AAT1265_0606 Datasheet, PDF(9/13 Page) Advanced Analogic Technologies – Low Voltage 2MHz Step-Up DC/DC Converter in SC70JW Package

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AAT1265_0606 Datasheet, PDF (9/13 Pages) Advanced Analogic Technologies – Low Voltage 2MHz Step-Up DC/DC Converter in SC70JW Package

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AAT1265

Low Voltage 2MHz Step-Up DC/DC

Converter in SC70JW Package

nous MOSFET, forcing DCM operation at light load.

These controls, along with very low quiescent cur-

rent, help to maintain high efficiency over the com-

plete load range without the compromise of

increased output voltage ripple during light load

conditions.

Start-up and Inrush Current Limit

The start-up sequence of the AAT1265 varies

depending upon whether the input voltage is

greater than or less than 2V. Above 1V, a start-up

oscillator operating at 25% duty cycle controls the

synchronous power stage and charges the output

to 2V. For an input voltage greater than 2V, the out-

put is charged at a constant current of 300mA until

the output reaches a voltage level just below the

input voltage. The step-up converter then takes

control and continues to charge the output to the

steady-state voltage. The step-up converter N-

channel switch current is limited to 1A and the typ-

ical start-up time is 2.5ms.

Shutdown and Output Disconnect

A typical synchronous step-up (boost) converter

has a conduction path from the input to the output

via the body diode of the P-channel MOSFET. The

AAT1265 design disconnects this body diode from

the output and eliminates this conduction path.

This enables the AAT1265 to provide true load dis-

connect during shutdown and inrush current limit at

turn-on.

Short-Circuit Protection

The P-channel synchronous MOSFET body diode

disconnect feature also gives the AAT1265 the

ability to provide output short-circuit current limit

protection.

Applications Information

Inductor Selection

The AAT1265 is designed to operate with a 2.2ÂµH

inductor for all input/output voltage combinations.

The inductor saturation current rating should be

greater than the NMOS current limit specification

listed in the Electrical Characteristics table. If nec-

essary, the peak inductor current can exceed the

saturation level by a small amount with no signifi-

cant effect on performance. Table 1 provides a list

of some suggested inductor manufacturers and

their part numbers.

Output and Input Capacitor Selection

Surface mount X5R or X7R ceramic capacitors are

suggested for both the output and the input. For the

output capacitor (C1 in Figure 4) a 4.7ÂµF, 10V, X5R

ceramic capacitor is necessary for stability, tran-

sient response, and ripple performance. The same

0805 sized capacitor is used for the input (C2 of

Figure 4). If desired, a smaller, 0603 sized, 4.7ÂµF,

6.3V, X5R ceramic capacitor can be substituted for

the input capacitor (C2). Suggested ceramic

capacitor suppliers are listed in Table 1.

PCB Layout Guidelines

Figures 1, 2, and 3 display the evaluation board

layout and suggested component placement. Due

to the high switching speed of the AAT1265, it is

important that the evaluation board layout be fol-

lowed. Even the best switch-mode power supply

design cannot overcome the problems that can be

caused by a poor layout.

For the AAT1265, it is necessary that C1 and C2 be

placed as close as possible to the IC with a good

low impedance path to the GND pins of the IC. It

is also good practice to minimize the length of the

trace from the OUT pin to the output inductor. This

prevents switching noise from radiating into other

high noise sensitive, high impedance circuits.

1265.2006.06.1.2

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