ISL97634IRT18Z-T Intersil, ISL97634IRT18Z-T Datasheet - Page 9

ISL97634IRT18Z-T

Manufacturer Part Number

ISL97634IRT18Z-T

Description

IC LED DRIVR WHITE BCKLGT 8-TDFN

Manufacturer

Intersil

Type

Backlight, White LEDr

Datasheet

1.ISL97634IRT14Z-T.pdf (10 pages)

Specifications of ISL97634IRT18Z-T

Topology

PWM, Step-Up (Boost)

Number Of Outputs

Internal Driver

Yes

Type - Primary

Automotive, Backlight

Type - Secondary

White LED

Frequency

1.3MHz ~ 1.6MHz

Voltage - Supply

2.4 V ~ 5.5 V

Mounting Type

Surface Mount

Package / Case

8-TDFN Exposed Pad

Operating Temperature

-40°C ~ 85°C

Current - Output / Channel

50mA

Internal Switch(s)

Yes

Efficiency

85%

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Output

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SEPIC Operation

For applications where the output voltage is not always

above the input voltage, a buck or boost regulation is

needed. A SEPIC (Single Ended Primary Inductance

Converter) topology, shown in Figure 18, can be considered

for such an application. A single cell Li-ion battery operating

a cellular phone backlight or flashlight is one example. The

battery voltage is between 2.5V and 4.2V, depending on the

state of charge. On the other hand, the output may require

only one 3V to 4V medium power LED for illumination

because the light guard of the backlight assembly is

optimized for cost efficiency trade-off reason.

In fact, a SEPIC configured LED driver is flexible enough to

allow the output to be well above or below the input voltage,

unlike the previous example. Another example is when the

number of LEDs and input requirements are different from

platform to platform, a common circuit and PCB that fit all the

platforms in some cases may be beneficial enough that it

outweighs the disadvantage of adding additional component

cost. L

The simplest way to understand SEPIC topology is to think

about it as a boost regulator where the input voltage is level

shifted downward at the same magnitude and the lowest

reference level starts at -V

FIGURE 17. CONCEPTUAL 8 LEDs HIGH VOLTAGE DRIVER

= 2.7V TO 5.5V

1µF

= 2.7V TO 5.5V

0.1µF

and L

FIGURE 18. SEPIC LED DRIVER

can be a coupled inductor in one package.

VIN

PWM/EN

VIN

SDIN

ISL97634

22µH

FBSW

2.2µ

VOUT

FBSW

VOUT

GND

rather than 0V.

1µF

FQT13N06L

6.3Ω

1Ω

10BQ100

SK011C226KAR

22µH

C3 4.7µF

0.22µF

ISL97634

The SEPIC works as follows; assume the circuit in Figure 18

operates normally when the ISL97634 internal switch opens

and it is in the PWM off state. After a short duration where few

LC time constants elapsed, the circuit is considered in the

steady-state within the PWM off period that L

shorted. V

charged to V

switch closes and the circuit is in the PWM on-state, V

pulled to ground. Since the voltage in C

instantaneously, V

The next cycle when the ISL97634 switch opens, V

up to the targeted output like the standard boost regulator

operation, except the lowest reference point is at -V

output is approximated in Equation 9:

where D is the on-time of the PWM duty cycle.

The convenience of SEPIC comes with some trade-off in

addition to the additional L and C costs. The efficiency is

usually lowered because of the relatively large efficiency loss

through the Schottky diode if the output voltage is low. The L

series resistance also contributes additional loss. Figure 19

shows the efficiency measurement of a single LED application

as the input varies between 2.7V and 4.2V.

Note V

boost regulator. The higher the input voltage, the lower the V

voltage will be during PWM on period. The result is that the

efficiency will be lower at higher input voltages because the

SEPIC has to work harder to boost up to the required level.

This behavior is the opposite to the standard boost regulator’s

and the comparison is shown in Figure 19.

PCB Layout Considerations

The layout is very important for the converter to function

properly. R

and GND pins. Longer traces to the LEDs are acceptable.

Similarly, the supply decoupling cap and the output filter cap

should be as close as possible to the VIN and VOUT pins.

The heat of the IC is mainly dissipated through the thermal pad

of the package. Maximizing the copper area connected to this

pad if possible. In addition, a solid ground plane is always

helpful for the EMI performance.

FIGURE 19. EFFICIENCY MEASUREMENT OF A SINGLE LED

OUT

is considered the level-shifted LX node of a standard

SET

is therefore shorted to the ground and C

----------------- -

(

SEPIC DRIVER

1 D

must be located as close as possible to the FB

with V

–

)

is shifted downward and becomes -V

= 2.7V

= V

ILED (mA)

. When the ISL97634 internal

cannot be changed

= 4.2V

1 LED

= L

= 1µF

= 4.7Ω

and L

= 22µH

March 7, 2008

boosts

. The

are

(EQ. 9)

FN6264.3

is now

ISL97634IRT18Z-T Intersil, ISL97634IRT18Z-T Datasheet - Page 9

ISL97634IRT18Z-T

Specifications of ISL97634IRT18Z-T

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