LM25088MH-1/NOPB National Semiconductor, LM25088MH-1/NOPB Datasheet - Page 19

LM25088MH-1/NOPB

Manufacturer Part Number

LM25088MH-1/NOPB

Description

IC CTLR BUCK NON-SYNC 16-TSSOP

Manufacturer

National Semiconductor

Series

PowerWise®r

Type

Step-Down (Buck)r

Datasheet

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

Specifications of LM25088MH-1/NOPB

Design Resources

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

Internal Switch(s)

Synchronous Rectifier

Number Of Outputs

Voltage - Output

1.21 ~ 45 V

Current - Output

10A

Frequency - Switching

200kHz, 500kHz

Voltage - Input

4.5 ~ 42 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

16-TSSOP Exposed Pad, 16-eTSSOP, 16-HTSSOP

Primary Input Voltage

42V

No. Of Outputs

Output Voltage

1.2V

Output Current

10A

No. Of Pins

Operating Temperature Range

-40Â°C To +125Â°C

Msl

MSL 1 - Unlimited

Filter Terminals

SMD

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Power - Output

Other names

LM25088MH-1

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

LM25088MH-1/NOPB

Manufacturer:

NSC

Quantity:

800

Current page: 19 of 28
Download datasheet (554Kb)

OUTPUT VOLTAGE DIVIDER

resistors can be calculated from:

1.62 kΩ was chosen for R

value of R

(1.2V/ R

UVLO DIVIDER

A voltage divider can be connected to the EN pin to the set

the minimum startup voltage (VIN

feature is required, set the value of R

100 kΩ and then calculate R

In this design, for a VIN

54.9 kΩ resulting in a R

ed to install a capacitor parallel to R

pin is left open, the LM25088 will begin operation once the

upper VCC UV threshold of 4.0V (typ) is reached.

RESTART CAPACITOR (LM5008-2 only)

The basic operation of the hiccup mode current limit is de-

scribed in the functional description. In the LM25088-2 appli-

cation example the RES pin is configured for delayed hiccup

mode. Please refer to the functional description to configure

this pin in alternate configurations and also refer figure 8 for

the timing diagram. The delay time to initiate a hiccup cycle

(t1) is programmed by the selection of RES pin capacitor. In

the case of continuous cycle-by-cycle current limit detection

at the CS pin, the time required for C

given by

The cool down time (t2) is set by the time taken to discharge

the RES cap with 1.2 µA current source. This feature will re-

duce the input power drawn by the converter during a pro-

longed over current condition. In this application 500 µs of

delay time was selected. The minimum value of C

itor should be no less than 0.022 µF.

MOSFET SELECTION

Selection of the Buck MOSFET is governed by the same

tradeoffs as the switching frequency. Losses in power MOS-

FETs can be broken down into conduction losses and switch-

ing losses. The conduction loss is given by:

Where, D is the duty cycle and IO is the maximum load cur-

rent. The factor 1.3 accounts for the increase in MOSFET on-

resistance due to heating. Alternatively, for a more precise

calculation, the factor of 1.3 can be ignored and the on-resis-

tance of the MOSFET can be estimated using the R

Temperature curves in the MOSFET datasheet.

The switching loss occurs during the brief transition period as

the MOSFET turns on and off. During the transition period

FB1

FB2

and R

value of 5.11 kΩ. A reasonable guide is to select the

FB1

FB2

) is in between 1 mA and 100 µA.

value such that the current through the resistor

set the output voltage level, the ratio of these

= D x (I

UV1

(min)

FB1

value of 16.2 kΩ. it is recommend-

UV1

of 5V, R

in this design which results in a

x R

from:

DS(ON)

(min)

UV1

UV2

RES

) of the regulator. If this

UV2

x 1.3)

for filtering. If the EN

between 10 kΩ and

to reach the 1.2V is

was selected to be

RES

DS(ON)

capac-

vs.

both current and voltage are present in the MOSFET. The

switching loss can be approximated as:

Where, t

The rise and fall times are usually mentioned in the MOSFET

datasheet or can be empirically observed on the scope. An-

other loss, which is associated with the buck MOSFET is the

“gate-charging loss”. This loss differs from the above two

losses in the sense that it is dissipated in the LM25088 and

not in the MOSFET itself. Gate charging loss, P

from the current driving charging the gate capacitance of the

power MOSFETs and is approximated as:

For this example with the maximum input voltage of 36V, the

Vds breakdown rating of the selected MOSFET must be

greater than 36V plus any ringing across drain to source due

to parasitics. In order to minimize switching time and gate

drive losses, the selected MOSFET must also have low gate

charge (Q

ample is the SI7848DP which has a total gate charge of 30nC

and rise and fall times of 10 ns and 12 ns respectively.

DIODE SELECTION

A Schottky type re-circulating diode is required for all

LM25088 applications. The near ideal reverse recovery cur-

rent transients and low forward voltage drop are particularly

important diode characteristics for high input voltage and low

output voltage applications common to LM25088. The diode

switching loss is minimized in a Schottky diode because of

near ideal reverse recovery. The conduction loss can be ap-

proximated by:

Where, V

to assume a short circuit load condition. In this case, the diode

will carry the output current almost continuously. The reverse

breakdown rating should be selected for the maximum input

voltage level plus some additional safety margin to withstand

ringing at the SW node. For this application a 45V On Semi-

conductor Schottky diode (MBRB1545) with a specified for-

ward drop of 0.5V at 7A at a junction temperature of 50°C was

selected. For output loads of 5A and greater and high input

voltage applications, a diode in a D

mended to support the worst case power dissipation

SNUBBER COMPONENTS SELECTION

Excessive ringing and spikes can cause erratic operation and

couple spikes and noise to the output. Voltage spikes beyond

the rating of the LM25088 or the re-circulating diode can dam-

age these devices. A snubber network across the power

diode reduces ringing and spikes at the switching node. Se-

lecting the values for the snubber is best accomplished

through empirical methods. First, make sure that the lead

lengths for the snubber connections are very short. For the

current levels typical for the LM25088, a resistor value be-

tween 3 and 10Ω should be adequate. As a rule of thumb, a

snubber capacitor which is 4~5 times the Schottky diode’s

junction capacitance will reduce spikes adequately. Increas-

ing the value of the snubber capacitor will result in more

damping but also results in higher losses. The resistor’s pow-

er dissipation is independent of the resistance value as the

resistor dissipates the energy stored by the snubber capaci-

tor. The resistor’s power dissipation can be approximated as:

and t

is the forward drop of the diode. The worst case is

). A good choice of MOSFET for this design ex-

R_SNUB

= 0.5 x V

are the rise and fall times of the MOSFET.

dc_diode

= C

= VCC x Q

= (1 - D) x I

SNUB

x I

x VIN

x (t

x f

PAK package is recom-

max

+ t

x V

) x f

x f

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LM25088MH-1/NOPB National Semiconductor, LM25088MH-1/NOPB Datasheet - Page 19

LM25088MH-1/NOPB

Specifications of LM25088MH-1/NOPB

Available stocks

Related parts for LM25088MH-1/NOPB