Design procedure – Rainbow Electronics MAX8737 User Manual

Slow UVP

If the output drops below 80% of the nominal output
voltage (V

REFIN

) for 75µs, the MAX8737 shuts down the

LDO and pulls the DRV_ pin to ground. If the output
voltage returns above 80% of the nominal output volt-
age (V

REFIN

) within the 75µs, the controller ignores the

load transient.

Fast UVP

If the output voltage drops below 60% of the nominal
output voltage (V

REFIN

) for approximately 5µs, the

MAX8737 immediately shuts down and pulls the DRV_
pin to ground. If the output voltage returns above 80%
of the nominal output voltage (V

REFIN

) within the 5µs,

the controller ignores the load transient.

Thermal Protection

The MAX8737 is available in a thin QFN package to
reduce the thermal impedance, and improve the ther-
mal coupling between the controller and the external
MOSFETs. When the controller’s junction temperature
exceeds T

J

= +125°C (max), a thermal sensor turns off

the external pass transistor, allowing the system to
cool. The thermal sensor turns the pass transistor back
on once the controller’s junction temperature drops by
approximately 20°C.

Design Procedure

Input Capacitor Selection (C

IN

)

Typically, the MAX8737 is powered from the output of a
step-down regulator, effectively providing a low-imped-
ance source. A local 10µF ceramic capacitor at V

IN

and

a 1.0µF ceramic capacitor at V

BIAS

should be sufficient

for most applications. If the linear regulator is connect-
ed to a high-impedance input, low-ESR polymer capac-
itors are recommended on the input.

Output Capacitor Selection (C

OUT

)

To maintain stability and provide good transient
response, the MAX8737 requires 4.7µF/A (4.7µF mini-
mum) of low ESR ceramic capacitor at the output. The
regulator remains stable with capacitances higher than
the minimum. When selecting the output capacitor to

MAX8737

Dual, Low-Voltage Linear Regulator Controllers

with External MOSFETs

______________________________________________________________________________________

11

V

OUT

C

OUT

R

CS

C

IN

INPUT

R3

C2

CS

OUT

DRV

MAX8737

MAX8737

V

OUT

C

OUT

R

CS

C

IN

INPUT

R3

C2

CS

OUT

DRV

R1

R2

10mV

R

CS

I

MAX

V

OUT

10mV

R

CS

I

MAX

V

OUT

SIMPLE CURRENT-LIMIT PROTECTION

FOLDBACK CURRENT-LIMIT PROTECTION

Figure 3. Current-Limit Protection