LM3485LED EVAL National Semiconductor, LM3485LED EVAL Datasheet - Page 11

LM3485LED EVAL

Manufacturer Part Number

LM3485LED EVAL

Description

BOARD EVALUATION LM3485LED

Manufacturer

National Semiconductor

Datasheets

1.LM3485MMNOPB.pdf (16 pages)

2.LM3485LED_EVAL.pdf (4 pages)

Specifications of LM3485LED EVAL

Current - Output / Channel

1.4A

Outputs And Type

1, Non-Isolated

Voltage - Output

30V

Features

Dimmable

Voltage - Input

5 ~ 30V

Utilized Ic / Part

LM3485

Lead Free Status / RoHS Status

Not applicable / Not applicable

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Design Information

Hysteretic control is a simple control scheme. However the

operating frequency and other performance characteristics

highly depend on external conditions and components. If ei-

ther the inductance, output capacitance, ESR, V

changed, there will be a change in the operating frequency

and output ripple. The best approach is to determine what

operating frequency is desirable in the application and then

begin with the selection of the inductor and C

INDUCTOR SELECTION (L1)

The important parameters for the inductor are the inductance

and the current rating. The LM3485 operates over a wide fre-

quency range and can use a wide range of inductance values.

A good rule of thumb is to use the equations used for

National's Simple Switchers

ple (Δi) as a function of output current (I

Δi

The inductance can be calculated based upon the desired

operating frequency where:

And

where D is the duty cycle, V

The inductor should be rated to the following:

The inductance value and the resulting ripple is one of the key

parameters controlling operating frequency. The second is

the ESR.

OUTPUT CAPACITOR SELECTION (C

The ESR of the output capacitor times the inductor ripple cur-

rent is equal to the output ripple of the regulator. However, the

creased with a given inductance, then operating frequency

increases as well. If ESR is reduced then the operating fre-

quency reduces.

The use of ceramic capacitors has become a common desire

of many power supply designers. However, ceramic capaci-

tors have a very low ESR resulting in a 90° phase shift of the

output voltage ripple. This results in low operating frequency

and increased output ripple. To fix this problem a low value

resistor should be added in series with the ceramic output

capacitor. Although counter intuitive, this combination of a

ceramic capacitor and external series resistance provide

highly accurate control over the output voltage ripple. The

other types capacitor, such as Sanyo POS CAP and OS-

HYST

for I

is the voltgae drop across the PFET.

≤

out

sets the first order value of this ripple. As ESR is in-

out

< 2.0Amps

> 2.0Amps

* 0.386827 * I

* 0.3

Ipk = (Iout+Δi/2)*1.1

out

−0.366726

is the diode forward voltage, and

. The equation for inductor rip-

OUT

) is:

)

OUT

ESR.

, or Cff is

CON, Panasonic SP CAP, Nichicon "NA" series, are also

recommended and may be used without additional series re-

sistance.

For all practical purposes, any type of output capacitor may

be used with proper circuit verification.

INPUT CAPACITOR SELECTION (C

A bypass capacitor is required between the input source and

ground. It must be located near the source pin of the external

PFET. The input capacitor prevents large voltage transients

at the input and provides the instantaneous current when the

PFET turns on.

The important parameters for the input capacitor are the volt-

age rating and the RMS current rating. Follow the

manufacturer's recommended voltage derating. For high in-

put voltage application, low ESR electrolytic capacitor, the

Nichicon "UD" series or the Panasonic "FK" series, is avail-

able. The RMS current in the input capacitor can be calculat-

ed.

The input capacitor power dissipation can be calculated as

follows.

The input capacitor must be able to handle the RMS current

and the P

parallel to handle large RMS currents. In some cases it may

be much cheaper to use multiple electrolytic capacitors than

a single low ESR, high performance capacitor such as OS-

CON or Tantalum. The capacitance value should be selected

such that the ripple voltage created by the charge and dis-

charge of the capacitance is less than 10% of the total ripple

across the capacitor.

PROGRAMMING THE CURRENT LIMIT (R

The current limit is determined by connecting a resistor

where:

Using the minimum value for I

current limit threshold will be set higher than the peak inductor

current.

The R

at the ADJ pin does not fall below 3.5V. With this in mind,

set the desired current limit, either use a PFET with a lower

The current limit function can be disabled by connecting the

ADJ pin to ground and ISENSE to VIN.

CATCH DIODE SELECTION (D1)

The important parameters for the catch diode are the peak

current, the peak reverse voltage, and the average power

dissipation. The average current through the diode can be

calculated as following.

ADJ_MAX

DSON

ADJ

CL_ADJ

IND_PEAK

DSON

) between input voltage and the ADJ pin.

ADJ

, or use a current sense resistor as shown in

: Drain-Source ON resistance of the external PFET

: 3.0µA minimum

= (V

value must be selected to ensure that the voltage

. Several input capacitors may be connected in

= I

LOAD

-3.5)/7µA. If a larger R

ADJ

D(CIN)

+ I

= I

D_AVE

RIPPLE

IND_PEAK

= I

RMS_CIN

= I

OUT

CL_ADJ

* R

(1 − D)

DSON

* ESR

(3.0µA) ensures that the

ADJ

)

CL_ADJ

CIN

value is needed to

ADJ

)

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LM3485LED EVAL National Semiconductor, LM3485LED EVAL Datasheet - Page 11

LM3485LED EVAL

Specifications of LM3485LED EVAL

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