MAX16834 Datasheet, PDF(9/23 Page) Maxim Integrated Products – High-Power LED Driver with Integrated High-Side LED Current Sense and PWM Dimming MOSFET Driver

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MAX16834 Datasheet, PDF (9/23 Pages) Maxim Integrated Products – High-Power LED Driver with Integrated High-Side LED Current Sense and PWM Dimming MOSFET Driver

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High-Power LED Driver with Integrated High-Side LED

Current Sense and PWM Dimming MOSFET Driver

The MAX16834 is also suitable for DC-DC converter

applications such as boost or buck-boost (Figures 6

and 7). Other applications include boost LED drivers

with automotive load dump protection (Figure 4) and

high-side buck LED drivers (Figure 5).

Undervoltage Lockout/Enable

The MAX16834 features an adjustable UVLO using the

enable input (UVEN). Connect UVEN to VIN through a

resistive divider to set the UVLO threshold. The

MAX16834 is enabled when the VUVEN exceeds the

1.435V (typ) threshold. See the Setting the UVLO

Threshold section for more information.

UVEN also functions as an enable/disable input to the

device. Drive UVEN low to disable the output and high

to enable the output.

Reference Voltage (REF)

The MAX16834 features a 3.7V reference output, REF.

REF provides power to most of the internal circuit blocks

except for the output drivers and is capable of sourcing

1mA to external circuits. Connect a 0.1ÂµF to 0.22ÂµF

ceramic capacitor from REF to SGND. Connect REF to

REFI through a resistive divider to set the LED current.

Reference Input (REFI)

The output current is proportional to the voltage at

REFI. Applying an external DC voltage at REFI or using

a potentiometer from REF to SGND allows analog dim-

ming of the output current.

High-Side Reference Voltage Input (LV)

LV is a reference input. Connect LV to SGND for boost

and SEPIC topologies. Connect LV to IN for buck-boost

and high-side buck topologies.

Dimming Driver Regulator

Input Voltage (HV)

The voltage at HV provides the input voltage for the

dimming driver regulator. For boost or SEPIC topology,

connect HV either to IN or to VCC. For buck-boost, con-

nect HV to a voltage higher than IN. The voltage at HV

must not exceed 28V with respect to PGND. For the

high-side buck, connect HV to IN.

Dimming MOSFET Driver (DIMOUT)

The MAX16834 requires an external n-channel MOSFET

for PWM dimming. Connect the gate of the MOSFET to

the output of the dimming driver, DIMOUT, for normal

operation. The dimming driver is capable of sinking or

sourcing up to 50mA of current.

n-Channel MOSFET Switch Driver (NDRV)

The MAX16834 drives an external n-channel switching

MOSFET. NDRV swings between VCC and PGND.

NDRV is capable of sinking/sourcing 3A of peak current,

allowing the MAX16834 to switch MOSFETs in high-

power applications. The average current demanded

from the supply to drive the external MOSFET depends

on the total gate charge (QG) and the operating

frequency of the converter, fSW. Use the following equa-

tion to calculate the driver supply current INDRV

required for the switching MOSFET:

INDRV = QG x fSW

Pulse Dimming Inputs (PWMDIM)

The MAX16834 offers a dimming input (PWMDIM) for

pulse-width modulating the output current. PWM dim-

ming can be achieved by driving PWMDIM with a pul-

sating voltage source. When the voltage at PWMDIM is

greater than 1.435V, the PWM dimming MOSFET turns

on and when the voltage on PWMDIM is below 1.235V,

the PWM dimming MOSFET turns off.

High-Side Linear Regulator (VCLV)

The MAX16834âs 5V high-side regulator (CLV) powers

up the dimming MOSFET driver. VCLV is measured with

respect to LV and sources up to 2mA of current.

Bypass CLV to LV with a 0.1ÂµF to 1ÂµF low-ESR ceramic

capacitor. The maximum voltage on CLV with respect

to PGND must not exceed 28V. This limits the input volt-

age for buck-boost topology.

Low-Side Linear Regulator (VCC)

The MAX16834âs 7V low-side linear regulator (VCC) pow-

ers up the switching MOSFET driver with sourcing capa-

bility of up to 50mA. Use at least a 1ÂµF low-ESR ceramic

capacitor from VCC to PGND for stable operation.

LED Current-Sense Input (SENSE+)

The differential voltage from SENSE+ to LV is fed to an

internal current-sense amplifier. This amplified signal is

then connected to the negative input of the transcon-

ductance error amplifier. The voltage gain factor of this

amplifier is 9.9 (typ).

Whenever VLV is greater than 5V, the input impedance

of the LED current-sense amplifier seen at the SENSE+

pin is 1kâ¦ Â±30%. In that condition, a bias current of

20ÂµA (Â±30%) is pulled from SENSE+, in addition to the

current due to the 1kâ¦ resistor. When VLV is less than

1V, the amplifier input (SENSE+ pin) is in high imped-

ance and the bias current of 20ÂµA (Â±30%) is pushed

out of that pin.

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