MAX1624 Datasheet, PDF(18/24 Page) Maxim Integrated Products – High-Speed Step-Down Controllers with Synchronous Rectification for CPU Power

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MAX1624 Datasheet, PDF (18/24 Pages) Maxim Integrated Products – High-Speed Step-Down Controllers with Synchronous Rectification for CPU Power

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High-Speed Step-Down Controllers with

Synchronous Rectification for CPU Power

VOUT

MAX1625

LOAD

AGND

PLACE VERY CLOSE

TO MAX1625

Figure 7. MAX1625 Adjustable Output Operation

A good compromise between size and loss is a 45%

ripple current to load current ratio (LIR = 0.45), which

corresponds to a peak inductor current 1.23 times

higher than the DC load current.

( ) VOUT VIN(MAX) â VOUT

VIN(MAX) x fOSC x IOUT x LIR

where f is the switching frequency, between 100kHz

and 1MHz; IOUT is the maximum DC load current; and

LIR is the ratio of AC to DC inductor current (typically

0.45). The exact inductor value is not critical and can be

adjusted to make trade-offs among size, transient

response, cost, and efficiency. Although lower inductor

values minimize size and cost, they also reduce efficien-

cy due to higher peak currents. In general, higher

inductor values increase efficiency, but at some point

resistive losses due to extra turns of wire exceed the

benefit gained from lower AC current levels. Load-

transient response can be adversely affected by

high inductor values, especially at low (VIN - VOUT)

differentials.

The peak inductor current at full load is 1.23 x IOUT if

the previous equation is used; otherwise, the peak cur-

rent can be calculated using the following equation:

( ) VOUT VIN(MAX) â VOUT

IPEAK = IOUT + 2fOSC x L x VIN(MAX)

The inductorâs DC resistance is a key parameter for effi-

cient performance, and should be less than the current-

sense resistor value.

Calculating the Current-Sense

Resistor Value

Calculate the current-sense resistor value according to

the worst-case minimum current-limit threshold voltage

(from the Electrical Characteristics) and the peak

inductor current required to service the maximum load.

Use IPEAK from the equation in the section Specifying

the Inductor.

RSENSE =

85mV

IPEAK

The high inductance of standard wire-wound resistors

can degrade performance. Low-inductance resistors,

such as surface-mount power metal-strip resistors, are

preferred. The current-sense resistorâs power rating

should be higher than the following:

RPOWER RATING

(115mV)2

RSENSE

In high-current applications, connect several resistors

in parallel as necessary, to obtain the desired resis-

tance and power rating.

Selecting the Output Filter Capacitor

Output filter capacitor values are generally determined

by effective series resistance (ESR) and voltage-rating

requirements, rather than by the actual capacitance

value required for loop stability. Due to the high switch-

ing currents and demanding regulation requirements in

a typical MAX1624/MAX1625 application, use only spe-

cialized low-ESR capacitors intended for switching-

regulator applications, such as AVX TPS, Sprague

595D, Sanyo OS-CON, or Nichicon PL series. Do not

use standard aluminum-electrolytic capacitors, which

can cause high output ripple and instability due to high

ESR. The output voltage ripple is usually dominated by

the filter capacitorâs ESR, and can be approximated as

IRIPPLE x RESR. To ensure stability, the capacitor must

meet both minimum capacitance and maximum ESR

values as given in the following equations:

COUT >

ï£«

VREF ï£¬1 +

ï£

VOUT

VIN(MIN)

ï£¶

ï£·

ï£¸

VOUT x RSENSE x fOSC

RESR < RSENSE

18 ______________________________________________________________________________________

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