LM3503ITL-44/NOPB National Semiconductor, LM3503ITL-44/NOPB Datasheet - Page 15

IC, LED DRIVER, CONSTANT CURRENT, µSMD16

LM3503ITL-44/NOPB

Manufacturer Part Number

LM3503ITL-44/NOPB

Description

IC, LED DRIVER, CONSTANT CURRENT, µSMD16

Manufacturer

National Semiconductor

Datasheet

1.LM3503ITL-44NOPB.pdf (20 pages)

Specifications of LM3503ITL-44/NOPB

Led Driver Application

Display Backlighting, Cellular Phones And PDAs

No. Of Outputs

Output Current

1.05A

Output Voltage

44V

Input Voltage

2.5V To 5.5V

Topology

Constant Current

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Application Information

CONTINUOUS AND DISCONTINUOUS MODES OF

OPERATION

Since the LM3503 is a constant frequency pulse-width-

modulated step-up regulator, care must be taken to make

sure the maximum duty cycle specification is not violated.

The duty cycle equation depends on which mode of opera-

tion the LM3503 is in. The two operational modes of the

LM3503 are continuous conduction mode (CCM) and dis-

continuous conduction mode (DCM). Continuous conduction

mode refers to the mode of operation where during the

switching cycle, the inductor current never goes to and stays

at zero for any significant amount of time during the switch-

ing cycle. Discontinuous conduction mode refers to the

mode of operation where during the switching cycle, the

inductor current goes to and stays at zero for a significant

amount of time during the switching cycle. Figure 4 illus-

trates the threshold between CCM and DCM operation. In

Figure 4 the inductor current is right on the CCM/DCM

operational threshold. Using this as a reference, a factor can

be introduced to calculate when a particular application is in

CCM or DCM operation. R is a CCM/DCM factor we can use

to compute which mode of operation a particular application

is in. If R is ≥ 1, then the application is operating in CCM.

Conversely, if R is

The R factor inequalities are a result of the components that

PWM Dimming Duty Cycle vs. LED Current

The results are based on the 2LEDs on Main display and 2LEDs on Sub display

Duty

(%)

R = 787k ohms

0.78mA

1.85mA

2.88mA

3.96mA

5.05mA

6.08mA

7.13mA

8.17mA

9.24mA

200Hz

1, the application is operating in DCM.

R =316k ohms

12.94mA

14.83mA

16.73mA

11.03mA

1.59mA

3.46mA

5.35mA

7.24mA

9.12mA

500Hz

(Continued)

FIGURE 4. Inductor Current Waveform

R = 158kohms

12.45mA

15.03mA

17.61mA

20.20mA

22.79mA

2.23mA

4.78mA

7.33mA

9.88mA

1KHz

make up the R factor. From Figure 4, the R factor is equal to

the average inductor current, I

inductor ripple current, ∆i

equation can be used to compute R factor:

R=16.2k ohms

10.77mA

14.48mA

21.86mA

25.71mA

29.53mA

33.32mA

3.42mA

7.09mA

19.1mA

10KHz

R=3.16k ohms

15.12mA

19.06mA

22.98mA

30.83mA

34.78mA

11.25mA

. Using Figure 4, the following

3.58mA

7.41mA

26.9mA

50KHz

(avg), divided by half the

20128637

R=1.62k ohms

11.34mA

15.24mA

19.16mA

23.10mA

27.05mA

31.00mA

35.00mA

100kHz

3.61mA

7.48mA

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LM3503ITL-44/NOPB National Semiconductor, LM3503ITL-44/NOPB Datasheet - Page 15

LM3503ITL-44/NOPB

Specifications of LM3503ITL-44/NOPB

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