Datasheet

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MaximIntegrated

│

MAX15062 60V, 300mA, Ultra-Small, High-Efciency,

Synchronous Step-Down DC-DC Converters

Reset Output (RESET)

The device includes an open-drain RESET output to

monitor the output voltage. RESET goes high impedance

2ms after the output rises above 95% of its nominal set

value and pulls low when the output voltage falls below

92% of the set nominal regulated voltage. RESET asserts

low during the hiccup timeout period.

Startup into a Prebiased Output

The device is capable of soft-start into a prebiased out-

put, without discharging the output capacitor in both the

PFM and forced-PWM modes. Such a feature is useful in

applications where digital integrated circuits with multiple

rails are powered.

Operating Input Voltage Range

The maximum operating input voltage is determined by

the minimum controllable on-time and the minimum oper-

ating input voltage is determined by the maximum duty

cycle and circuit voltage drops. The minimum and maxi-

mum operating input voltages for a given output voltage

should be calculated as follows:

OUT OUT DCR

INMIN OUT

MAX

V (I (R 0.5))

V (I 1.0)

+× +

= +×

OUT

INMAX

ONMIN SW

where V

OUT

is thesteady-state outputvoltage, I

OUT

themaximumloadcurrent,R

DCR

is the DC resistance of

the inductor, f

is the switching frequency (max), D

MAX

is maximum duty cycle (0.9), and t

ONMIN

is the worst-

case minimum controllable switch on-time (130ns).

Overcurrent Protection/Hiccup Mode

The device is provided with a robust overcurrent

protection scheme that protects the device under over-

load and output short-circuit conditions. A cycle-by-cycle

peak current limit turns off the high-side MOSFET when-

ever the high-side switch current exceeds an internal limit

of 0.56A (typ). A runaway current limit on the high-side

switch current at 0.66A (typ) protects the device under

high input voltage, and short-circuit conditions when

there is insufficient output voltage available to restore the

inductor current that was built up during the on period of

the step-down converter. One occurrence of the runaway

current limit triggers a hiccup mode. In addition, if due

to a fault condition, output voltage drops to 65% (typ) of

its nominal value any time after soft-start is complete,

hiccupmodeistriggered.Inhiccupmode,theconverter

is protected by suspending switching for a hiccup timeout

period of 131ms. Once the hiccup timeout period expires,

soft-start isattempted again. Hiccup mode of operation

ensures low power dissipation under output short-circuit

conditions.

Care should be taken in board layout and system wiring

to prevent violation of the absolute maximum rating of the

FB/V

OUT

pin under short-circuit conditions. Under such

conditions, it is possible for the ceramic output capacitor

to oscillate with the board or wiring inductance between

the output capacitor or short-circuited load, thereby caus-

ing the absolute maximum rating of FB/V

OUT

(-0.3V) to

be exceeded. The parasitic board or wiring inductance

should be minimized and the output voltage waveform

under short-circuit operation should be verified to ensure

the absolute maximum rating of FB/V

OUT

is not exceeded.

Thermal Overload Protection

Thermal overload protection limits the total power dis-

sipation in the device. When the junction temperature

exceeds +166°C, an on-chip thermal sensor shuts down

the device, turns off the internal power MOSFETs, allow-

ing the device to cool down. The thermal sensor turns the

device on after the junction temperature cools by 10°C.

Applications Information

Inductor Selection

A low-loss inductor having the lowest possible DC resis-

tance that fits in the allotted dimensions should be selected.

The saturation current (I

SAT

) must be high enough to

ensure that saturation cannot occur below the maximum

current-limitvalue(I

PEAK-LIMIT

) of 0.56A (typ). The required

inductance for a given application can be determined from

the following equation:

L = 9.3 x V

OUT

whereLisinductanceinµH andV

OUT

is output voltage.

Once the L value is known, the next step is to select the

right core material. Ferrite and powdered iron are com-

monly available core materials. Ferrite cores have low

core losses and are preferred for high-efficiency designs.

Powdered iron cores have more core losses and are rela-

tively cheaper than ferrite cores. See Table 1 to select the

inductors for typical applications.