LM5022LEDEVAL National Semiconductor, LM5022LEDEVAL Datasheet - Page 18

LM5022LEDEVAL

Manufacturer Part Number

LM5022LEDEVAL

Description

BOARD EVALUATION FOR LM5022

Manufacturer

National Semiconductor

Series

PowerWise®r

Datasheets

1.LM5022MMNOPB.pdf (22 pages)

2.LM5022LEDEVAL.pdf (8 pages)

Specifications of LM5022LEDEVAL

Current - Output / Channel

Outputs And Type

1, Non-Isolated

Voltage - Output

40V

Features

Dimmable

Voltage - Input

10 ~ 14V

Utilized Ic / Part

LM5022

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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MOSFET SWITCHING LOSS

MOSFET AND R

OUTPUT DIODE LOSS

The average output diode current is equal to I

estimated forward drop, V

therefore:

INPUT CAPACITOR LOSS

This term represents the loss as input ripple current passes

through the ESR of the input capacitor bank. In this equation

‘n’ is the number of capacitors in parallel. The 4.7 µF input

capacitors selected have a combined ESR of approximately

1.5 mΩ, and Δi

OUTPUT CAPACITOR LOSS

This term is calculated using the same method as the input

capacitor loss, substituting the output capacitor RMS current

for V

approximately 1.5 mΩ.

BOOST INDUCTOR LOSS

The typical DCR of the selected inductor is 40 mΩ.

= 0.5 x 13.8 x 1.5 x (10 ns + 12 ns) x 5 x 10

= 13.8V. The output capacitors' combined ESR is also

CIN

O-RMS

IN-RMS

= [0.16

= 0.66 x (1.5

= 13.8 X (3.5m + 13.5m) = 235 mW

= D x (I

= 1.13 x 1.5 x (0.66 x 0.34)

for a 13.8V input is 0.55A:

= 0.29 x Δi

SNS

= 0.5 x V

= [0.8 x 0.0015] / 2 = 0.6 mW

x 0.0015] / 2 = 0.02 mW (negligible)

CONDUCTION LOSS

= 0.5 x 0.5 = 0.25W

DCR

x (R

x (0.029 + 0.1)) = 192 mW

, is 0.5V. The output diode loss is

= I

x I

DSON

= 0.29 x 0.55 = 0.16A

x DCR

x V

x (t

x 1.3 + R

+ t

FIGURE 11. Boost Converter Current Loops

) x f

0.5

SNS

= 0.8A

, or 0.5A. The

))

= 114 mW

Core loss in the inductor is estimated to be equal to the DCR

loss, adding an additional 90 mW to the total inductor loss.

TOTAL LOSS

EFFICIENCY

Layout Considerations

To produce an optimal power solution with the LM5022, good

layout and design of the PCB are as important as the com-

ponent selection. The following are several guidelines to aid

in creating a good layout.

FILTER CAPACITORS

The low-value ceramic filter capacitors are most effective

when the inductance of the current loops that they filter is

minimized. Place C

GND pins of the LM5022. Place C

SENSE LINES

The top of R

separate trace made as short as possible. Route this trace

away from the inductor and the switch node (where D1, Q1,

and L1 connect). For the voltage loop, keep R

the LM5022 and run a trace from as close as possible to the

positive side of C

should be routed away from the inductor and the switch node.

These measures minimize the length of high impedance lines

and reduce noise pickup.

COMPACT LAYOUT

Parasitic inductance can be reduced by keeping the power

path components close together and keeping the area of the

loops that high currents travel small. Short, thick traces or

copper pours (shapes) are best. In particular, the switch node

should be just large enough to connect all the components

together without excessive heating from the current it carries.

The LM5022 (boost converter) operates in two distinct cycles

whose high current paths are shown in

next to the VCC and GND pins of the LM5022.

LOSS

SNS

= Sum of All Loss Terms = 972 mW

η = 20 / (20 + 0.972) = 95%

should be connected to the CS pin with a

DCR

INX

to R

= 1.5

as close as possible to the VIN and

FB2

. As with the CS line, the FB line

x 0.04 = 90 mW

20212252

close to the load, and

Figure

11:

FB1/2

close to

LM5022LEDEVAL National Semiconductor, LM5022LEDEVAL Datasheet - Page 18

LM5022LEDEVAL

Specifications of LM5022LEDEVAL

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