Max8649 – Rainbow Electronics MAX8649 User Manual

MAX8649

Soft-Start

The MAX8649 includes internal soft-start circuitry that
eliminates inrush current at startup, reducing transients
on the input source (see the

Typical Operating Charac-

teristics

). Soft-start is particularly useful for high-imped-

ance input sources, such as Li+ and alkaline cells.
When enabling the MAX8649 into a prebiased output,
the MAX8649 performs a complete soft-start cycle.

Synchronous Rectification

An internal n-channel synchronous rectifier eliminates
the need for an external Schottky diode and improves
efficiency. The synchronous rectifier turns on during the
second half of each switching cycle (off-time). During
this time, the voltage across the inductor is reversed,
and the inductor current ramps down. In PWM mode,
the synchronous rectifier turns off at the end of the
switching cycle. In power-save mode, the synchronous
rectifier turns off when the inductor current falls below
50mA (typ) or at the end of the switching cycle,
whichever occurs first.

Ramp-Rate Control

The MAX8649 output voltage has an actively controlled
variable ramp rate, set with the I

2

C interface (see

Figures 6, 7, and 8). The value set in the RAMP register
controls the output voltage ramp rate. The
RAMP_DOWN bit controls the active ramp-down

behavior in power-save mode. When the regulator is set
for power-save mode and the RAMP_DOWN bit is
cleared, the ramp-down is not actively controlled, and
the regulator output voltage ramps down at the rate
determined by the output capacitance and the external
load. Small loads result in an output-voltage decay that
is slower than that specified by RAMP; large loads
result in an output-voltage decay that is no faster than
that specified by RAMP When the RAMP_DOWN bit is
set in power-save mode, the zero-cross comparator is
disabled during the ramp-down condition. Active ramp-
down functionality is inherent in forced-PWM operation.

Calculate the maximum and minimum values for the
ramp rate as follows:

where:

f

SW

= 3.25MHz ±10% for PWM operation

f

SW

= 3.25MHz ±25% for hysteretic operation

f

SYNC

= frequency of external clock

n = 4 for 13MHz, 6 for 19.2MHz, and 8 for 26MHz

RAMP_CODE = value of the RAMP[2:0] register (see
Table 9)

f

f

n

SW

SYNC

=

V

mV

t

f

t

f

OUT LSB

CLK MAX

SW MIN

CLK MIN

SW

_

_

_

_

=

=

=

10

1

1

_

_ MAX

t

V

t

t

RAMP MIN

OUT LSB

CLK MAX

RAMP CODE

RAMP

_

_

_

_

=

×

1

2

_

_

_

_

_

MAX

OUT LSB

CLK MIN

RAMP CODE

V

t

=

×

1

2

TIME

OUTPUT

VOLTAGE

DELTA V = 10mV

VOUT1

VOUT2

10mV/RAMP RATE

Figure 6. Ramp-Up Function

TIME

OUTPUT

VOLTAGE

DELTA
V = 10mV

VOUT1

VOUT2

10mV/RAMP
RATE

Figure 7. Ramp-Down Function

FINAL

OUTPUT

VOLTAGE

MODE CHANGE

TO HIGHER VOUT

MODE CHANGE

TO LOWER VOUT

Figure 8. Mode Change Before Final Value is Reached

1.8A Step-Down Regulator with Differential

Remote Sense in 2mm x 2mm WLP

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