LTC3129-1_15 Datasheet, PDF(19/30 Page) Linear Technology – 15V, 200mA Synchronous Buck-Boost DC/DC Converter with 1.3A Quiescent Current

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LTC3129-1_15 Datasheet, PDF (19/30 Pages) Linear Technology – 15V, 200mA Synchronous Buck-Boost DC/DC Converter with 1.3A Quiescent Current

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LTC3129-1

Applications Information

at large step-up ratios, the output current capability can

also be limited by the total resistive losses in the power

stage. These losses include, switch resistances, inductor

DC resistance and PCB trace resistance. Avoid inductors

with a high DC resistance (DCR) as they can degrade the

maximum output current capability from what is shown

in the Typical Performance Characteristics section and

from the Typical Application circuits.

As a guideline, the inductor DCR should be significantly

less than the typical power switch resistance of 750mÎ©

each. The only exceptions are applications that have a

maximum output current requirement much less than

what the LTC3129-1 is capable of delivering. Generally

speaking, inductors with a DCR in the range of 0.15Î© to

0.3Î© are recommended. Lower values of DCR will improve

the efficiency at the expense of size, while higher DCR

values will reduce efficiency (typically by a few percent)

while allowing the use of a physically smaller inductor.

Different inductor core materials and styles have an impact

on the size and price of an inductor at any given current

rating. Shielded construction is generally preferred as it

minimizes the chances of interference with other circuitry.

The choice of inductor style depends upon the price, sizing,

and EMI requirements of a particular application. Table 2

provides a wide sampling of inductors that are well suited

to many LTC3129-1 applications.

Table 2. Recommended Inductors

VENDOR

PART

Coilcraft

www.coilcraft.com

EPL2014, EPL3012, EPL3015, XFL3012

LPS3015, LPS3314

Coiltronics

SDH3812, SD3814

www.cooperindustries.com SD3114, SD3118

Murata

www.murata.com

LQH3NP

LQH32P

LQH44P

Sumida

www.sumida.com

CDRH2D16, CDRH2D18

CDRH3D14, CDRH3D16

Taiyo-Yuden

www.t-yuden.com

NR3012T, NR3015T, NRS4012T

BRC2518

TDK

www.tdk.com

VLS3012, VLS3015

VLF302510MT, VLF302512MT

Toko

www.tokoam.com

DB3015C, DB3018C, DB3020C

DP418C, DP420C, DEM2815C,

DFE322512C, DFE252012C

WÃ¼rth

www.we-online.com

WE-TPC 2813, WE-TPC 3816,

WE-TPC 2828

Recommended inductor values for different operating

voltage ranges are given in Table 3. These values were

chosen to minimize inductor size while maintaining an

acceptable amount of inductor ripple current for a given

VIN and VOUT range.

Table 3. Recommended Inductor and Output Capacitor Values

VIN AND VOUT RANGE

RECOMMENDED MAXIMUM RECOMMENDED

INDUCTOR TOTAL OUTPUT CAPACITOR

VALUES

VALUE FOR PWM MODE

OPERATION AT LIGHT LOAD

(<15mA, PWM PIN HIGH)

VIN and VOUT Both < 4.5V 3.3ÂµH to 4.7ÂµH

10ÂµF

VIN and VOUT Both < 8V 4.7ÂµH to 6.8ÂµH

10ÂµF

VIN and VOUT Both < 11V 6.8ÂµH to 8.2ÂµH

10ÂµF

VIN and VOUT Up to 15V 8.2ÂµH to 10ÂµH

10ÂµF

Due to the fixed, internal loop compensation and feedback

divider provided by the LTC3129-1, there are limitations to

the maximum recommended total output capacitor value in

applications that must operate in PWM mode at light load

(PWM pin pulled high with minimum load currents less

than ~15mA). In these applications, a maximum output

capacitor value, shown in Table 3, is recommended. For

applications that must operate in PWM mode at light load

with higher values of output capacitance, the LTC3129 is

recommended. Its external feedback pin allows the use

of additional feedforward compensation for improved

light-load stability under these conditions.

Note that for applications where Burst Mode operation

is enabled (PWM pin grounded), the output capacitor

value can be increased without limitation regardless of

the minimum load current or inductor value.

Output Capacitor Selection

A low effective series resistance (ESR) output capacitor

of 4.7ÂµF minimum should be connected at the output of

the buck-boost converter in order to minimize output volt-

age ripple. Multilayer ceramic capacitors are an excellent

option as they have low ESR and are available in small

footprints. The capacitor value should be chosen large

enough to reduce the output voltage ripple to acceptable

levels. Neglecting the capacitorâs ESR and ESL (effec-

tive series inductance), the peak-to-peak output voltage

ripple in PWM mode can be calculated by the following

31291fb

For more information www.linear.com/LTC3129-1

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