SC4519HEVB-3 Semtech, SC4519HEVB-3 Datasheet - Page 9

SC4519HEVB-3

Manufacturer Part Number

SC4519HEVB-3

Description

EVALUATION BOARD

Manufacturer

Semtech

Datasheet

1.SC4519HSETRT.pdf (14 pages)

Specifications of SC4519HEVB-3

Silicon Manufacturer

Semtech

Application Sub Type

Step Down Switching Regulator

Kit Application Type

Power Management - Voltage Regulator

Silicon Core Number

SC4519H

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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capacitor must be able to provide the ripple current

drawn by the converter. For the continuous conduction

mode, the RMS value of the input capacitor current

This current gives the capacitor’s power loss through its

The input ripple voltage mainly depends on the input

capacitor’s ESR and its capacitance for a given load, input

voltage and output voltage. Assuming that the input

current of the converter is constant, the required input

capacitance for a given voltage ripple can be calculated

by:

Where:

Because the input capacitor is exposed to the large surge

current, attention is needed for the input capacitor. If

tantalum capacitors are used at the input side of the

converter, one needs to ensure that the RMS and surge

ratings are not exceeded. For generic tantalum

capacitors, it is suggested to derate their voltage ratings

at a ratio of about two to protect these input capacitors.

Boost Capacitor and its Supply Source Selection

The boost capacitor selection is based on its discharge

ripple voltage, worst case conduction time and boost

current. The worst case conduction time T

estimated as follows:

Where:

Dmax = maximum duty ratio, 0.85 for the SC4519H.

The required minimum capacitance for the boost

capacitor will be:

POWER MANAGEMENT

Application Information (Cont.)

CIN(RMS)

CIN(ESR)

2007 Semtech Corp.

= the switching frequency and

= the given input voltage ripple.

can be calculated from:

as follows:

CIN

(RMS)

OMAX

CIN

boost

CIN

OMAX

(

(RMS)

max

OMAX

CIN(ESR)

CIN

(ESR)

)

can be

Where:

With f

minimum capacitance for the boost capacitor is:

The internal driver of the switch requires a minimum 2.7V

to fully turn on that switch to reduce its conduction loss.

If the output voltage is less than 2.7V, the boost capacitor

can be connected to either the input side or an

independent supply with a decoupling capacitor. But the

Pin BST should not see a voltage higher than its maximum

rating.

Freewheeling Diode Selection

This diode conducts during the switch’s off-time. The diode

should have enough current capability for full load and

short circuit conditions without any thermal concerns.

Its maximum repetitive reverse block voltage has to be

higher than the input voltage of the SC4519H. A low

forward conduction drop is also required to increase the

overall efficiency. The freewheeling diode should be

turned on and off fast with minimum reverse recovery

because the SC4519H is designed for high frequency

applications. SS23 Schottky rectifier is recommended

for certain applications. The average current of the diode,

Thermal Considerations

There are three major power dissipation sources for the

SC4519H. The internal switch conduction loss, its

switching loss due to the high frequency switching actions

and the base drive boost circuit loss. These losses can

be estimated as:

Where:

connection.

BOOST

total

= the boost current and

= discharge ripple voltage.

= load current;

AVG

= on-equivalent resistance of the switch;

= input voltage or output based on the boost circuit

can be calculated by:

= 600kHz, V

boost

10.8

AVG

= 0.5V and I

max

omax

0.045

0.5

I (

600k

=0.045A, the required

1000

)

0.85

SC4519H

www.semtech.com

128nF

boost

)

SC4519HEVB-3 Semtech, SC4519HEVB-3 Datasheet - Page 9

SC4519HEVB-3

Specifications of SC4519HEVB-3

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