MAX16831_09 Datasheet, PDF(15/19 Page) Maxim Integrated Products – High-Voltage, High-Power LED Driver with Analog and PWM Dimming Control

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MAX16831_09 Datasheet, PDF (15/19 Pages) Maxim Integrated Products – High-Voltage, High-Power LED Driver with Analog and PWM Dimming Control

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High-Voltage, High-Power LED Driver with

Analog and PWM Dimming Control

When using the MAX16831 in a boost or buck-boost

configuration, the input RMS current is low and the

input capacitance can be small.

Operating the MAX16831 Without the

Dimming Switch

The MAX16831 can also be used in the absence of the

dimming MOSFET. In this case, the PWM dimming per-

formance is compromised but in applications that do

not require dimming, the MAX16831 can still be used.

A short circuit across the load will cause the MAX16831

to disable the gate drivers and they will remain off until

the input power is recycled.

Switching Power MOSFET Losses

When selecting MOSFETs for switching, consider the

total gate charge, power dissipation, the maximum

drain-to-source voltage, and package thermal imped-

ance. The product of the MOSFET gate charge and

RDS(ON) is a figure of merit, with a lower number signi-

fying better performance. Select MOSFETs optimized

for high-frequency switching applications.

MOSFET losses may be broken into three categories:

conduction loss, gate drive loss, and switching loss.

The following simplified power loss equation is true for

all the different configurations.

PLOSS = PCONDUCTION + PGATEDRIVE + PSWITCH

Layout Recommendations

Typically, there are two sources of noise emission in a

switching power supply: high di/dt loops and high dv/dt

surfaces. For example, traces that carry the drain cur-

rent often form high di/dt loops. Similarly, the heatsink

of the MOSFET connected to the device drain presents

a high dv/dt source; therefore, minimize the surface

area of the heatsink as much as possible. Keep all PCB

traces carrying switching currents as short as possible

to minimize current loops. Use ground planes for best

results.

Careful PCB layout is critical to achieve low switching

losses and clean, stable operation. Use a multilayer

board whenever possible for better noise performance

and power dissipation. Follow these guidelines for

good PCB layout:

â¢ Use a large copper plane under the MAX16831

package. Ensure that all heat-dissipating compo-

nents have adequate cooling. Connect the exposed

pad of the device to the ground plane.

â¢ Isolate the power components and high-current paths

from sensitive analog circuitry.

â¢ Keep the high-current paths short, especially at the

ground terminals. This practice is essential for sta-

ble, jitter-free operation. Keep switching loops short.

â¢ Connect AGND, SGND, and QGND to a ground

plane. Ensure a low-impedance connection between

all ground points.

â¢ Keep the power traces and load connections short.

This practice is essential for high efficiency. Use

thick copper PCBs (2oz vs. 1oz) to enhance full-load

efficiency.

â¢ Ensure that the feedback connection to FB is short

and direct.

â¢ Route high-speed switching nodes away from the

sensitive analog areas.

â¢ To prevent discharge of the compensation capaci-

tors, C1 and C2, during the off-time of the dimming

cycle, ensure that the PCB area close to these com-

ponents has extremely low leakage. Discharge of

these capacitors due to leakage may result in

degraded dimming performance.

Pin Configuration

TOP VIEW

N.C. 1

UVEN 2

REG1 3

AGND 4

REF 5

DIM 6

RTSYNC 7

CLKOUT 8

32 31 30 29 28 27 26 25

24 N.C.

23 DGT

22 QGND

MAX16831

21 SNS-

20 SNS+

19 DRI

18 DRV

*EP

17 SGND

9 10 11 12 13 14 15 16

*EP = EXPOSED PAD

TQFN

(5mm x 5mm)

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