LTC1871EMS#TRPBF Linear Technology, LTC1871EMS#TRPBF Datasheet - Page 25

LTC1871EMS#TRPBF

Manufacturer Part Number

LTC1871EMS#TRPBF

Description

IC CONTRLR CURRENT MODE 10-MSOP

Manufacturer

Linear Technology

Type

Step-Up (Boost), Flyback, Sepicr

Datasheet

1.LTC1871EMS.pdf (36 pages)

Specifications of LTC1871EMS#TRPBF

Internal Switch(s)

Synchronous Rectifier

Number Of Outputs

Voltage - Output

1.23 ~ 72 V

Current - Output

50mA

Frequency - Switching

50kHz ~ 1MHz

Voltage - Input

2.5 ~ 36 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

10-MSOP, Micro10™, 10-uMAX, 10-uSOP

Number Of Pwm Outputs

On/off Pin

Adjustable Output

Topology

Boost/Buck/Flyback

Switching Freq

50 TO 1000kHz

Duty Cycle

97%

Operating Supply Voltage (max)

36V

Synchronous Pin

Yes

Rise Time

17ns

Fall Time

8ns

Operating Temperature Classification

Industrial

Mounting

Surface Mount

Pin Count

Package Type

MSOP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Power - Output

Lead Free Status / Rohs Status

Compliant

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APPLICATIONS INFORMATION

It is worth noting here that SEPIC converters that operate

at high duty cycles (i.e., that develop a high output volt-

age from a low input voltage) can have very high input

currents, relative to the output current. Be sure to check

that the maximum load current will not overload the input

supply.

SEPIC Converter: Inductor Selection

For most SEPIC applications the equal inductor values

will fall in the range of 10μH to 100μH. Higher values will

reduce the input ripple voltage and reduce the 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 and minimum

input voltage. The peak inductor current can be signiﬁ cantly

higher than the output current, especially with smaller in-

ductors and lighter loads. The following formulas assume

CCM operation and calculate the maximum peak inductor

currents at minimum V

The ripple current in the inductor is typically 20% to 40%

(i.e., a range of ‘χ’ from 0.20 to 0.40) of the maximum

average input current occurring at V

ΔI

the output current results in the following equations for

calculating the inductor value:

By making L1 = L2 and winding them on the same core,

the value of inductance in the equation above is replace

by 2L due to mutual inductance. Doing this maintains the

same ripple current and energy storage in the inductors. For

where:

L =

L1(PEAK)

L2(PEAK)

= ΔI

= •I

IN(MIN)

. Expressing this ripple current as a function of

= 1+

• f

= 1+

O(MAX)

• D

MAX

•

1– D

•I

O(MAX)

MAX

•

IN(MIN)

+ V

IN(MIN)

+ V

and I

O(MAX)

and

example, a Coiltronix CTX10-4 is a 10μH inductor with two

windings. With the windings in parallel, 10μH inductance is

obtained with a current rating of 4A (the number of turns

hasn’t changed, but the wire diameter has doubled). Split-

ting the two windings creates two 10μH inductors with a

current rating of 2A each. Therefore, substituting 2L yields

the following equation for coupled inductors:

Specify the maximum inductor current to safely handle

current rating for the inductor should be checked at the

minimum input voltage (which results in the highest

inductor current) and maximum output current.

SEPIC Converter: Power MOSFET Selection

The power MOSFET serves two purposes in the LTC1871:

it represents the main switching element in the power path,

and its R

for the control loop. Important parameters for the power

MOSFET include the drain-to-source breakdown voltage

(BV

and gate-to-drain charges (Q

the maximum drain current (I

thermal resistances (R

The gate drive voltage is set by the 5.2V INTV

dropout regulator. Consequently, logic-level threshold

MOSFETs should be used in most LTC1871 applications.

If low input voltage operation is expected (e.g., supplying

power from a lithium-ion battery), then sublogic-level

threshold MOSFETs should be used.

The maximum voltage that the MOSFET switch must

sustain during the off-time in a SEPIC converter is equal

to the sum of the input and output voltages (V

As a result, careful attention must be paid to the BV

speciﬁ cations for the MOSFETs relative to the maximum

actual switch voltage in the application. Many logic-level

devices are limited to 30V or less. Check the switching

waveforms directly across the drain and source terminals

of the power MOSFET to ensure the V

the maximum rating for the device.

L(PK)

DS(ON)

L1= L2 =

DSS

speciﬁ ed in the equation above. The saturation

), the threshold voltage (V

) versus gate-to-source voltage, the gate-to-source

DS(ON)

2 • I

IN(MIN)

represents the current sensing element

• f

• D

TH(JC)

MAX

and R

D(MAX)

GS(TH)

and Q

TH(JA)

) and the MOSFET’s

), the on-resistance

LTC1871

, respectively),

remains below

+ V

1871fe

low

DSS

LTC1871EMS#TRPBF Linear Technology, LTC1871EMS#TRPBF Datasheet - Page 25

LTC1871EMS#TRPBF

Specifications of LTC1871EMS#TRPBF

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