smaller

inductor values are favored. Operating at higher frequen-

cies generally results in lower efficiency because of

MOSFET gate charge losses. In addition to this basic

trade-off, the effect of inductor value on ripple current and

low current operation must also be considered.

The inductor value has a direct effect on ripple current. The

inductor ripple current ∆I

decreases with higher induc-

tance and increases with higher V

or V

OUT

∆IVV

LIN OUT OUT D

IN D

=−

()()











where V

is the output Schottky diode forward drop.

Accepting larger values of ∆I

allows the use of low

inductances, but results in higher output voltage ripple

and greater core losses. A reasonable starting point for

setting ripple current is ∆I

= 0.4(I

MAX

). Remember, the

maximum ∆I

occurs at the maximum input voltage.

The inductor value also has an effect on low current

operation. Lower inductor values (higher ∆I

) will cause

Burst Mode operation to begin at higher load currents,

which can cause a dip in efficiency in the upper range of

low current operation. In Burst Mode operation lower

inductance values will cause the burst frequency to

decrease. In general, inductor values from 5µH to 68µH

are typical depending on the maximum input voltage and

output current. See also Modifying Burst Mode Operation

section.

Step-Down Converter: Inductor Core Selection

Once the value for L is known, the type of inductor must be

selected. High efficiency converters generally cannot

afford the core loss found in low cost powdered iron cores,

forcing the use of more expensive ferrite, molypermalloy

or Kool Mµ

cores. Actual core loss is independent of core

size for a fixed inductor value, but it is very dependent on

inductance selected. As inductance increases, core losses

go down. Unfortunately, increased inductance requires

more turns of wire and, therefore, copper losses will

increase.

Ferrite designs have very low core loss and are preferred

at high switching frequencies, so design goals can con-

centrate on copper loss and preventing saturation. Ferrite

core material saturates “hard,” which means that induc-

tance collapses abruptly when the peak design current is

exceeded. This results in an abrupt increase in inductor

ripple current and consequent output voltage ripple. Do

not allow the core to saturate!

Molypermalloy (from Magnetics, Inc.) is a very good, low

loss core material for toroids, but it is more expensive than

ferrite. A reasonable compromise from the same manu-

facturer is Kool Mµ. Toroids are very space efficient,

especially when you can use several layers of wire.

Because they generally lack a bobbin, mounting is more

difficult. However, designs for surface mount that do not

increase the height significantly are available.

Kool Mu is a registered trademark of Magnetics, Inc.

LTC1624

Step-Down Converter: Power MOSFET Selection

One external N-channel power MOSFET must be selected

for use with the LTC1624 for the top (main) switch.

The peak-to-peak gate drive levels are set by the INTV

voltage. This voltage is typically 5V. Consequently, logic

level threshold MOSFETs must be used in most LTC1624

applications. If low input voltage operation is expected

< 5V) sublogic level threshold MOSFETs should be

used. Pay close attention to the BV

DSS

specification for the

MOSFETs as well; many of the logic level MOSFETs are

limited to 30V or less.

Selection criteria for the power MOSFET include the “ON”

resistance R

DS(ON)

, reverse transfer capacitance C

RSS

input voltage and maximum output current. When the

LTC1624 is operating in continuous mode the duty cycle

for the top MOSFET is given by:

Main V

IN D

Switch Duty Cycle = V

OUT

The MOSFET power dissipation at maximum output

current is given by:

PVV

kV I C f

MAIN OUT D

IN DMAX

IN MAX RSS

()

() ( )( )()

()

185

1δ R

DS ON

where δ is the temperature dependency of R

DS(ON)

and k

is a constant inversely related to the gate drive current.

MOSFETs have I

R losses, plus the P

MAIN

equation

includes an additional term for transition losses that are

highest at high output voltages. For V

< 20V the high

current efficiency generally improves with larger MOSFETs,

while for V

> 20V the transition losses rapidly increase to

the point that the use of a higher R

DS(ON)

device with lower

RSS

actual provides higher efficiency. The diode losses

are greatest at high input voltage or during a short circuit

when the diode duty cycle is nearly 100%.

The term (1+ δ) is generally given for a MOSFET in the form

of a normalized R

DS(ON)

vs Temperature curve, but

δ = 0.005/°C can be used as an approximation for low

voltage MOSFETs. C

RSS

is usually specified in the MOSFET

APPLICATIONS INFORMATION

WUU U

characteristics. The constant k = 2.5 can be used to

estimate the contributions of the two terms in the P

MAIN

dissipation equation.

Step-Down Converter: Output Diode Selection (D1)

The Schottky diode D1 shown in Figure 1 conducts during

the off-time. It is important to adequately specify the diode

peak current and average power dissipation so as not to

exceed the diode ratings.

The most stressful condition for the output diode is under

short circuit (V

OUT

= 0V). Under this condition, the diode

must safely handle I

SC(PK)

at close to 100% duty cycle.

Under normal load conditions, the average current con-

ducted by the diode is simply:

DIODE AVG LOAD AVG IN OUT

IN D

() ()













=−

Remember to keep lead lengths short and observe proper

grounding (see Board Layout Checklist) to avoid ringing

and increased dissipation.

The forward voltage drop allowable in the diode is calcu-

lated from the maximum short-circuit current as:

SC AVG

IN D

≈+











()

where P

is the allowable diode power dissipation and will

be determined by efficiency and/or thermal requirements

(see Efficiency Considerations).

Step-Down Converter: C

and C

OUT

Selection

In continuous mode the source current of the top

N-channel MOSFET is a square wave of approximate duty

cycle V

OUT

. To prevent large voltage transients, a low

ESR input capacitor sized for the maximum RMS current

must be used. The maximum RMS capacitor current is

given by:

VVV

IN MAX OUT IN OUT

Required I

RMS

≈−

()

[]

12/

This formula has a maximum at V

= 2V

OUT

, where

RMS

= I

OUT

/2. This simple worst-case condition is com-

LTC1624

APPLICATIONS INFORMATION

WUU U

ratings that are ideal for input capacitor applications.

Consult the manufacturer for other specific recommend-

ations.

INTV

Regulator

An internal regulator produces the 5V supply that powers

the drivers and internal circuitry within the LTC1624.

Good V

bypassing is necessary to supply the high

transient currents required by the MOSFET gate drivers.

High input voltage applications in which large MOSFETs

are being driven at high frequencies may cause the maxi-

mum junction temperature rating for the LTC1624 to be

exceeded. The supply current is dominated by the gate

charge supply current as discussed in the Efficiency

Considerations section. The junction temperature can be

estimated by using the equations given in Note 1 of the

Electrical Characteristics table. For example, the LTC1624

is limited to less than 17mA from a 30V supply:

= 70°C + (17mA)(30V)(110°C/W) = 126°C

To prevent maximum junction temperature from being

exceeded, the input supply current must be checked

operating in continuous mode at maximum V

Step-Down Converter: Topside MOSFET Driver

Supply (C

, D

)

An external bootstrap capacitor C

connected to the BOOST

pin supplies the gate drive voltage for the topside MOSFET.

Capacitor C

in the functional diagram is charged through

internal diode D

from INTV

when the SW pin is low.

When the topside MOSFET is to be turned on, the driver

places the C

voltage across the gate to source of the

MOSFET. This enhances the MOSFET and turns on the

topside switch. The switch node voltage SW rises to V

and the BOOST pin rises to V

+ INTV

. The value of the

boost capacitor C

needs to be 50 times greater than the

total input capacitance of the topside MOSFET. In most

applications 0.1µF is adequate.

Significant efficiency gains can be realized by supplying

topside driver operating voltage from the output, since the

current resulting from the driver and control currents

will be scaled by a factor of (Duty Cycle)/(Efficiency). For

5V regulators this simply means connecting the BOOST

monly used for design because even significant deviations

do not offer much relief. Note that capacitor manufacturer’s

ripple current ratings are often based on only 2000 hours

of life. This makes it advisable to further derate the

capacitor, or to choose a capacitor rated at a higher

temperature than required. Several capacitors may also be

paralleled to meet size or height requirements in the

design. Always consult the manufacturer if there is any

question.

The selection of C

OUT

is driven by the required effective

series resistance (ESR). Typically, once the ESR require-

ment is satisfied the capacitance is adequate for filtering.

The output ripple (∆V

OUT

) is determined by:

∆∆V I ESR fC

OUT L OUT

≈+











where f = operating frequency, C

OUT

= output capacitance

and ∆I

= ripple current in the inductor. The output ripple

is highest at maximum input voltage since ∆I

increases

with input voltage. With ∆I

= 0.4I

OUT(MAX)

the output

ripple will be less than 100mV at maximum V

, assuming:

OUT

Required ESR < 2R

SENSE

Manufacturers such as Nichicon, United Chemicon and

SANYO should be considered for high performance

through-hole capacitors. The OS-CON semiconductor

dielectric capacitor available from SANYO has the lowest

ESR(size) product of any aluminum electrolytic at a some-

what higher price. Once the ESR requirement for C

OUT

has

been met, the RMS current rating generally far exceeds

the I

RIPPLE(P-P)

requirement.

In surface mount applications multiple capacitors may

have to be paralleled to meet the ESR or RMS current

handling requirements of the application. Aluminum elec-

trolytic and dry tantalum capacitors are both available in

surface mount configurations. In the case of tantalum it is

critical that the capacitors are surge tested for use in

switching power supplies. An excellent choice is the AVX

TPS series of surface mount tantalums, available in case

heights ranging from 2mm to 4mm. Other capacitor types

include SANYO OS-CON, Nichicon WF series and Sprague

595D series and the new ceramics. Ceramic capacitors are

now available in extremely low ESR and high ripple current

LTC1624

pin through a small Schottky diode (like a Central

CMDSH-3) to V

OUT

as shown in Figure 10. However, for

3.3V and other lower voltage regulators, additional cir-

cuitry is required to derive boost supply power from the

output.

For low input voltage operation (V

< 7V), a Schottky

diode can be connected from V

to BOOST to increase the

external MOSFET gate drive voltage. Be careful not to

exceed the maximum voltage on BOOST to SW pins

of 7.8V.

Output Voltage Programming

The output voltage is set by a resistive divider according

to the following formula:

OUT













119 1 2

The external resistive divider is connected to the output as

shown in Figure 2, allowing remote voltage sensing. When

using remote sensing, a local 100Ω resistor should be

connected from L1 to R2 to prevent V

OUT

from running

away if the sense lead is disconnected.

APPLICATIONS INFORMATION

WUU U

/RUN

1624 F03

3.3V

OR 5V I

/RUN

(a) (b)

/RUN

(c)

Figure 3. ITH/RUN Pin Interfacing

Soft start can be implemented by ramping the voltage on

/RUN during start-up as shown in Figure 3(c). As the

voltage on I

TH/RUN

ramps from 1.19V to 2.4V the internal

peak current limit is also ramped at a proportional linear

rate. The peak current limit begins at approximately

10mV/R

SENSE

(at V

ITH/RUN

= 1.4V) and ends at:

160mV/R

SENSE

ITH/RUN

= 2.4V)

The output current thus ramps up slowly, charging the

output capacitor. The peak inductor current and maximum

output current are as follows:

L(PEAK)

= (V

ITH/RUN

– 1.3V)/(6.8R

SENSE

)

OUT(MAX)

= I

LPEAK

– ∆I

with ∆I

= ripple current in the inductor.

During normal operation the voltage on the I

/RUN pin

will vary from 1.19V to 2.4V depending on the load current.

Pulling the I

/RUN pin below 0.8V puts the LTC1624 into

a low quiescent current shutdown (I

< 30µA). This pin can

be driven directly from logic as shown in Figures 3(a)

and 3(b).

Efficiency Considerations

The percent efficiency of a switching regulator is equal to

the output power divided by the input power times 100%.

It is often useful to analyze individual losses to determine

/RUN Function

The I

/RUN pin is a dual purpose pin that provides the

loop compensation and a means to shut down the LTC1624.

Soft start can also be implemented with this pin. Soft start

reduces surge currents from V

by gradually increasing

the internal current limit.

Power supply sequencing

can

also be accomplished using this pin.

An internal 2.5µA current source charges up the external

capacitor C

When the voltage on I

/RUN reaches 0.8V

the LTC1624 begins operating. At this point the error

amplifier pulls up the I

/RUN pin to its maximum of 2.4V

(assuming V

OUT

is starting low).

Figure 2. Setting the LTC1624 Output Voltage

LTC1624

GND

100pF

OUT

1624 F02

LTC1624

what is limiting the efficiency and which change would

produce the most improvement. Percent efficiency can be

expressed as:

%Efficiency = 100% – (L1 + L2 + L3 + ...)

where L1, L2, etc. are the individual losses as a percentage

of input power.

Although all dissipative elements in the circuit produce

losses, four main sources usually account for most of the

losses in LTC1624 circuits:

1. LTC1624 V

current

2. I

R losses

3. Topside MOSFET transition losses

4. Voltage drop of the Schottky diode

1. The V

current is the sum of the DC supply current I

given in the Electrical Characteristics table, and the

MOSFET driver and control currents. The MOSFET

driver current results from switching the gate

capacitance of the power MOSFET. Each time a MOSFET

gate is switched from low to high to low again, a packet

of charge dQ moves from INTV

to ground. The

resulting dQ/dt is a current out of V

which is typically

much larger than the control circuit current. In

continuous mode, I

GATECHG

= f (Q

+ Q

), where Q

and

are the gate charges of the topside and internal

bottom side MOSFETs.

By powering BOOST from an output-derived source

(Figure 10 application), the additional V

current

resulting from the topside driver will be scaled by a

factor of (Duty Cycle)/(Efficiency). For example, in a

20V to 5V application, 5mA of INTV

current results in

approximately 1.5mA of V

current. This reduces the

midcurrent loss from 5% or more (if the driver was

powered directly from V

) to only a few percent.

2. I

R losses are predicted from the DC resistances of the

MOSFET, inductor and current shunt. In continuous

mode the average output current flows through L but is

“chopped” between the topside main MOSFET/current

shunt and the Schottky diode. The resistances of the

topside MOSFET and R

SENSE

multiplied by the duty

cycle can simply be summed with the resistance of L to

obtain I

R losses. (Power is dissipated in the sense

resistor only when the topside MOSFET is on. The I

loss is thus reduced by the duty cycle.) For example, at

50% DC, if R

DS(ON)

= 0.05Ω, R

= 0.15Ω and R

SENSE

0.05Ω, then the effective total resistance is 0.2Ω. This

results in losses ranging from 2% to 8% for V

OUT

= 5V

as the output current increases from 0.5A to 2A. I

losses cause the efficiency to drop at high output

currents.

3. Transition losses apply only to the topside MOSFET(s),

and only when operating at high input voltages (typically

20V or greater). Transition losses can be estimated

from:

Transition Loss = 2.5(V

)

1.85

MAX

)(C

RSS

)(f)

4. The Schottky diode is a major source of power loss at

high currents and gets worse at high input voltages.

The diode loss is calculated by multiplying the forward

voltage drop times the diode duty cycle multiplied by

the load current. For example, assuming a duty cycle of

50% with a Schottky diode forward voltage drop of

0.5V, the loss is a relatively constant 5%.

As expected, the I

R losses and Schottky diode loss

dominate at high load currents. Other losses including

and C

OUT

ESR dissipative losses and inductor core

losses generally account for less than 2% total additional

loss.

Checking Transient Response

The regulator loop response can be checked by looking at

the load transient response. Switching regulators take

several cycles to respond to a step in DC (resistive) load

current. When a load step occurs, V

OUT

immediately shifts

by an amount equal to (∆I

LOAD

• ESR), where ESR is the

effective series resistance of C

OUT

. ∆I

LOAD

also begins to

charge or discharge C

OUT

which generates a feedback

error signal. The regulator loop then acts to return V

OUT

its steady-state value. During this recovery time V

OUT

can

be monitored for overshoot or ringing that would indicate

a stability problem. The I

external components shown in

the Figure 1 circuit will provide adequate compensation for

most applications.

A second, more severe transient, is caused by switching in

loads with large (>1µF) supply bypass capacitors. The

discharged bypass capacitors are effectively put in parallel

APPLICATIONS INFORMATION

WUU U

LTC1624

with C

OUT

, causing a rapid drop in V

OUT

. No regulator can

deliver enough current to prevent this problem if the load

switch resistance is low and it is driven quickly. The only

solution is to limit the rise time of the switch drive so that

the load rise time is limited to approximately (25 • C

LOAD

Thus a 10µF capacitor would require a 250µs rise time,

limiting the charging current to about 200mA.

Automotive Considerations: Plugging into the

Cigarette Lighter

As battery-powered devices go mobile there is a natural

interest in plugging into the cigarette lighter in order to

conserve or even recharge battery packs during operation.

But before you connect, be advised: you are plugging into

the supply from hell. The main battery line in an automo-

bile is the source of a number of nasty potential transients,

including load dump, reverse battery and double battery.

Load dump is the result of a loose battery cable. When the

cable breaks connection, the field collapse in the alternator

can cause a positive spike as high as 60V which takes

several hundred milliseconds to decay. Reverse battery is

just what it says, while double battery is a consequence of

tow-truck operators finding that a 24V jump start cranks

cold engines faster than 12V.

The network shown in Figure 4 is the most straightforward

approach to protect a DC/DC converter from the ravages

of an automotive battery line. The series diode prevents

current from flowing during reverse battery, while the

transient suppressor clamps the input voltage during load

dump. Note that the transient suppressor should not

conduct during double battery operation, but must still

clamp the input voltage below breakdown of the converter.

Although the LTC1624 has a maximum input voltage of

APPLICATIONS INFORMATION

WUU U

36V, most applications will be limited to 30V by the

MOSFET BV

DSS

Modifying Burst Mode Operation

The LTC1624 automatically enters Burst Mode operation

at low output currents to boost efficiency. The point when

continuous mode operation changes to Burst Mode op-

eration scales as a function of maximum output current.

The output current when Burst Mode operation com-

mences is approximately 8mV/R

SENSE

(8% of maximum

output current).

With the additional circuitry shown in Figure 5 the LTC1624

can be forced to stay in continuous mode longer at low

output currents. Since the LTC1624 is not a fully synchro-

nous architecture, it will eventually start to skip cycles as

the load current drops low enough. The point when the

minimum on-time (450ns) is reached determines the load

current when cycle skipping begins at approximately 1%

of maximum output current. Using the circuit in Figure 5

the LTC1624 will begin to skip cycles but stays in regula-

tion when I

OUT

is less than I

OUT(MIN)

Itf

VV VV

OUT MIN

ON MIN

IN OUT IN D

OUT D

() ()













−

()











where t

ON(MIN)

= 450ns, f = 200kHz.

The transistor Q1 in the circuit of Figure 5 operates as a

current source developing an 18mV offset across the

1000pF 100Ω

18mV

OUT

SENSE

OUT

D1

MBRS340T3

Q1

2N2222

1624 F05

OUT

– 0.7V)

180µA

*R =

LTC1624

SENSE

–

Figure 5. Modifying Burst Mode OperationFigure 4. Plugging into the Cigarette Lighter

LTC1624

50A I



RATING

12V

TRANSIENT VOLTAGE

SUPPRESSOR

GENERAL INSTRUMENT

1.5KA24A

1624 F04

LTC1624

100Ω resistor in series with the SENSE

–

pin. This offset

cancels the internal offset in current comparator I

(refer

to Functional Diagram). This comparator in conjunction

with the voltage on the I

/RUN pin determines when to

enter into Burst Mode operation (refer to Low Current

Operation in Operation section). With the additional exter-

nal offset present, the drive to the topside MOSFET is

always enabled every cycle and constant frequency opera-

tion occurs for I

OUT

> I

OUT(MIN)

Step-Down Converter: Design Example

As a design example, assume V

= 12V(nominal),

= 22V(max), V

OUT

= 3.3V and I

MAX

= 2A. R

SENSE

can

immediately be calculated:

SENSE

= 100mV/2A = 0.05Ω

Assume a 10µH inductor. To check the actual value of the

ripple current the following equation is used:

∆IVV

LIN OUT OUT D

IN D

=−

()()











The highest value of the ripple current occurs at the

maximum input voltage:

∆IVV

kHz H

=−

()











22 3 3

200 10

33 05

22 0 5 158

...

µA

P-P

The power dissipation on the topside MOSFET can be

easily estimated. Choosing a Siliconix Si4412DY results

in: R

DS(ON)

= 0.042Ω, C

RSS

= 100pF. At maximum input

voltage with T(estimated) = 50°C:

ACC

V A pF kHz mW

MAIN

()

°− °

()

[]

()

()()( )( )

33 05

22 0 5 2 1 0 005 50 25 0 042

2 5 22 2 100 200 62

185

...

Ω

The most stringent requirement for the Schottky diode

occurs when V

OUT

= 0V (i.e. short circuit) at maximum V

In this case the worst-case dissipation rises to:

PI V V

D SC AVG D IN

IN D

()











()

APPLICATIONS INFORMATION

WUU U

With the 0.05Ω sense resistor I

SC(AVG)

= 2A will result,

increasing the 0.5V Schottky diode dissipation to 0.98W.

is chosen for an RMS current rating of at least 1.0A at

temperature. C

OUT

is chosen with an ESR of 0.03Ω for low

output ripple. The output ripple in continuous mode will be

highest at the maximum input voltage. The output voltage

ripple due to ESR is approximately:

ORIPPLE

= R

ESR

(∆I

) = 0.03Ω (1.58A

P-P

) = 47mV

P-P

Step-Down Converter: Duty Cycle Limitations

At high input to output differential voltages the on-time

gets very small. Due to internal gate delays and response

times of the internal circuitry the minimum recommended

on-time is 450ns. Since the LTC1624’s frequency is inter-

nally set to 200kHz a potential duty cycle limitation exists.

When the duty cycle is less than 9%, cycle skipping may

occur which increases the inductor ripple current but does

not cause V

OUT

to lose regulation. Avoiding cycle skipping

imposes a limit on the input voltage for a given output

voltage only when V

OUT

< 2.2V using 30V MOSFETs.

(Remember not to exceed the absolute maximum voltage

of 36V.)

IN(MAX)

= 11.1V

OUT

+ 5V For DC > 9%

Boost Converter Applications

The LTC1624 is also well-suited to boost converter appli-

cations. A boost converter steps up the input voltage to a

higher voltage as shown in Figure 6.

Figure 6. Boost Converter

M1 R2

SENSE

1624 F06

LTC1624

SENSE

–

BOOST

GND

OUT

LTC1624

Boost Converters: Power MOSFET Selection

One external N-channel power MOSFET must be selected

for use with the LTC1624 for the switch. In boost applica-

tions the source of the power MOSFET is grounded along

with the SW pin. The peak-to-peak gate drive levels are set

by the INTV

voltage. The gate drive voltage is equal to

approximately 5V for V

> 5.6V and a logic level MOSFET

can be used. At V

voltages below 5V the gate drive

voltage is equal to V

– 0.6V and a sublogic level MOSFET

should be used.

Selection criteria for the power MOSFET include the “ON”

resistance R

DS(ON)

, reverse transfer capacitance C

RSS

input voltage and maximum output current. When the

LTC1624 is operating in continuous mode the duty cycle

for the MOSFET is given by:

Main Switch Duty Cycle = 1−+

OUT D

The MOSFET power dissipation at maximum output cur-

rent is given by:

APPLICATIONS INFORMATION

WUU U

Boost Converter: Inductor Selection

For most applications the inductor will fall in the range of

10µH to 100µH. Higher values reduce the input ripple

voltage and reduce core loss. Lower inductor values are

chosen to reduce physical size.

The input current of the boost converter is calculated at full

load current. Peak inductor current can be significantly

higher than output current, especially with smaller induc-

tors and lighter loads. The following formula assumes

continuous mode operation and calculates maximum peak

inductor current at minimum V

II V

L PEAK OUT MAX OUT

IN MIN

L MAX

() ()() ()

=











∆

The ripple current in the inductor (∆I

) is typically 20% to

30% of the peak inductor current occuring at V

IN(MIN)

and

OUT(MAX)

∆IVV V V

kHz L V V

LIN OUT D IN

OUT D

P-P

()

=+−

()

()()

()

200

with ∆I

L(MAX)

= ∆I

L(P-P)

at V

= V

IN(MIN)

Remember boost converters are not short-circuit pro-

tected, and that under output short conditions, inductor

current is limited only by the available current of the input

supply, I

OUT(OVERLOAD)

. Specify the maximum inductor

current to safely handle the greater of I

L(PEAK)

OUT(OVERLOAD)

. Make sure the inductor’s saturation cur-

rent rating (current when inductance begins to fall)

exceeds the maximum current rating set by R

SENSE

Boost Converter: R

SENSE

Selection for Maximum

Output Current

SENSE

is chosen based on the required output current.

Remember the LTC1624 current comparator has a maxi-

mum threshold of 160mV/R

SENSE

. The current compara-

tor threshold sets the peak of the inductor current, yielding

a maximum average output current I

OUT(MAX)

equal to

L(PEAK)

less half the peak-to-peak ripple current (∆I

divided by the output-input voltage ratio (see equation for

L(PEAK)

)

PI V

VV R

k V I C kHz

where I I VV

MAIN IN MAX

IN MIN

OUT D DS ON

OUT IN MAX RSS

IN MAX OUT MAX OUT D

IN MIN

=



−+













+

()







()( )













() () ()

()

() () ()

185

200

δ is the temperature dependency of R

DS(ON)

and k is a

constant inversely related to the gate drive current.

MOSFETs have I

R losses, plus the P

MAIN

equation

includes an additional term for transition losses that are

highest at high output voltages. For V

OUT

< 20V the high

current efficiency generally improves with larger MOSFETs,

while for V

OUT

> 20V the transition losses rapidly increase

to the point that the use of a higher R

DS(ON)

device with

lower C

RSS

actual provides higher efficiency. For addi-

tional information refer to Step-Down Converter: Power

MOSFET Selection in the Applications Information

section.

LTC1624

Allowing a margin for variations in the LTC1624 (without

considering variation in R

SENSE

), assuming 30% ripple

current in the inductor, yields:

RmV

SENSE OUT MAX

IN MIN

OUT D













() ()

100

Boost Converter: Output Diode

The output diode conducts current only during the switch

off-time. Peak reverse voltage for boost converters is

equal to the regulator output voltage. Average forward

current in normal operation is equal to output current.

Remember boost converters are not short-circuit pro-

tected. Check to be sure the diode’s current rating exceeds

the maximum current set by R

SENSE

. Schottky diodes such

as Motorola MBR130LT3 are recommended.

Boost Converter: Output Capacitors

The output capacitor is normally chosen by its effective

series resistance (ESR), because this is what determines

output ripple voltage.

Since the output capacitor’s ESR affects efficiency, use

low ESR capacitors for best performance. Boost regula-

tors have large RMS ripple current in the output capacitor

that must be rated to handle the current. The output

capacitor ripple current (RMS) is:

OUT OUT OUT IN

RIPPLE RMS

()

≈−

Output ripple is then simply: V

OUT

= R

ESR

(∆I

L(RMS)

Boost Converter: Input Capacitors

The input capacitor of a boost converter is less critical due

to the fact that the input current waveform is triangular,

and does not contain large square wave currents as found

in the output capacitor. The input voltage source imped-

ance determines the size of the capacitor that is typically

10µF to 100µF. A low ESR is recommended although not

as critical as the output capacitor and can be on the order

of 0.3Ω. Input capacitor ripple current for the LTC1624

used as a boost converter is:

APPLICATIONS INFORMATION

WUU U

CVV V

kHz L V

IN IN OUT IN

OUT

RIPPLE

≈

()

−

()

()()()

200

The input capacitor can see a very high surge current when

a battery is suddenly connected and solid tantalum capaci-

tors can fail under this condition. Be sure to specify surge

tested capacitors.

Boost Converter: Duty Cycle Limitations

The minimum on-time of 450ns sets a limit on how close

can approach V

OUT

without the output voltage over-

shooting and tripping the overvoltage comparator. Unless

very low values of inductances are used, this should never

be a problem. The maximum input voltage in continuous

mode is:

IN(MAX)

= 0.91V

OUT

+ 0.5V For DC = 9%

SEPIC Converter Applications

The LTC1624 is also well-suited to SEPIC (Single Ended

Primary Inductance Converter) converter applications.

The SEPIC converter shown in Figure 7 uses two induc-

tors. The advantage of the SEPIC converter is the input

voltage may be higher or lower than the output voltage.

The first inductor L1 together with the main N-channel

MOSFET switch resemble a boost converter. The second

inductor L2 and output diode D1 resemble a flyback or

buck-boost converter. The two inductors L1 and L2 can be

independent but also can be wound on the same core since

Figure 7. SEPIC Converter

M1 R2

SENSE

1624 F07

LTC1624

SENSE

–

BOOST

GND

OUT

LTC1624

APPLICATIONS INFORMATION

WUU U

identical voltages are applied to L1 and L2 throughout the

switching cycle. By making L1 = L2 and wound on the

same core the input ripple is reduced along with cost and

size. All SEPIC applications information that follows

assumes L1 = L2 = L.

SEPIC Converter: Power MOSFET Selection

One external N-channel power MOSFET must be selected

for use with the LTC1624 for the switch. As in boost

applications the source of the power MOSFET is grounded

along with the SW pin. The peak-to-peak gate drive levels

are set by the INTV

voltage. This voltage is equal to

approximately 5V for V

> 5.6V and a logic level MOSFET

can be used. At V

voltages below 5V the INTV

voltage

is equal to V

– 0.6V and a sublogic level MOSFET should

be used.

Selection criteria for the power MOSFET include the “ON”

resistance R

DS(ON)

, reverse transfer capacitance C

RSS

input voltage and maximum output current. When the

LTC1624 is operating in continuous mode the duty cycle

for the MOSFET is given by:

Main Switch Duty Cycle = VV

VV V

OUT D

IN OUT D

The MOSFET power dissipation and maximum switch

current at maximum output current are given by:

IVV

VVVR

k V V I C kHz

where I I VV

MAIN

SW MAX OUT D

IN MIN OUT D DS ON

IN MIN OUT SW MAX RSS

SW MAX OUT MAX OUT D

IN MIN





+













()













()( )











() () ()

() ( )

() () ()

185

200





δ is the temperature dependency of R

DS(ON)

and k is a

constant inversely related to the gate drive current. The

peak switch current is I

SW(MAX)

+ ∆I

MOSFETs have I

R losses plus the P

MAIN

equation

includes an additional term for transition losses that are

highest at high total input plus output voltages. For

+ V

OUT

) < 20V the high current efficiency generally

improves with larger MOSFETs, while for (V

+ V

OUT

) >

20V the transition losses rapidly increase to the point that

the use of a higher R

DS(ON)

device with lower C

RSS

actual

provides higher efficiency. For additional information refer

to the Step-Down Converter: Power MOSFET Selection in

the Applications Information section.

SEPIC Converter: Inductor Selection

For most applications the equal inductor values will fall in

the range of 10µH to 100µH. Higher values reduce the

input ripple voltage and reduce core loss. Lower inductor

values are chosen to reduce physical size and improve

transient response.

Like the boost converter the input current of the SEPIC

converter is calculated at full load current. Peak inductor

current can be significantly higher than output current,

especially with smaller inductors and lighter loads. The

following formula assumes continuous mode operation

and calculates maximum peak inductor current at mini-

mum V

L1 PEAK

L2 PEAK

() ()()

()

=























IVV

OUT MAX OUT

IN MIN

OUT MAX

IN MIN D

IN MIN

∆

The ripple current in the inductor (∆I

) is typically 20% to

30% of the peak current occuring at V

IN(MIN)

and I

OUT(MAX)

and ∆I

= ∆I

. Maximum ∆I

occurs at maximum V

∆IVV V

kHz L V V V

LIN OUT D

IN OUT D

P-P

()

()()

()

200

By making L1 = L2 and wound on the same core

the value

of inductance in all the above equations are replaced by

due to their mutual inductance. Doing this maintains

the same ripple current and inductive energy storage in the

inductors. For example a Coiltronix CTX10-4 is a 10µH

inductor with two windings. With the windings in parallel

LTC1624

10µH inductance is obtained with a current rating of 4A.

Splitting the two windings creates two 10µH inductors

with a current rating of 2A each. Therefore substitute

(2)(10µH) = 20µH for L in the equations.

Specify the maximum inductor current to safely handle

L(PEAK)

. Make sure the inductor’s saturation current rat-

ing (current when inductance begins to fall) exceeds the

maximum current rating set by R

SENSE

SEPIC Converter: R

SENSE

Selection for Maximum

Output Current

SENSE

is chosen based on the required output current.

Remember the LTC1624 current comparator has a maxi-

mum threshold of 160mV/R

SENSE

. The current compara-

tor threshold sets the peak of the inductor current, yielding

a maximum average output current I

OUT(MAX)

equal to

L1(PEAK)

less half the peak-to-peak ripple current, ∆I

divided by the output-input voltage ratio (see equation for

L1(PEAK)

)

Allowing a margin for variations in the LTC1624 (without

considering variation in R

SENSE

), assuming 30% ripple

current in the inductor, yields:

RmV

SENSE OUT MAX

IN MIN

OUT D













() ()

100

SEPIC Converter: Output Diode

The output diode conducts current only during the switch

off-time. Peak reverse voltage for SEPIC converters is

equal to V

OUT

+ V

. Average forward current in normal

operation is equal to output current. Peak current is:

II VV

D PEAK OUT MAX OUT D

IN MIN L1

() () ()

=++













+∆

Schottky diodes such as MBR130LT3 are recommended.

SEPIC Converter: Input and Output Capacitors

The output capacitor is normally chosen by its effective

series resistance (ESR), because this is what determines

APPLICATIONS INFORMATION

WUU U

output ripple voltage. The input capacitor needs to be sized

to handle the ripple current safely.

Since the output capacitor’s ESR affects efficiency, use

low ESR capacitors for best performance. SEPIC regula-

tors, like step-down regulators, have a triangular current

waveform but have maximum ripple at V

IN(MAX)

. The input

capacitor ripple current is:

RIPPLE RMS L

()

∆

The output capacitor ripple current is:

RIPPLE RMS OUT V

OUT

()

The output capacitor ripple voltage (RMS) is:

OUT(RIPPLE)

= 2(∆I

)(ESR)

The input capacitor can see a very high surge current when

a battery is suddenly connected, and solid tantalum

capacitors can fail under this condition. Be sure to specify

surge tested capacitors.

SEPIC Converter: Coupling Capacitor (C1)

The coupling capacitor C1 in Figure 7 sees a nearly

rectangular current waveform. During the off-time the

current through C1 is I

OUT

) while approximately

–I

OUT

flows though C1 during the on-time. This current

waveform creates a triangular ripple voltage on C1:

∆VI

kHz C

VV V

COUT OUT

IN OUT D

200 1

()()























The maximum voltage on C1 is then:

C1(MAX)

= V

+ ∆V

/2 (typically close to V

IN(MAX)

The ripple current though C1 is:

RIPPLE C OUT OUT

()

The maximum ripple current occurs at I

OUT(MAX)

and

IN(MIN)

. The capacitance of C1 should be large enough so

LTC1624

APPLICATIONS INFORMATION

WUU U

Positive-to-Negative Converter: Output Voltage

Programming

Setting the output voltage for a positive-to-negative con-

verter is different from other architectures since the feed-

back voltage is referenced to the LTC1624 ground pin and

the ground pin is referenced to –V

OUT

. The output voltage

is set by a resistive divider according to the following

formula:

OUT IN













≈− −











119 1 1

The external resistive divider is connected to the output as

shown in Figure 8.

Positive-to-Negative Converter: Power

MOSFET Selection

One external N-channel power MOSFET must be selected

for use with the LTC1624 for the switch. As in step-down

applications the source of the power MOSFET is con-

nected to the Schottky diode and inductor. The peak-to-

peak gate drive levels are set by the INTV

voltage. The

gate drive voltage is equal to approximately 5V for V

5.6V and a logic level MOSFET can be used. At V

voltages

below 5V the INTV

voltage is equal to V

– 0.6V and a

sublogic level MOSFET should be used.

Selection criteria for the power MOSFET include the “ON”

resistance R

DS(ON)

, reverse transfer capacitance C

RSS

input voltage and maximum output current. When the

LTC1624 is operating in continuous mode the duty cycle

for the MOSFET is given by:

Main V

OUT D

Switch Duty Cycle = V

OUT

with V

OUT

 being the absolute value of V

OUT

The MOSFET power dissipation and maximum switch

current are given by:

that the voltage across C1 is constant such that V

= V

at full load over the entire V

range. Assuming the enegry

storage in the coupling capacitor C1 must be equal to the

enegry stored in L1, the minimum capacitance of C1 is:

CLI V

MIN OUT OUT

IN MIN

() ()

()( )

SEPIC Converter: Duty Cycle Limitations

The minimum on-time of 450ns sets a limit on how high

an input-to-output ratio can be tolerated while not skip-

ping cycles. This only impacts designs when very low

output voltages (V

OUT

< 2.5V) are needed. Note that a

SEPIC converter would not be appropriate at these low

output voltages. The maximum input voltage is (remem-

ber not to exceed the absolute maximum limit of 36V):

IN(MAX)

= 10.1V

OUT

+ 5V For DC > 9%

Positive-to-Negative Converter Applications

The LTC1624 can also be used as a positive-to-negative

converter with a grounded inductor shown in Figure 8.

Since the LTC1624 requires a positive feedback signal

relative to device ground, Pin 4 must be tied to the

regulated negative output. A resistive divider from the

negative output to ground sets the output voltage.

Remember not to exceed maximum V

ratings V

V

OUT

 ≤ 36V.

PMAIN = ISW MAX ×

I

OUT MAX I + δ RDS ON +

 k V IN MAX + VOUT

1.85

CRSS 200kHz



() ()

()

( )

() ()( )

()

{

Figure 8. Positive-to-Negative Converter

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

8

7

6

1

2

3

100pF

OUT

SENSE

–V

OUT

1624 F08

LTC1624

where I VV V

OUT MAX IN OUT D

: I

SW MAX

() ()

=++













δ is the temperature dependency of R

DS(ON)

and k is a

constant inversely related to the gate drive current. The

maximum switch current occurs at V

IN(MIN)

and the peak

switch current is I

SW(MAX)

+ ∆I

/2. The maximum voltage

across the switch is V

IN(MAX)

+ V

OUT

.

MOSFETs have I

R losses plus the P

MAIN

equation

includes an additional term for transition losses that are

highest at high total input plus output voltages. For

(V

OUT

+ V

) < 20V the high current efficiency generally

improves with larger MOSFETs, while for (V

OUT

+ V

)

> 20V the transition losses rapidly increase to the point

that the use of a higher R

DS(ON)

device with lower C

RSS

actual provides higher efficiency. For additional informa-

tion refer to the Step-Down Converter: Power MOSFET

Selection in the Applications Information section.

Positive-to-Negative Converter: Inductor Selection

For most applications the inductor will fall in the range of

10µH to 100µH. Higher values reduce the input and output

ripple voltage (although not as much as step-down con-

verters) and also reduce core loss. Lower inductor values

are chosen to reduce physical size and improve transient

response but do increase output ripple.

Like the boost converter, the input current of the positive-

to-negative converter is calculated at full load current.

Peak inductor current can be significantly higher than

output current, especially with smaller inductors (with

high ∆I

values). The following formula assumes continu-

ous mode operation and calculates maximum peak induc-

tor current at minimum V

II VV V

L PEAK OUT MAX IN OUT D

() ()

=++













∆

The ripple current in the inductor (∆I

) is typically 20% to

50% of the peak inductor current occuring at V

IN(MIN)

and

OUT(MAX)

to minimize output ripple. Maximum ∆I

occurs

at minimum V

APPLICATIONS INFORMATION

WUU U

∆IVV V

kHz L V V V

LIN OUT D

IN OUT D

P-P

()

()()

()

200

Specify the maximum inductor current to safely handle

L(PEAK)

. Make sure the inductor’s saturation current rat-

ing (current when inductance begins to fall) exceeds the

maximum current rating set by R

SENSE

Positive-to-Negative Converter: R

SENSE

Selection for

Maximum Output Current

SENSE

is chosen based on the required output current.

Remember the LTC1624 current comparator has a maxi-

mum threshold of 160mV/R

SENSE

. The current compara-

tor threshold sets the peak of the inductor current, yielding

a maximum average output current I

OUT(MAX)

equal to

L(PEAK)

less half the peak-to-peak ripple current with the

remainder divided by the duty cycle.

Allowing a margin for variations in the LTC1624 (without

considering variation in R

SENSE

) and assuming 30% ripple

current in the inductor, yields:

RmV

VVV

SENSE OUT MAX

IN MIN

IN MIN OUT D

=++













() ()

()

100

Positive-to-Negative Converter: Output Diode

The output diode conducts current only during the switch

off-time. Peak reverse voltage for positive-to-negative

converters is equal to V

OUT

+ V

. Average forward

current in normal operation is equal to I

D(PEAK)

– ∆I

/2.

Peak diode current (occurring at V

IN(MIN)

) is:

II VV

D PEAK OUT MAX OUT D

() ()

()













∆

Positive-to-Negative Converter: Input and

Output Capacitors

The output capacitor is normally chosen by its effective

series resistance (ESR), because this is what determines

output ripple voltage. Both input and output capacitors

need to be sized to handle the ripple current safely.

LTC1624

Positive-to-negative converters have high ripple current in

both the input and output capacitors. For long capacitor

lifetime, the RMS value of this current must be less than

the high frequency ripple rating of the capacitor.

The following formula gives an approximate value for RMS

ripple current. This formula assumes continuous mode

and low current ripple. Small inductors will give somewhat

higher ripple current, especially in discontinuous mode.

For the exact formulas refer to Application Note 44, pages

28 to 30. The input and output capacitor ripple current

(occurring at V

IN(MIN)

) is:

Capacitor ff I V

OUT OUT

RMS

()( )

ff = Fudge factor (1.2 to 2.0)

The output peak-to-peak ripple voltage is:

OUT(P-P)

= R

ESR

D(MAX)

)

The input capacitor can also see a very high surge current

when a battery is suddenly connected, and solid tantalum

capacitors can fail under this condition. Be sure to specify

surge tested capacitors.

Positive-to-Negative Converter: Duty Cycle

Limitations

The minimum on-time of 450ns sets a limit on how high

of input-to-output ratio can be tolerated while not skipping

cycles. This only impacts designs when very low output

voltages (V

OUT

< 2.5V) are needed. The maximum input

voltage is:

IN(MAX)

< 10.1V

OUT

+ 5V For DC > 9%

IN(MAX)

< 36V – V

OUT

 For absolute maximum ratings

Positive-to-Negative Converter: Shutdown

Considerations

Since the ground pin on the LTC1624 is referenced to

–V

OUT

, additional circuitry is needed to put the LTC1624

into shutdown. Shutdown is enabled by pulling the

/RUN pin below 0.8V relative to the LTC1624 ground

pin. With the LTC1624 ground pin referenced to –V

OUT

the nonimal range on the I

/RUN pin is –V

OUT

(in

shutdown) to (–V

OUT

+ 2.4V)(at Max I

OUT

). Referring to

Figure 15, M2, M3 and R3 provide a level shift from typical

TTL levels to the LTC1624 operating as positive-to-nega-

tive converter. MOSFET M3 supplies gate drive to M2

during shutdown, while M2 pulls the I

TH/RUN

pin voltage to

–V

OUT

, shutting down the LTC1624.

Step-Down Converters: PC Board Layout Checklist

When laying out the printed circuit board, the following

checklist should be used to ensure proper operation of the

LTC1624. These items are also illustrated graphically in

the layout diagram of Figure 9. Check the following in your

layout:

1. Are the signal and power grounds segregated? The

LTC1624 ground (Pin 4) must return to the (–) plate

of C

OUT.

2. Does the V

(Pin 3) connect directly to the feedback

resistors? The resistive divider R1, R2 must be con-

nected between the (+) plate of C

OUT

and signal ground.

The 100pF capacitor should be as close as possible to

the LTC1624.

3. Does the V

lead connect to the input voltage at the

same point as R

SENSE

and are the SENSE

–

and V

leads

routed together with minimum PC trace spacing? The

filter capacitor between V

and SENSE

–

should be as

close as possible to the LTC1624.

4. Does the (+) plate of C

connect to R

SENSE

as closely

as possible? This capacitor provides the AC current to

the MOSFET(s). Also, does C

connect as close as

possible to the V

and ground pin of the LTC1624?

This capacitor also supplies the energy required to

recharge the bootstrap capacitor. Adequate input

decoupling is critical for proper operation.

5. Keep the switch node SW away from sensitive small-

signal nodes. Ideally, M1, L1 and D1 should be con-

nected as closely as possible at the switch node.

APPLICATIONS INFORMATION

WUU U

LTC1624

TYPICAL APPLICATIONS

Figure 9. LTC1624 Layout Diagram (See Board Layout Checklist)

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

100pF



560pF



4.7k

D1

MBRS340T3

D2

CMDSH-3



0.1µF

R2

35.7k

R1

11k

OUT



100µF

10V

× 2

M1

Si4412DY

L1*

10µH

SENSE



0.033Ω



22µF

35V

× 2

OUT



5V



5.3V TO 28V

1624 F10

*COILTRONICS CTX10-4

0.1µF

Figure 10. 5V/3A Converter with Output Derived Boost Voltage

SENSE–

ITH/RUN

VFB

GND



VIN

BOOST

TG

LTC1624

1000pF

8

7

6

1

2

3

100pF

BOLD LINES INDICATE

HIGH CURRENT PATHS

CB

0.1µF

COUT

M1 L1

–

RSENSE CIN VIN

–

VOUT

1624 F09

LTC1624

TYPICAL APPLICATIONS

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

100pF



330pF



3.3k

D1

MBRS130LT3



0.1µF

4R2

35.7k

R1

3.92k

OUT



100µF

16V

× 2

M1

Si4412DY

L1*

22µH

SENSE



0.04Ω



22µF

35V

× 2

OUT



12V

0.75A



5.2V TO 11V

1624 F13

*SUMIDA CDRH125-220

0.1µF

Figure 11. Wide Input Range 1.8V/1.5A Converter

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

100pF



470pF



6.8k

D1

MBRS140T3



0.1µF

R2

35.7k

R1

3.92k

OUT



100µF

16V

× 2

M1

Si4412DY L1*

47µH

SENSE



0.068Ω



22µF

35V

× 2

OUT



12V



12.3V TO 28V

1624 F12

*SUMIDA CDRH125-470

0.1µF

Figure 12. 12V/1A Low Dropout Converter

Figure 13. 12V/0.75A Boost Converter

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

100pF



470pF



6.8k

D1

MBRS340T3



0.1µF

R2

35.7k

R1

69.8k

OUT



100µF

10V

× 2

M1

Si6436DY L1*

10µH

SENSE



0.068Ω



22µF

35V

× 2

OUT



1.8V

1.5A



4.8V TO 22V

1624 F11

*SUMIDA CDR105B-100

0.1µF

LTC1624

TYPICAL APPLICATIONS

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

100pF



330pF



4.7k

D1

MBRS130LT3



0.1µF

4R2

35.7k

R1

3.92k

OUT



100µF

16V

× 2

M1

Si4412DY

L1a*

L1b*

SENSE



0.068Ω



22µF

35V 22µF

35V

OUT



12V

0.5A



5V TO 15V

1624 F14

*COILTRONICS CTX20-4

0.1µF

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

100pF



470pF



6.8k

D1

MBRS340T3



0.1µF

R2

35.7k

R1

20k

OUT



100µF

10V

× 2

M1

Si6426DQ L1*

20µH

SENSE



0.068Ω



22µF

35V

× 2

OUT



3.3V

1.5A



3.5V TO 18V

1624 F16

*COILTRONICS CTX20-4

0.1µF

Figure 16. Low Dropout 3.3V/1.5A Converter

Figure 14. 12V/0.4A SEPIC Converter

Figure 15. Inverting –5V/2A Converter

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

0.1µF

100pF



1000pF



3.3k

R3

100k

SHUTDOWN

D1

MBRS340T3

D2

CMDSH-3



0.1µF

R2

78.7k

R1

24.9k

OUT



100µF

10V

× 2

M2

VN2222

M3

TP0610L

M1

Si4410DY L1*

33µH

SENSE



0.025Ω



22µF

35V

× 2

OUT



–5V



5V TO 22V

1624 F15

*COILCRAFT DO5022P-333

LTC1624

TYPICAL APPLICATIONS

SENSE–

ITH/RUN

VFB

GND



VIN

BOOST

TG

LTC1624

1000pF

100pF

CC

330pF

RC

6.8k

D1

MBRS130LT3

D2

CMDSH-3

CB

0.1µF

R2

35.7k

R1

11k

COUT

100µF

16V

× 2

M1

Si6426DQ L1b*



L1a*

RSENSE

0.05Ω

CIN

22µF

35V

× 2 22µF

35V

VOUT

5V

VOUT

VIN

3.6V TO 18V

1624 F17

* COILTRONICS CTX20-4

0.1µF

Figure 17. 5V/1A SEPIC Converter with Output Derived Boost Voltage

Figure 18. 24V to 12V/10A Buck Converter with Output-Derived Boost Voltage

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

IN1

, C

IN2



1000µF

35V

× 2



13V TO

28V

D1*



0.1µF

C5

3.3µF

50V

C4, 0.1µF

SENSE2

, 0.015Ω

R1

11k



20k



100pF

M1*

OUT



2700µF

16V

R5

220ΩR2

100k

Z1

IN 755

L1 V

OUT



12V

10A

1624 F18

IN1

, C

IN2

= SANYO 35MV1000GX

C5, C7 = WIMA MKS2

OUT

= SANYO 16MV2700GX

D1 = MOTOROLA MBR2535CT

L1 = PULSE ENGINEERING PO472



M1 = INTERNATIONAL RECTIFIER IRL3803

SENSE1

, R

SENSE2

= IRC LR2010-01-R015-F

* BOTH D1 AND M1 MOUNTED TO SAME

THERMALLOY #6399B HEAT SINK



SENSE1

, 0.015Ω

C7

3.3µF

50V

C9

0.1µF

C10

220pF

D2

MBR0540

LTC1624

TYPICAL APPLICATIONS

Figure 20. 12V to 24V/5A Boost Converter

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

C3

100pF C4

1500pF



100µF

16V



9V TO

15V

OUT



24V

D1*



0.1µF

C5

0.1µF

R2, 1M, 1%

SENSE



0.005Ω, 5%

R1

52.3k

R5

750Ω

0.5W



27k



4700pF

M1*

OUT1



1000µF

35V

OUT2



1000µF

35V

Z1

IN755

7.5V

L1

10µH

1624 F20

= KEMET T495X107M016AS

OUT1

, C

OUT2

= SANYO 35MV 1000GX

D1 = MOTOROLA MBR2535CT



L1 = MAGNETICS CORE #55930AZ WINDING = 8T#14BIF

M1 = INTERNATIONAL RECTIFIER IRL 3803

SENSE

= IRC OAR-3, 0.005Ω, 5%

*BOTH D1 AND Q1 MOUNTED ON

THERMALLOY MODEL 6399 HEAT SINK

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

C3

100pF



22µF

35V



20V TO

32V



0.1µF

C5

0.1µF

R2, 1M, 1%

SENSE



0.025Ω

R1

13.3k



6.8k



820pF

OUT



100µF

100V

L1

47µH

OUT



90V

0.5A

1624 F19

= KEMET T495X226M035AS

OUT

= SANYO 100MV100GX

D1 = MOTOROLA MBRS1100



L1 = COILCRAFT D05022P-473

M1 = INTERNATIONAL RECTIFIER IRL 540NS

SENSE

= IRC LR2010-01-R025-F



Figure 19. 24V to 90V at 0.5A Boost Converter

LTC1624

TYPICAL APPLICATIONS

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

C4

100pF

IN1

, C

IN2



22µF

35V

× 2



13V TO

28V +V

D1

MBRS340



0.1µF

C10

0.1µFC11

0.1µF

C12

1µF

C9

100pF

C13

0.1µF

C5, 0.1µF

SENSE



0.033Ω

R1

3.92k

R6

10k

R7

56k

R8

CURRENT

ADJ

R2

35.7k



10k



330pF

OUT



100µF

16V

× 2

L1

27µHR4

0.025ΩV

OUT



12V

1624 F21



IN1

, C

IN2

= KEMET T495X226M035AS

L1 = SUMIDA CDRH127-270

SENSE

= IRC LR2010-01-R033-F

R4 = IRC LR2010-01-R025-F

M1 = SILICONIX Si4412DY

Q2 = MOTOROLA MMBT A14



C14, 0.01µF

SENSE

OUT



GND

–IN



AVE

PROG



+IN

1

2

3

8

7

6

LTC1620

OUT

NC/ADJ

GND

NC



IN

NC

SHDN

1

2

3

8

7

6

LT1121-5

Figure 21. 12V/3A Adjustable Current Power Supply for Battery Charger or Current Source Applications

LTC1624

TYPICAL APPLICATIONS

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 represen-

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

1234

0.150 – 0.157**

(3.810 – 3.988)

8765

0.189 – 0.197*

(4.801 – 5.004)

0.228 – 0.244

(5.791 – 6.197)

0.016 – 0.050

0.406 – 1.270

0.010 – 0.020

(0.254 – 0.508)× 45°

0°– 8° TYP

0.008 – 0.010

(0.203 – 0.254)

SO8 0996

0.053 – 0.069

(1.346 – 1.752)

0.014 – 0.019

(0.355 – 0.483)

0.004 – 0.010

(0.101 – 0.254)

0.050

(1.270)

TYP

DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH 

SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE

DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD 

FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE



*

PACKAGE DESCRIPTION

Dimensions in inches (millimeters) unless otherwise noted.

S8 Package

8-Lead Plastic Small Outline (Narrow 0.150)

(LTC DWG # 05-08-1610)

Figure 22. High Current 3.3V/6.5A Converter

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

1000pF

0.1µF

100pF



680pF



3.3k

D1

MBRD835L



0.1µF

R2

35.7k

R1

20k

OUT



100µF

10V

× 3

M1** L1*

8µH

SENSE



0.015Ω



22µF

35V

× 3

OUT



3.3V

6.5A



4.8V TO 28V

1624 F22

* PANASONIC 12TS-7ROLB

** SILICONIX SUD50N03-10

LTC1624

1624f LT/TP 0198 4K • PRINTED IN USA

 LINEAR TECHN OLOGY CORPORATION 1997

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

●

(408) 432-1900

FAX: (408) 434-0507

●

TELEX: 499-3977

●

www.linear-tech.com

TYPICAL APPLICATION

PART NUMBER DESCRIPTION COMMENTS

LTC1147 High Efficiency Step-Down Controller 100% DC, Burst Mode Operation, 8-Pin SO

and PDIP

LTC1148HV/LTC1148 High Efficiency Synchronous Step-Down Controllers 100% DC, Burst Mode Operation, V

< 20V

LTC1149 High Efficiency Synchronous Step-Down Controller 100% DC,Std Threshold MOSFETs, V

< 48V

LTC1159 High Efficiency Synchronous Step-Down Controller 100% DC, Logic Level MOSFETs, V

< 40V

LTC1174 Monolithic 0.6A Step-Down Switching Regulator 100% DC, Burst Mode Operation, 8-Pin SO

LTC1265 1.2A Monolithic High Efficiency Step-Down Switching Regulator 100% DC, Burst Mode Operation, 14-Pin SO

LTC1266 High Efficiency Synchronous Step-Down Controller, N-Channel Drive 100% DC, Burst Mode Operation, V

< 20V

LT®1375/LT1376 1.5A, 500kHz Step-Down Switching Regulators High Frequency

LTC1433/LTC1434 Monolithic 0.45A Low Noise Current Mode Step-Down Switching Regulators 16- and 20-Pin Narrow SSOP

LTC1435 High Efficiency Low Noise Synchronous Step-Down Controller, Burst Mode Operation, 16-Pin Narrow SO

N-Channel Drive

LTC1436/LTC1436-PLL High Efficiency Low Noise Synchronous Step-Down Controllers, Adaptive PowerTM Mode, 20- and 24-Pin SSOP

N-Channel Drive

LTC1474/LTC1475 Ultralow Quiesent Current Step-Down Monolithic Switching Regulators 100% DC, 8-Pin MSOP, V

< 20V

Adaptive Power is a trademark of Linear Technology Corporation.

RELATED PARTS

Figure 23. 5V to 3.3V/10A Converter (Surface Mount)

SENSE

–



/RUN



GND



BOOST

TG

LTC1624

10k



0.1µF

C2

100pF



100µF

10V

× 4

C4, 0.1µF

C3, 0.033µF

SENSE



0.0082Ω



6.8k



820pF

OUT



470µF

6.3V

× 2

L1

1.68µH+V

OUT



3.3V

10A



4.5V TO

5.5V

OUT



RTN

1624 F23

(× 4) = KEMET T495D107M010AS

OUT

(× 2) = AVX TPSV477M006R0055

D1 = MOTOROLA MBRB2515L

D2 = MOTOROLA MBR0520



L1 = PULSE ENGINEERING PE53691

M1 = INTERNATIONAL RECTIFIER IRL3803S

Q2 = MOTOROLA MMBTA14LT1 

SENSE

= IRC OAR3-R0082

R3, 10Ω

C8

100pF

R1

20k

R2

35.7k