MAX1649_09 Datasheet, PDF(9/12 Page) Maxim Integrated Products – 5V/3.3V or Adjustable, High-Efficiency, Low-Dropout, Step-Down DC-DC Controllers

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MAX1649_09 Datasheet, PDF (9/12 Pages) Maxim Integrated Products – 5V/3.3V or Adjustable, High-Efficiency, Low-Dropout, Step-Down DC-DC Controllers

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5V/3.3V or Adjustable, High-Efficiency,

Low-Dropout, Step-Down DC-DC Controllers

To maximize efficiency and reduce the size and cost

of external components, minimize the peak current.

However, since the available output current is a func-

tion of the peak current, the peak current must not be

too low.

To choose the proper current-sense resistor for a par-

ticular output voltage, determine the minimum input

voltage and the maximum load current. Next, refer-

ring to Figures 5a or 5b, using the minimum input volt-

age, find the curve with the largest sense resistor that

provides sufficient output current. It is not necessary

to perform worst-case calculations. These curves take

into account the sense-resistor (Â±5%) and inductor

(47ÂµH Â±10%) values, the diode drop (0.4), and the

ICâs current-sense trip level (85mV); an external MOS-

FET on-resistance of 0.07Î© is assumed for VGS = -5V.

Standard wire-wound and metal-film resistors have an

inductance high enough to degrade performance.

Surface-mount (chip) resistors have very little inductance

and are well suited for use as current-sense resistors.

A U-shaped wire resistor made by IRC works well in

through-hole applications. Because this resistor is a

band of metal shaped as a âUâ, its inductance is less

than 10nH (an order of magnitude less than metal film

resistors). Resistance values between 5mÎ© and 0.1Î©

are available (see Table 1).

Inductor Selection

The MAX1649/MAX1651 operate with a wide range of

inductor values, although for most applications coils

between 10ÂµH and 68ÂµH take best advantage of the con-

trollersâ high switching frequency. With a high inductor

value, the MAX1649/MAX1651 will begin continuous-cur-

rent operation (see Detailed Description) at a lower frac-

tion of full-load current. In general, smaller values pro-

duce higher ripple (see below) while larger values require

larger size for a given current rating.

In both the continuous and discontinuous modes, the

lower limit of the inductor is important. With a too-small

inductor value, the current rises faster and overshoots the

desired peak current limit because the current-limit com-

parator has a finite response time (300ns). This reduces

efficiency and, more importantly, could cause the current

rating of the external components to be exceeded.

Calculate the minimum inductor value as follows:

(V+(max) - VOUT) x 0.3Âµs

L(min) = ââââââââââââââ

ÎI x ILIM

where ÎI is the inductor-current overshoot factor,

ILIM = VCS/RSENSE, and 0.3Âµs is the time it takes the com-

parator to switch. Set ÎI = 0.1 for an overshoot of 10%.

For highest efficiency, use a coil with low DC resis-

tance; a value smaller than 0.1V/ILIM works best. To

minimize radiated noise, use a toroid, pot core, or

shielded-bobbin inductor. Inductors with a ferrite core

or equivalent are recommended. Make sure the induc-

torâs saturation-current rating is greater than ILIM(max).

However, it is generally acceptable to bias the inductor

into saturation by about 20% (the point where the

inductance is 20% below its nominal value).

3.0

VOUT = 5V

2.5

2.0

1.5

1.0

0.5

rs = 0.030

rs = 0.040

rs = 0.050

rs = 0.060

rs = 0.080

rs = 0.100

5.0 5.4 5.8 6.2 6.6 16.0

INPUT VOLTAGE (V)

3.0

VOUT = 3.3V

2.5

2.0

1.5

1.0

0.5

rs = 0.030

rs = 0.040

rs = 0.050

rs = 0.060

rs = 0.080

rs = 0.100

3.0 3.4 3.8 4.2 4.6 16.0

INPUT VOLTAGE (V)

Figure 5a. MAX1649 Current-Sense Resistor Graph

Figure 5b. MAX1651 Current-Sense Resistor Graph

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