LTC3114-1_15 Datasheet, PDF(19/34 Page) Linear Technology – 40V, 1A Synchronous Buck-Boost DC/DC Converter with Programmable Output Current

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LTC3114-1_15 Datasheet, PDF (19/34 Pages) Linear Technology – 40V, 1A Synchronous Buck-Boost DC/DC Converter with Programmable Output Current

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LTC3114-1

APPLICATIONS INFORMATION

A standard application circuit for the LTC3114-1 is shown

on the front page of this data sheet. The appropriate selec-

tion of external components is dependent upon the required

performance of the IC in each particular application given

considerations and trade-offs such as PCB area, input

and output voltage range, output voltage ripple, required

efficiency, thermal considerations and cost. This section

of the data sheet provides some basic guidelines and con-

siderations to aid in the selection of external components

and the design of the applications circuit.

LDO Capacitor Selection

The LDO output of the LTC3114-1 is generated from VIN

by a low dropout linear regulator. The LDO regulator has

been designed for stable operation with a wide range

of output capacitors. For most applications, a low ESR

capacitor of at least 4.7ÂµF should be used. The capacitor

should be located as close to the PLDO pin as possible and

connected to the LDO pin and ground through the shortest

traces possible. PLDO is the regulator output and is also

the internal supply pin for the gate drivers and boost rail

charging diodes. The LDO pin is the supply connection for

the remainder of the control circuitry. The LDO and PLDO

pins must be connected together on the PCB. If the con-

necting trace cannot be made short, an additional 0.1ÂµF

bypass capacitor should be connected between the LDO

pin and ground as close to the package pins as possible.

Inductor Selection

The choice of inductor used in LTC3114-1 application cir-

cuits influences the maximum deliverable output current,

the converter bandwidth, the magnitude of the inductor

current ripple and the overall converter efficiency. The

inductor must have a low DC series resistance or output

current capability and efficiency will be compromised.

Larger inductor values reduce inductor current ripple but

will not increase output current capability as is the case with

peak current mode control as described in the Maximum

Output Current section of this data sheet. Larger value

inductors also tend to have a higher DC series resistance

for a given case size, which will have a negative impact on

efficiency. Larger values of inductance will also lower the

right half plane (RHP) zero frequency when operating in

boost mode, which requires the converter bandwidth to be

set lower in frequency, slowing the converterâs response

to load transients. Nearly all LTC3114-1 application cir-

cuits deliver the best performance with an inductor value

between 4.7ÂµH and 15ÂµH. Buck mode-only applications

can use the larger inductor values as they are unaffected

by the RHP zero, while mostly boost applications generally

require inductance on the low end of this range depending

on how deep they will operate in boost mode.

Regardless of inductor value, the saturation current rating

should be selected such that it is greater than the worst-case

average inductor current plus half of the ripple current. The

peak-to-peak inductor current ripple for each operational

mode can be calculated from the following formula, where

f is the switching frequency (1.2MHz), L is the inductance

in ÂµH and tLOW is the switch pin minimum low time in

Âµs. The switch pin minimum low time is typically 0.05Âµs.

âIL(P-P )(BUCK )

VOUT

ï£«

ï£ï£¬

VIN

â VOUT

VIN

ï£¶

ï£¸ï£·

ï£«

ï£ï£¬

1â

tLOW

ï£¶

ï£¸ï£·

Amps

âIL(P-P)(BOOST)

VIN

ï£«

ï£ï£¬

VOUT â VIN

VOUT

ï£¶

ï£¸ï£·

ï£«

ï£ï£¬

1â

tLOW

ï£¶

ï£¸ï£·

Amps

It should be noted that the worst-case inductor peak-to-

peak inductor ripple current occurs when the duty cycle

in buck mode is maximum (highest VIN) and in boost

mode when the duty cycle is 50% (VOUT = 2 â¢ VIN). As an

example, if VIN (minimum) = 3.6V and VIN (maximum) =

40V, VOUT = 5V and L = 6.8ÂµH, the peak-to-peak inductor

ripples at the voltage extremes (40V VIN for buck and 3.6V

VIN for boost) are:

Buck = 504mA peak-to-peak

Boost = 116mA peak-to-peak

One-half of this inductor ripple current must be added to

the highest expected average inductor current in order to

select the proper saturation current rating for the inductor.

In addition to its influence on power conversion efficiency,

the inductor DC resistance can also impact the maximum

output current capability of the buck-boost converter par-

ticularly at low input voltages. In buck mode, the output

current of the buck-boost converter is primarily limited

by the inductor current reaching the average current limit

31141fa

For more information www.linear.com/LTC3114-1

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