Applications information – Rainbow Electronics MAX1677 User Manual

MAX1677

Compact, High-Efficiency, Dual-Output

Step-Up and LCD Bias DC-DC Converter

______________________________________________________________________________________

13

in the 10k

Ω to 200kΩ range and calculate R1 using one

of the following two equations (for positive or negative
output).

For a positive LCD output, connect LCDPOL to OUT as
shown in Figure 2. This sets the threshold at LCDFB to
1.25V. Select R2 and the desired output voltage
(V

LCD

), and calculate R1:

For positive LCD output: R1 = R2 [(V

LCD

/ 1.25V) - 1]

Figure 3 shows the standard circuit for generating a
negative LCD supply. This connection limits V

LCD

to

values between -V

IN

and -28V. If a smaller negative

output voltage is required, D2’s cathode can be con-
nected to V

IN

rather than ground. This alternate con-

nection permits output voltages from 0 to -



28 - V

IN



.

For a negative LCD output voltage, connect LCDPOL to
GND. The feedback threshold voltage of LCDFB is set
to 0. Select R2 and the desired output voltage (V

LCD

),

and calculate R1:

For negative LCD output: R1 = R2

×



V

LCD



/ 1.25V

To minimize ripple in the LCD output and prevent sub-
harmonic noise caused by switching pulse grouping, it
may be necessary in some PC board layouts to con-
nect a small capacitor in parallel with R1. For R1 values
in 500k

Ω to 2MΩ range, 22pF is usually adequate.

Many LCD bias applications require an adjustable out-
put voltage. In Figure 9, an external control voltage
(generated by a potentiometer, DAC, filtered PWM con-
trol signal, or other source) is coupled to LCDFB
through the resistor R

ADJ

. The output voltage of this cir-

cuit, for both positive and negative outputs, is given by:

V

OUT

= V

INIT

+ (R1 / R

ADJ

)(V

LCDFB

- V

ADJ

)

where V

INIT

is the initial output obtained without the

added adjust voltage, as calculated in one of the pre-
ceding two equations. V

LCDFB

is 1.25V for the positive

configuration, and 0 for the negative configuration.
R

ADJ

sets the output adjustment span, which is

1.25V

× R1 / R

ADJ

for either polarity output. Note that

raising V

ADJ

lowers V

OUT

in positive output designs,

while in negative output designs, raising V

ADJ

increas-

es the magnitude of the negative output.

Higher LCD Output Voltages

If the application requires LCD output voltages greater
than +28V, use the connection in Figure 10. This circuit
adds one capacitor-diode charge pump stage to
increase the output voltage without increasing the volt-
age stress on the LCDLX pin. The maximum output
voltage of the circuit is +55V and output current is
slightly less than half that available from the standard
circuit in Figure 2. In Figure 10, diodes D1, D2, and D3
should be at least 30V-rated Schottky diodes such as
1N5818 or MBR0530L or equivalent. Capacitors C1
and C2 should also be rated for 30V, while C3 must be
rated for the maximum set output voltage.

Applications Information

Inductor Selection

The MAX1677’s high switching frequency allows the
use of small surface-mount inductors. The 10µH values
shown in Figures 2 and 3 are recommended for most
applications, although values between 4.7µH and 47µH
are suitable. Smaller inductance values typically offer a
smaller physical size for a given series resistance,
allowing the smallest overall circuit dimensions. Larger
inductance values exhibit higher output current capa-
bility, but larger physical dimensions.

MAX1677

FB

R2

R1

V

ADJ

R

ADJ

V

LCD

GND

(REF)

Figure 9. Adjusting LCD Output Voltage

MAX1677

LCDLX

OUT

LCDPOL

L2

10

µH

D1

D2

D3

C1
1

µF

30V

C2
2.2

µF

30V

C3
2.2

µF

+40V/5mA
(SET TO
NO MORE
THAN 55V)

D1, D2, D3 = 30V RATED SCHOTTKY DIODES:
MBR0530L OR EQUIVALENT.

R2
65k

R1
2M

1

7

12

10

V

IN

LCDFB

Figure 10. Higher LCD Output Voltage