LM25088MH-1EVAL National Semiconductor, LM25088MH-1EVAL Datasheet - Page 21

LM25088MH-1EVAL

Manufacturer Part Number

LM25088MH-1EVAL

Description

BOARD EVAL FOR LM25088MH-1

Manufacturer

National Semiconductor

Series

PowerWise®r

Datasheets

1.LM25088MH-2NOPB.pdf (28 pages)

2.LM25088MH-1EVAL.pdf (10 pages)

3.LM25088MH-1EVAL.pdf (26 pages)

Specifications of LM25088MH-1EVAL

Design Resources

LM(2)5088-1/2 QS Component Calculator

Main Purpose

DC/DC, Step Down

Outputs And Type

1, Non-Isolated

Voltage - Output

Current - Output

Voltage - Input

5.5 ~ 36V

Regulator Topology

Buck

Frequency - Switching

250kHz

Board Type

Fully Populated

Utilized Ic / Part

LM25088

Silicon Manufacturer

National

Silicon Core Number

LM25088

Kit Application Type

Power Management - Voltage Regulator

Application Sub Type

Buck Controller

Kit Contents

Board

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Power - Output

Lead Free Status / Rohs Status

Supplier Unconfirmed

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PCB BOARD LAYOUT AND THERMAL

CONSIDERATIONS

In a buck regulator there are two loops where currents are

switched very fast. The first loop starts from the input capac-

itors, through the buck MOSFET, to the inductor then out to

the load. The second loop starts from the output capacitor

ground, to the regulator PGND pins, to the current sense re-

sistor, through the Schottky diode, to the inductor and then

out to the load. Minimizing the area of these two loops reduces

the stray inductance and minimizes noise which can cause

erratic operation. A ground plane is recommended as a

means to connect the input filter capacitors of the output filter

capacitors and the PGND pin of the regulator. Connect all of

the low power ground connections (C

to the regulator GND pin. Connect the GND pin and PGND

pins together through to topside copper area covering the en-

tire underside of the device. Place several vias in this under-

side copper area to the ground plane. The input capacitor

ground connection should be as close as possible to the cur-

rent sense ground connection.

In a buck converter, most of the losses can be attributed to

MOSFET conduction and switching loss, re-circulating diode

conduction loss, inductor DCR loss and LM25088 VIN and

VCC loss. The other dissipative components in a buck con-

, R

, C

RAMP

) directly

verter produce losses but these other losses collectively ac-

count for about 2% of the total loss. Formulae to calculate all

the major losses are described in their respective sections of

this datasheet. The easiest method to determine the power

dissipated within the LM25088 is to measure the total con-

version losses (Pin-Pout), then subtract the power losses in

the Schottky diode, MOSFET, output inductor and snubber

resistor. When operating at 7A of output current and at 36V,

the power dissipation of the LM25088 is approximately 550

mW. The junction to ambient thermal resistance of the

LM25088 mounted in the evaluation board is approximately

40°C with no airflow. At 25°C ambient temperature and no

airflow, the predicted junction temperature will be 25+40*0.55

= 47°C. The LM25088 has an exposed thermal pad to aid in

power dissipation. Adding several vias under the device will

greatly reduce the controller junction temperature. The junc-

tion to ambient thermal resistance will vary with application.

The most significant variables are the area of copper in the

PC board; the number of vias under the IC exposed pad and

the amount of forced air cooling. The integrity of solder con-

nection from the IC exposed pad to the PC board is critical.

Excessive voids will greatly diminish the thermal dissipation

capacity.

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LM25088MH-1EVAL National Semiconductor, LM25088MH-1EVAL Datasheet - Page 21

LM25088MH-1EVAL

Specifications of LM25088MH-1EVAL

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