MAX15031 Datasheet, PDF(13/16 Page) Maxim Integrated Products – 80V, 300mW Boost Converter and Current Monitor for APD Bias Applications

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MAX15031 Datasheet, PDF (13/16 Pages) Maxim Integrated Products – 80V, 300mW Boost Converter and Current Monitor for APD Bias Applications

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80V, 300mW Boost Converter and Current

Monitor for APD Bias Applications

Diode Selection

The MAX15031âs 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 drop. Ensure that the

diodeâs peak current rating is greater than the peak

inductor current. Also the diode reverse-breakdown

voltage must be greater than VOUT. The output voltage

of the boost converter.

Output Filter Capacitor Selection

For most applications, use a small output capacitor of

0.1ÂµF or greater. To achieve low output ripple, a capaci-

tor with low ESR, low ESL, and high capacitance value

should be selected. If tantalum or electrolytic capacitors

are used to achieve high capacitance values, always

add a smaller ceramic capacitor in parallel to bypass

the high-frequency components of the diode current.

The higher ESR and ESL of electrolytic capacitors

increase the output ripple and peak-to-peak transient

voltage. Assuming the contribution from the ESR and

capacitor discharge equals 50% (proportions may vary),

calculate the output capacitance and ESR required for a

specified ripple using the following equations:

COUT[ÂµF]

0.5

IOUT

x âVOUT

â¡

â¢TS

â£â¢

ILPEAK x LOPTIMUM

(VOUT â VIN_MIN)

â¤

â¥

â¦â¥

ESR[mâ¦] = 0.5 x âVOUT

IOUT

For very low output ripple applications, the output of the

boost converter can be followed by an RC filter to further

reduce the ripple. Figure 2 shows a 100â¦ (RF), 0.1ÂµF

(CF) filter used to reduce the switching output ripple to

1mVP-P with a 0.1mA load or 2mVP-P with a 4mA load.

The output-voltage regulation resistor-divider must remain

connected to the diode and output capacitor node.

Use X7R ceramic capacitors for more stability over the full

temperature range. Use an X5R capacitor for -40Â°C to

+85Â°C applications.

Input Capacitor Selection

Bypass PWR to PGND with a 1ÂµF (min) ceramic capaci-

tor and bypass IN to PGND with a 1ÂµF (min) ceramic

capacitor. Depending on the supply source imped-

ance, higher values may be needed. Make sure that the

input capacitors are close enough to the IC to provide

adequate decoupling at IN and PWR as well. If the lay-

out cannot achieve this, add another 0.1ÂµF ceramic

capacitor between IN and PGND (or PWR and PGND)

in the immediate vicinity of the IC. Bulk aluminum elec-

trolytic capacitors may be needed to avoid chattering

at low input voltage. In case of aluminum electrolytic

capacitors, calculate the capacitor value and ESR of

the input capacitor using the following equations:

CIN[ÂµF] =

Î·

VOUT

VIN_MIN

x IOUT

x 0.5 x

âVIN

â¡

â£â¢â¢TS

ILPEAK x LOPTIMUM x VOUT

VIN_MIN(VOUT â VIN_MIN)

â¤

â¥

â¦â¥

ESR[mâ¦] = 0.5 x âVIN x Î· x VIN_MIN

VOUT x IOUT

VIN = 2.7V TO 5.5V

CPWR

CCP

CIN

PWR

CNTRL

SHDN

MAX15031 FB

BIAS

PGND

SGND

100â¦

COUT1

VOUT

0.1ÂµF

Figure 2. Typical Operating Circuit with RC Filter

______________________________________________________________________________________ 13

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