lt3579iufd-trpbf Linear Technology Corporation, lt3579iufd-trpbf Datasheet - Page 26

lt3579iufd-trpbf

Manufacturer Part Number

lt3579iufd-trpbf

Description

Lt3579/lt3579-1 6a Boost/inverting Dc/dc Converter With Fault Protection Features

Manufacturer

Linear Technology Corporation

Datasheet

1.LT3579IUFD-TRPBF.pdf (40 pages)

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LT3579/LT3579-1

APPENDIX

Maximum Inductance

Excessive inductance can reduce ripple current to levels

that are difﬁ cult for the current comparator (A4 in the Block

Diagram) to cleanly discriminate, thus causing duty cycle

jitter and/or poor regulation. The maximum inductance

can be calculated by:

where:

Inductor Current Rating

The inductor(s) must have a rating greater than its (their)

peak operating current to prevent inductor saturation, which

would result in catastrophic failure and efﬁ ciency losses.

The maximum inductor current (considering start-up and

steady-state conditions) is given by:

where:

Note that these equations offer conservative results for

the required inductor current ratings. The current ratings

could be lower for applications with light loads, provided

the SS capacitor is sized appropriately to limit inductor

currents at start-up.

L PEAK

L_PEAK

LIM

MAX

MIN_PROP

MAX

= L1 for Boost Topologies (see Figure 6)

= L1 = L2 for Coupled Dual Inductor

= L1 || L2 for Uncoupled Dual Inductor

(

Topologies (see Figures 7 and 8)

LIM

= Peak Inductor Current in L1 for a Boost

= For Hard-Saturation Inductors, 9.4A with

= 100ns (Propagation Delay through the

−

OSC

Topology, or the sum of the Peak

Inductor Currents in L1 and L2 for Dual

Inductor Topologies.

SW1 and SW2 Tied Together, or 5.1A

with just SW1 used. For Soft-Saturation

Inductors, 6A with SW1 and SW2 Tied

Together, or 3.4A with just SW1 used.

Current Feedback Loop).

CESAT

• 0 5 .

•

)

•

MIN PROP

DIODE SELECTION

Schottky diodes, with their low forward voltage drops and

fast switching speeds, are recommended for use with the

LT3579. Choose a Schottky with low parasitic capacitance

to reduce reverse current spikes through the power switch

of the LT3579. The Diodes Inc. MBRM360 is a very good

choice with a 60V reverse voltage rating and an average

forward current of 3A.

OUTPUT CAPACITOR SELECTION

Low ESR (equivalent series resistance) capacitors should

be used at the output to minimize the output ripple voltage.

Multilayer ceramic capacitors are an excellent choice, as

they have an extremely low ESR and are available in very

small packages. X5R or X7R type are preferred, as these

materials retain their capacitance over wide voltage and

temperature ranges. A 22μF to 47μF output capacitor is

sufﬁ cient for most applications, but systems with low

output currents may need only 4.7μF to 22μF. Always

use a capacitor with a sufﬁ cient voltage rating. Many

ceramic capacitors, particularly 0805 or 0603 case sizes,

have greatly reduced capacitance at the desired output

voltage. Tantalum polymer or OS-CON capacitors can be

used, but it is likely that these capacitors will occupy more

board area than a ceramic, and will have higher ESR with

greater output ripple.

INPUT CAPACITOR SELECTION

Ceramic capacitors make a good choice for the input

decoupling capacitor, C

close as possible to the V

that the voltage seen at the V

a nearly ﬂ at DC voltage. A 1μF to 4.7μF input capacitor is

sufﬁ cient for most applications.

A ceramic bypass capacitor, C

as close as possible to the input of the inductor. This

ensures that the inductor ripple current is supplied from

the bypass capacitor and provides a nearly ﬂ at DC voltage

to the input of the voltage converter. A 4.7μF to 10μF input

power capacitor is sufﬁ cient for most applications.

VIN

pin of the LT3579. This ensures

, which should be placed as

PWR

pin of the LT3579 remains

, should also be placed

35791f

lt3579iufd-trpbf Linear Technology Corporation, lt3579iufd-trpbf Datasheet - Page 26

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