ISL1902FAZ-T7A Intersil, ISL1902FAZ-T7A Datasheet - Page 20

ISL1902FAZ-T7A

Manufacturer Part Number

ISL1902FAZ-T7A

Description

LED Lighting Drivers Dimmable AC Mains LED Driver PFC

Manufacturer

Intersil

Datasheet

1.ISL1902FAZ-T7A.pdf (25 pages)

Specifications of ISL1902FAZ-T7A

Rohs

yes

Input Voltage

4 V

Operating Frequency

320 Hz

Maximum Supply Current

14.5 mA

Output Current

1 A

Maximum Operating Temperature

+ 125 C

Mounting Style

SMD/SMT

Package / Case

QSOP-24

Minimum Operating Temperature

- 40 C

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The red trace is the current source supplying the output. The blue

trace is the output capacitor voltage. The green trace is the LED

current. When the PWM signal is off, the 50mA current source

charges C

turns on, 100mA of current flows through the LEDs, with the initial

current slightly higher and the final current slightly lower as C

discharges. The peak-to-peak ripple voltage on C

The decrease in the LED current during conduction is determined

by the size of the output capacitor and the LED current.

Linear Amplifier

The linear amplifier block is a fully accessible uncommitted

operational amplifier. It may be used for a variety of purposes,

such as interfacing sensors, direct sensing of LED current, or a

pre-load amplifier. Examples of using the linear amplifier as a

sensor interface are shown in Figures 20 through 23.

The linear amplifier may be used as a pre-load control to provide

a larger dynamic dimming range as well as providing additional

holding current for applications using triac-based dimmers. As

shown in Figure 26, the pre-load can be configured as an active

load that increases linearly as the control loop reference level

(REFIN) decreases. The result is not only is the total load current

decreased as REFIN is lowered, but an increasing portion of the

load current is shunted to the pre-load. At some point, the

preload conducts all of the load current while allowing zero LED

current. This allows the converter to continue operation to

maintain circuit bias with zero LED current. Very high levels of

LED dimming resolution become achievable. Both the maximum

pre-load current and turn-on threshold are adjustable.

Again referring to FIgure 26, the voltage across R5 represents

the current flowing in the pre-load. The maximum level of this

signal is limited by the VOH of the linear amplifier and the gate

FIGURE 26. LINEAR AMPLIFIER CONFIGURED AS PRE-LOAD

OUT

and the output voltage increases. When the PWM

R 1

R 2

P R ELO A D

V R EF

R E FIN

LP O U T

ISL 19 02

LO U T

LR E F

LFB

R 5

Q 1

OUT

is ~160mV.

R 3

R 4

ISL1902

OUT

threshold voltage of the pre-load FET, Q1. A reasonable

maximum voltage for this signal is 3.0V. Therefore, the

maximum pre-load current, I

where LREF and REFIN are the voltages at the LREF and REFIN

pins, respectively. For purposes of illustration, if R3 and R4 are

equal, Equation 25 simplifies to:

Equation 26 shows that if REFIN is greater than 2x LREF, V

non-positive and the pre-load is not conducting. With proper

selection of LREF and R3/R4, the pre-load turn-on threshold and

gain characteristics can be matched to the application

requirements.

------- -

where%H is the selected fraction of maximum load when the pre-

load begins to conduct.

LREF

As an example, assume the pre-load should begin to operate at

75% of full load, and that the maximum pre-load current, I

50mA. Using Equation 27 to solve for the ratio of R3/R4 yields a

result of 8. Equation 28 yields a value of 0.333V for LREF.

Remembering the maximum allowed voltage across R5 is 3.0V

yields R5 = 3.0V/50mA = 60Ω at 150mW. V

Figure 27.

Alternatively, the linear amplifier may be used to control a

second LED string, either to force current sharing, or to control a

colored LED string for color correction. The second string can be

controlled from the same reference as the first LED string

allowing the string currents to track, or it can be controlled from

a separate reference that allows the two strings to work in

opposition, sharing the load current in proportion to each

reference. Figure 28 shows the tracking configuration.

3.0

2.5

2.0

1.5

1.0

0.5

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

–

------- - 0.5 %H

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

(

0.5 %H

⋅

LREF

2 LREF

⋅

------- -

100

⋅

FIGURE 27. PRE-LOAD EXAMPLE

)

⋅

⎛

⎝

150

–

(

0.5 %H

REFIN

------- -

VREF

⋅

200

⎞

⎠

–

REFIN (mV)

, is 3.0/R5.

⎛

⎝

–

------- - REFIN

⋅

250

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

)

⋅

300

6 %H

⋅

⎞

⎠

350

is plotted in

400

March 20, 2013

450

FN7981.2

(EQ. 25)

(EQ. 26)

(EQ. 27)

(EQ. 28)

500

, is

ISL1902FAZ-T7A Intersil, ISL1902FAZ-T7A Datasheet - Page 20

ISL1902FAZ-T7A

Specifications of ISL1902FAZ-T7A

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