Rainbow Electronics MAX8728 User Manual

MAX8728

Low-Cost, Multiple-Output

Power Supply for LCD Monitors/TVs

______________________________________________________________________________________

25

output voltage ripple is typically dominated by
V

AVDD

_

RIPPLE(C)

. The voltage rating and temperature

characteristics of the output capacitor must also be
considered.

Input-Capacitor Selection

The input capacitor reduces the current peaks drawn
from the input supply and reduces noise injection into
the IC. Two 10µF ceramic capacitors are used in the
Typical Applications Circuit (Figure 1) because of the
high-source impedance seen in typical lab setups.
Actual applications usually have much lower source
impedance since the step-up regulator often runs
directly from the output of another regulated supply.
Typically, the input capacitance can be reduced below
the values used in the Typical Operating Circuit.

Rectifier Diode

The MAX8728’s high-switching frequency demands a
high-speed rectifier. Schottky diodes are recommend-
ed for most applications because of their fast recovery
time and low forward voltage. In general, a 1A to 2A
Schottky diode complements the internal MOSFET well.

Output-Voltage Selection

The output voltage of the step-up regulator is adjusted
by connecting a resistive voltage-divider from the out-
put (V

AVDD

) to GND with the center tap connected to

FB2 (see Figure 1). Select R2 in the 10k

Ω to 50kΩ

range. Calculate R1 with the following equation:

where V

FB2

, the step-up regulator’s feedback set point,

is 2.0V. Place R1 and R2 close to the IC.

Loop Compensation

Choose R

COMP

(R3 in Figure 1) to set the high-frequen-

cy integrator gain for fast-transient response. Choose
C

COMP

(C13 in Figure 1) to set the integrator zero to

maintain loop stability.

For low-ESR output capacitors, use the following equa-
tions to obtain stable performance and good transient
response:

To further optimize transient response, vary R

COMP

in

20% steps and C

COMP

in 50% steps while observing

transient response waveforms.

Charge-Pump Regulators

Selecting the Number of Charge-Pump Stages

For highest efficiency, always choose the lowest num-
ber of charge-pump stages that meet the output
requirement.

The number of positive charge-pump stages is given by:

where n

POS

is the number of positive charge-pump

stages, V

GON

is the output of the positive charge-pump

regulator, I

GON

is the positive charge-pump output cur-

rent, V

SUPP

is the supply voltage of the charge-pump

regulators, V

D

is the forward voltage drop of the

charge-pump diode, and R

EFF

is the effective output

resistance of the charge-pump switches (10

Ω typ.)

The number of negative charge-pump stages is given by:

where n

NEG

is the number of negative charge-pump

stages, V

GOFF

is the output of the negative charge-

pump regulator, and I

GOFF

is the negative charge-

pump output current.

The above equations assume that the flying capacitors
are large enough to not further limit the output current.

Flying Capacitors

Increasing the flying capacitor (C

X

) value lowers the

effective source impedance and increases the output
current capability. Increasing the capacitance indefi-
nitely has a negligible effect on output current capabili-
ty because the internal switch resistance and the diode
impedance place a lower limit on the source imped-
ance. A 0.1µF ceramic capacitor works well, except in
cases of low frequency, low headroom, and high cur-
rent. The flying capacitor’s voltage rating must exceed
the following:

V

CX

> n x V

SUPP

where n is the stage number in which the flying capaci-
tor appears.

n

V

V

x V

I

x R

NEG

GOFF

SUPP

D

GOFF

EFF

(

)

(

)

=

−

−

−

2

n

V

V

V

V

I

x R

POS

GON

SUPP

SUPP

D

GON

EFF

(

)

(

)

=

−

−

×

−

2

R

V

V

C

L

I

C

V

C

I

R

COMP

IN

AVDD

AVDD

AVDD

AVDD MAX

COMP

AVDD

AVDD

AVDD MAX

COMP

(

)

(

)

≈

Ч

Ч

Ч

Ч

≈

Ч

Ч

Ч

250

20

R

R

V

V

AVDD

FB

1

2

1

2

=

Ч

−

⎛
⎝⎜

⎞
⎠⎟