MAX16826_15 Datasheet, PDF(11/26 Page) Maxim Integrated Products – Programmable, Four-String HB LED Driver with Output-Voltage Optimization and Fault Detection

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MAX16826_15 Datasheet, PDF (11/26 Pages) Maxim Integrated Products – Programmable, Four-String HB LED Driver with Output-Voltage Optimization and Fault Detection

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MAX16826

Programmable, Four-String HB

LED Driver with Output-Voltage

Optimization and Fault Detection

The MAX16826 provides additional flexibility with an

internal I2C serial interface to communicate with a

microcontroller (Î¼C). The interface can be used to

dynamically adjust the amplitude of the LED current in

each LED string and the switch-mode regulator output

voltage. It can also be used to read the ADC drain volt-

age measurements for each string, allowing a Î¼C to

dynamically adjust the output voltage to minimize the

power dissipation in the LED current sink FETs. The I2C

interface can also be used to detect faults such as LED

short or open.

Modes of Operation

The MAX16826 has six modes of operation: normal

mode, undervoltage lockout (UVLO) mode, thermal

shutdown (TSD) mode, shutdown (SHDN) mode,

standby (STBY) mode, and overvoltage protection

(OVP) mode.

The normal mode is the default state where each cur-

rent sink regulator is maintaining a constant current

through each of the LED strings. Digitized voltage feed-

back from the drains of the current sink FETs can be

used to establish a secondary control loop by using an

external Î¼C to control the output of the switching stage

for the purpose of achieving low-power dissipation

across these FETs.

UVLO mode occurs when VVCC goes below 4.3V. In

UVLO mode, each of the linear current sinks and the

switching regulator is shut down until the input voltage

exceeds the rising UVLO threshold.

TSD mode occurs when the die temperature exceeds

the internally set thermal limit (+160Â°C). In TSD mode,

each of the linear regulators and the switching regulator

is shut down until the die temperature cools by 20Â°C.

SHDN mode occurs when SYNC/EN is driven low. In

SHDN mode, all internal circuitry with the exception of

the shunt regulator is deactivated to limit current draw

to less than 50Î¼A. SHDN mode disengages when

SYNC/EN is driven high or clocked.

STBY mode is initiated using the I2C interface. In STBY

mode, each of the linear current sinks and the switching

regulator is shut down. STBY mode is also deactivated

using the I2C interface. In STBY mode, the internal VCC

regulator and the shunt regulator remain active. Whenever

the MAX16826 enters a mode that deactivates the switch-

ing regulator, the soft-start capacitor is discharged so that

soft-start occurs upon reactivation.

OVP mode occurs when the voltage at OVP is higher than

the internal reference. In OVP mode, the switching regula-

tor gate-drive output is latched off and can only be

restored by cycling enable, power, or entering standby

mode.

Switching Preregulator Stage

The MAX16826 features a current-mode controller that

is capable of operating in the frequency range of

100kHz to 1MHz. Current-mode control provides fast

response and simplifies loop compensation.

Output voltage regulation can be achieved in a two-

loop configuration. A required conventional control loop

can be set up by using the internal error amplifier with

its inverting input connected to FB. The bandwidth of

this loop is set to be as high as possible utilizing con-

ventional compensation techniques. The noninverting

input of this amplifier is connected to a reference volt-

age that is dynamically adjustable using the I2C inter-

face. The optional slower secondary loop consists of

the external Î¼C using the I2C interface reading out the

voltages at the drains of the current sink FETs and

adjusting the reference voltage for the error amplifier.

To regulate the output voltage, the error amplifier com-

pares the voltage at FB to the internal 1.25V (adjustable

down by using the I2C interface) reference. The output

of the error amplifier is compared to the sum of the cur-

rent-sense signal and the slope compensation ramp at

RSC to control the duty cycle at DL.

Two current-limit comparators also monitor the voltage

across the sense resistor using CS. If the primary cur-

rent-limit threshold is reached, the FET is turned off and

remains off for the reminder of the switching cycle. If

the current through the FET reaches the secondary cur-

rent limit, the switching cycle is terminated and the soft-

start capacitor is discharged. The converter then

restarts in soft-start mode preventing inductor current

runaway due to the delay of the primary cycle-by-cycle

current limit. The switching regulator controller also fea-

tures an overvoltage protection circuit that latches the

gate driver off if the voltage at OVP exceeds the inter-

nal 1.25V reference voltage.

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