MAX1534 Datasheet, PDF(14/16 Page) Maxim Integrated Products – High-Efficiency, Triple-Output, Keep-Alive Power Supply for Notebook Computers

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MAX1534 Datasheet, PDF (14/16 Pages) Maxim Integrated Products – High-Efficiency, Triple-Output, Keep-Alive Power Supply for Notebook Computers

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High-Efficiency, Triple-Output, Keep-Alive

Power Supply for Notebook Computers

input capacitor that exhibits less than +10Â°C tempera-

ture rise at the RMS input current for optimal circuit

longevity.

Diode Selection

The current in the external diode (D1 in Figure 1)

changes abruptly from zero to its peak value each time

the LX switch turns off. To avoid excessive losses, the

diode must have a fast turn-on time and a low forward

voltage. Make sure that the diodeâs peak current rating

exceeds the peak current set by the current limit, and

that its breakdown voltage exceeds VIN. Use Schottky

diodes when possible.

Linear Regulators

Capacitor Selection and LDO Stability

Use a 2.2ÂµF capacitor on the MAX1534 LDOIN pin and

a 2.2ÂµF capacitor on the outputs. Larger input capaci-

tor values and lower ESRs provide better supply-noise

rejection and line-transient response. To reduce noise,

improve load transients, and for loads up to 160mA,

use larger output capacitors (up to 10ÂµF). For stable

operation over the full temperature range and with load

currents up to 80mA, use 2.2ÂµF. Note that some ceram-

ic dielectrics exhibit large capacitance and ESR varia-

tion with temperature. With dielectrics such as Z5U and

Y5V, it may be necessary to use 4.7ÂµF or more to

ensure stability at temperatures below -10Â°C. With X7R

or X5R dielectrics, 2.2ÂµF is sufficient at all operating

temperatures. These regulators are optimized for

ceramic capacitors, and tantalum capacitors are not

recommended.

Use a 0.01ÂµF bypass capacitor at BP for low output volt-

age noise. Increasing the capacitance slightly decreas-

es the output noise, but increases the startup time.

Applications Information

Buck Dropout Performance

A step-down converterâs minimum input-to-output volt-

age differential (dropout voltage) determines the lowest

usable supply voltage. In battery-powered systems,

this limits the useful end-of-life battery voltage. To maxi-

mize battery life, the MAX1534 operates with duty

cycles up to 100%, which minimizes the dropout volt-

age and eliminates switching losses while in dropout.

When the supply voltage approaches the output volt-

age, the P-channel MOSFET remains on continuously to

supply the load.

For a step-down converter with 100% duty cycle,

dropout depends on the MOSFET drain-to-source on-

resistance and inductor series resistance; therefore, it

is proportional to the load current:

VDROPOUT(BUCK) = IOUT3 â (RLX + RINDUCTOR)

LDO PSRR

The MAX1534âs linear regulators are designed to deliv-

er low dropout voltages and low quiescent currents in

battery-powered systems. Power-supply rejection is

55dB at low frequencies and rolls off above 20kHz.

(See the LDO PSRR vs. Frequency graph in the Typical

Operating Characteristics.)

To improve supply-noise rejection and transient

response, increase the values of the input and output

bypass capacitors or use passive filtering techniques.

LDO Dropout Voltage

A linear regulatorâs minimum input-output voltage differ-

ential (or dropout voltage) determines the lowest usable

supply voltage. Because the MAX1534 uses a P-chan-

nel MOSFET pass transistor, its dropout voltage is a

function of drain-to-source on-resistance (RDS(ON))

multiplied by the load current (see LDO Dropout

Voltage vs. Load Current in the Typical Operating

Characteristics).

PC Board Layout Guidelines

High switching frequencies and large peak currents

make PC board layout an important part of the design.

Poor layout introduces switching noise into the feedback

path, resulting in jitter, instability, or degraded perfor-

mance. High current traces, highlighted in the Typical

Application Circuit (Figure 1), should be as short and

wide as possible. Additionally, the current loops formed

by the power components (CIN, COUT3, L1, and D1)

should be as short as possible to avoid radiated noise.

Connect the ground pins of these power components at

a common node in a star-ground configuration.

Separate the noisy traces, such as the LX node, from

the feedback network with grounded copper.

Furthermore, keep the extra copper on the board and

integrate it into a pseudoground plane. When using

external feedback, place the resistors as close to the

feedback pin as possible to minimize noise coupling.

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