LM3431QMH/NOPB National Semiconductor, LM3431QMH/NOPB Datasheet - Page 15

LM3431QMH/NOPB

Manufacturer Part Number

LM3431QMH/NOPB

Description

IC LED DRVR HP CONS CURR 28TSSOP

Manufacturer

National Semiconductor

Series

PowerWise®r

Type

High Power, Constant Currentr

Datasheet

1.LM3431MHNOPB.pdf (24 pages)

Specifications of LM3431QMH/NOPB

Constant Current

Yes

Topology

PWM, Step-Up (Boost)

Number Of Outputs

Internal Driver

Type - Primary

Automotive

Type - Secondary

High Brightness LED (HBLED)

Frequency

651kHz ~ 1.1MHz

Voltage - Supply

4.5 V ~ 36 V

Mounting Type

Surface Mount

Package / Case

28-TSSOP Exposed Pad, 28-eTSSOP, 28-HTSSOP

Operating Temperature

-40°C ~ 125°C

Current - Output / Channel

200mA

Internal Switch(s)

Yes

Efficiency

88%

Operating Supply Voltage (typ)

5/9/12/15/18/24V

Number Of Segments

Operating Temperature (min)

-40C

Operating Temperature (max)

125C

Operating Temperature Classification

Automotive

Package Type

TSSOP EP

Pin Count

Mounting

Surface Mount

Power Dissipation

3.1W

Operating Supply Voltage (min)

4.5V

Operating Supply Voltage (max)

36V

Led Driver Application

Display Backlighting, Automotive Lighting

No. Of Outputs

Output Current

200mA

Output Voltage

40V

Input Voltage

5V To 37V

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Output

Lead Free Status / Rohs Status

Compliant

Other names

LM3431QMH

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INPUT CAPACITOR SELECTION

Because the inductor is at the input of a boost converter, the

input current waveform is continuous and triangular. The in-

ductor ensures that the input capacitor sees relatively low

ripple currents. The rms current in the input capacitor is given

by:

The input capacitor must be capable of handling this rms cur-

rent. Input ripple voltage increases with increasing ESR as

well as decreasing input capacitance. A typical value of 10 µF

will work well for most applications. For low input voltages,

additional input capacitance may be required to prevent trip-

ping the UVLO. Additionally, a ceramic capacitor of 1 µF or

larger should be placed close to the VIN pin to prevent noise

from interfering with normal device operation.

OUTPUT CAPACITOR SELECTION

The output capacitor in a boost converter provides all the out-

put current when the switch is on and the inductor is charging.

As a result, the output capacitor sees relatively large ripple

currents. The output capacitor must be capable of handling

more than the rms current, which can be estimated as:

Additionally, the ESR of the output capacitor affects the output

ripple and has an effect on transient response during dim-

ming. For low output ripple voltage, low ESR ceramic capac-

itors are recommended. Although not a critical parameter,

excessive output ripple can affect LED current.

The output capacitance requirement is somewhat arbitrary

and depends mostly on dimming frequency. Although a min-

imum value of 4 µF is recommended, at lower dimming fre-

quencies, the longer LED-off times will typically require more

capacitance to reduce output voltage transients.

When ceramic capacitors are used, audible noise may be

generated during LED dimming. Audible noise increases with

the amplitude of output voltage transients. To minimize this

noise, use the smallest case sizes and if possible, use a larger

number of capacitors in parallel to reduce the case size of

each. Output transients are also minimized via the FF pin

(See Setting FF section). Setting the dimming frequency

above 18 kHz or below 500 Hz will also help eliminate the

audible effects of output voltage transients.

When selecting an output capacitor, always consider the ef-

fective capacitance at the output voltage, which can be less

than 50% of the capacitance specified at 0V. Use this effective

capacitance value for the compensation calculations below.

COMPENSATION

Once the output capacitor is selected, the control loop char-

acteristics and compensation can be determined. The COMP

pin is provided to ensure stable operation and optimum tran-

sient performance over a wide range of applications. The

following equations define the control-to-output or power

stage of the loop:

Where R

rent, and K

Since the control-to-output response will shift with input volt-

age, the compensation should be calculated at both the min-

imum and maximum input voltage.

The zero created by the ESR of the output capacitor, f

generally at a very high frequency if the ESR is small. If low

ESR capacitors are used f

capacitors are used, C

A current mode control boost regulator has an inherent right

half plane zero, RHPz. This has the effect of a zero in the gain

plot, causing a +20dB/decade increase, but has the effect of

a pole in the phase, subtracting 90° in the phase plot. This

can cause instability if the control loop is influenced by this

zero. To ensure the RHP zero does not cause instability, the

control loop must be designed to have a bandwidth of less

than one third the frequency of the RHP zero. The regulator

also has a double pole, fpn, at one half the switching frequen-

cy. The control loop bandwidth must be lower than 1/5 of fpn.

A typical control-to-output gain response is shown in Figure

6 below.

FIGURE 6. Typical Control-to-Output Bode Plot

is the load resistance corresponding to LED cur-

is calculated as shown:

can be added (see below).

can be neglected and if high ESR

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LM3431QMH/NOPB National Semiconductor, LM3431QMH/NOPB Datasheet - Page 15

LM3431QMH/NOPB

Specifications of LM3431QMH/NOPB

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