MAX1623 Datasheet, PDF(10/12 Page) Maxim Integrated Products – 3A, Low-Voltage, Step-Down Regulator with Synchronous Rectification and Internal Switches

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MAX1623 Datasheet, PDF (10/12 Pages) Maxim Integrated Products – 3A, Low-Voltage, Step-Down Regulator with Synchronous Rectification and Internal Switches

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3A, Low-Voltage, Step-Down Regulator with

Synchronous Rectification and Internal Switches

flow. A copper area of 0.4in2 showed thermal resis-

tance of 60Â°C/W.

Airflow over the IC can significantly reduce Î¸JA.

Power Dissipation

The MAX1623âs power dissipation consists mostly of con-

duction losses in the two internal power switches. Power

dissipation due to supply current in the control section

and average current used to charge and discharge the

gate capacitance of the two power switches is less than

30mW at 300kHz. This number is reduced when switch-

ing frequency is reduced as the part enters Idle Mode.

Combined conduction loss in the two power switches is

calculated by:

PD = ILOAD2 (RON)

where RON = 100mâ¦ (max).

The Î¸JA required to deliver this amount of power is cal-

culated by:

Î¸JA = (TJ(MAX) â TA(MAX)) / PD

where:

TJ(MAX) = maximum allowed junction temperature

TA(MAX)= maximum ambient temperature expected

Applications Information

Inductor L1

The inductor value can be adjusted to optimize the

design for size, cost, and efficiency. Three key inductor

parameters must be specified: inductance value (L),

peak current (IPEAK), and DC resistance (RDC). The fol-

lowing equation includes a constant, denoted as LIR,

which is the ratio of inductor peak-to-peak AC current

to DC load current. A higher value of LIR allows smaller

inductance, but results in higher losses and ripple. A

good compromise between size and losses is found at

a 30% ripple current to load current ratio (LIR = 0.3),

which corresponds to a peak inductor current 1.15

times the DC load current:

â â L = VOUT(VIN(MAX) â VOUT)

VIN(MAX) f (IOUT) (LIR)

where:

f = switching frequency

IOUT = maximum DC load current

LIR = ratio of AC to DC inductor current, typically

0.3

Table 2. Suggested Values (VIN = 5V,

IO = 3A, f = 300kHz)

VOUT

(V)

TOFF

(Âµs)

RTOFF

(kâ¦)

(ÂµH)

3.3

1.10

120

4.7

2.5

1.67

180

4.7

1.8

2.16

240

4.7

1.5

2.38

260

3.9

1.1

2.68

280

3.3

The peak inductor current at full load is 1.15 â¢ IOUT if

the above equation is used; otherwise, the peak current

can be calculated by:

â â â IPEAK =

IOUT

VOUT(VIN(MAX) â VOUT)

2 f L VIN(MAX)

The inductorâs DC resistance is a key parameter for effi-

ciency and must be minimized, preferably to less than

25mâ¦ at IOUT = 3A. To reduce EMI, use a shielded

inductor.

Input and Output Filter

Capacitors (C1, C2)

Use a low-ESR input capacitor according to the input

ripple-current requirements and voltage rating.

( ) IRIPPLE

ï£«

ILOAD

ï£¬

ï£ï£¬

VOUT

VIN

VOUT

ï£¶

ï£·

VIN

ï£¸ï£·

In addition to C1, place a 10ÂµF ceramic bypass capacitor

from the power input (pin 2, 4, 6) to power ground (pin

15, 17, 19) within 5mm of the IC.

The output filter capacitor determines the output volt-

age ripple and output load-transient response, as well

as the loopâs stability.

The output ripple in continuous-conduction mode is:

â â â VOUT(RPL) = IOUT(MAX)

LIRï£«ï£ï£¬ESRC2 + 2Ï

ï£¶

f C2 ï£¸ï£·

where f is the switching frequency.

10 ______________________________________________________________________________________

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