AAT2514 Datasheet, PDF(10/16 Page) Advanced Analogic Technologies

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AAT2514 Datasheet, PDF (10/16 Pages) Advanced Analogic Technologies – Dual Channel 600mA Step-Down Converter

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AAT2514

Dual Channel 600mA Step-Down Converter

Inductor Selection

For most designs, the AAT2514 operates with

inductor values of 1ÂµH to 4.7ÂµH. Low inductance

values are physically smaller, but require faster

switching, which results in some efficiency loss.

The inductor value can be derived from the follow-

ing equation:

VOUT Â· (VIN - VOUT)

VIN Â· âIL Â· fOSC

Where âIL is inductor ripple current. Large value

inductors lower ripple current and small value

inductors result in high ripple currents. Choose

inductor ripple current approximately 35% of the

maximum load current 600mA, or âIL = 210mA.

For output voltages above 2.0V, when light-load

efficiency is important, the minimum recommended

inductor size is 2.2ÂµH. For optimum voltage-posi-

tioning load transients, choose an inductor with DC

series resistance in the 50mâ¦ to 150mâ¦ range. For

higher efficiency at heavy loads (above 200mA), or

minimal load regulation (with some transient over-

shoot), the resistance should be kept below

100mâ¦. The DC current rating of the inductor

should be at least equal to the maximum load cur-

rent plus half the ripple current to prevent core sat-

uration (600mA + 105mA). Table 2 lists some typi-

cal surface mount inductors that meet target appli-

cations for the AAT2514.

Manufacturer's specifications list both the inductor

DC current rating, which is a thermal limitation, and

the peak current rating, which is determined by the

saturation characteristics. The inductor should not

show any appreciable saturation under normal load

conditions. Some inductors may meet the peak and

average current ratings yet result in excessive loss-

es due to a high DCR. Always consider the losses

associated with the DCR and its effect on the total

converter efficiency when selecting an inductor. For

example, the 2.2ÂµH CR43 series inductor selected

from Sumida has a 71.2mâ¦ DCR and a 1.75ADC

current rating. At full load, the inductor DC loss is

25mW which gives a 2.8% loss in efficiency for a

600mA, 1.5V output.

Slope Compensation

The AAT2514 step-down converter uses peak cur-

rent mode control with a unique adaptive slope

compensation scheme to maintain stability with

lower value inductors for duty cycles greater than

50%. Using lower value inductors provides better

overall efficiency and also makes it easier to stan-

dardize on one inductor for different required output

voltage levels. In order to do this and keep the

step-down converter stable when the duty cycle is

greater than 50%, the AAT2514 separates the

slope compensation into 2 phases. The required

slope compensation is automatically detected by

an internal circuit using the feedback voltage VFB

before the error amp comparison to VREF.

Part

CDRH2D11/HP

Sumida CDRH4D18

Toko D312C

L (ÂµH)

1.5

2.2

3.3

4.7

1.0

2.2

3.3

4.7

1.5

2.2

3.3

4.7

Max DCR (mâ¦)

120

173

238

110

162

120

140

180

240

Rated DC Current (A)

1.35

1.10

0.9

0.75

1.72

1.32

1.04

0.84

1.29

1.14

0.98

0.79

Table 2: Typical Surface Mount Inductors.

Size WxLxH (mm)

3.2x3.2x1.2

4.7x4.7x2.0

3.6x3.6x1.2

2514.2007.06.1.0

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