CS51413EDR8G ON Semiconductor, CS51413EDR8G Datasheet - Page 15

CS51413EDR8G

Manufacturer Part Number

CS51413EDR8G

Description

IC REG BUCK LV 1.5A SYNC 8SOIC

Manufacturer

ON Semiconductor

Type

Step-Down (Buck)r

Datasheet

1.CS51412ED8G.pdf (20 pages)

Specifications of CS51413EDR8G

Internal Switch(s)

Yes

Synchronous Rectifier

Number Of Outputs

Current - Output

1.5A

Frequency - Switching

520kHz

Voltage - Input

4.5 ~ 40 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Mounting Style

SMD/SMT

Primary Input Voltage

40V

No. Of Outputs

Output Current

1.5A

No. Of Pins

Operating Temperature Range

-40Â°C To +85Â°C

Current Rating

1.5A

Filter Terminals

SMD

Input Voltage Primary Max

40V

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Output

Power - Output

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

CS51413EDR8GOS

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

CS51413EDR8G

Manufacturer:

ON/安森美

Quantity:

20 000

Current page: 15 of 20
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to 3.3 V/500 mA regulator using 22 mH inductor and various

capacitor types. At the switching frequency, the low ESR

and ESL make the ceramic capacitors behave capacitively

as shown in Figure 21. Additional paralleled ceramic

capacitors will further reduce the ripple voltage, but

inevitably increase the cost. “POSCAP”, manufactured by

SANYO, is a solid electrolytic capacitor. The anode is

sintered tantalum and the cathode is a highly conductive

polymerized organic semiconductor. TPC series, featuring

low ESR and low profile, is used in the measurement of

Figure 22. It is shown that POSCAP presents a good balance

of capacitance and ESR, compared with a ceramic capacitor.

In this application, the low ESR generates less than 5.0 mV

of ripple and the ESL is almost unnoticeable. The ESL of the

through−hole OS−CON capacitor give rise to the inductive

impedance. It is evident from Figure 23 which shows the

step rise of the output ripple on the switch turn−on and large

spike on the switch turn−off. The ESL prevents the output

capacitor from quickly charging up the parasitic capacitor of

the inductor when the switch node is pulled below ground

through the catch diode conduction. This results in the spike

associated with the falling edge of the switch node. The D

package tantalum capacitor used in Figure 24 has the same

footprint as the POSCAP, but doubles the height. The ESR

of the tantalum capacitor is apparently higher than the

POSCAP. The electrolytic and tantalum capacitors provide

a low−cost solution with compromised performance. The

reliability of the tantalum capacitor is not a serious concern

for output filtering because the output capacitor is usually

free of surge current and voltage.

Diode Selection

current path when the power switch turns off. The peak

reverse voltage is equal to the maximum input voltage. The

peak conducting current is clamped by the current limit of

the IC. The average current can be calculated from:

Figure 21 to Figure 24 show the output ripple of a 5.0 V

The diode in the buck converter provides the inductor

I D(AVG) +

I O (V IN * V O )

V IN

http://onsemi.com

maximum load current and maximum input voltage. For the

diode to survive the short circuit condition, the current rating

of the diode should be equal to the Foldback Current Limit.

See Table 1 for Schottky diodes from ON Semiconductor

which are suggested for CS5141X regulator.

Inductor Selection

maximum load current, core and copper losses, component

height, output ripple, EMI, saturation and cost. Lower

inductor values are chosen to reduce the physical size of the

inductor. Higher value cuts down the ripple current, core

losses and allows more output current. For most

applications, the inductor value falls in the range between

2.2 mH and 22 mH. The saturation current ratings of the

inductor shall not exceed the I

current. The worse case occurs during maximum load

current. Check the vendor’s spec to adjust the inductor value

undercurrent loading. Inductors can lose over 50% of

inductance when it nears saturation.

performance. The ferrite core has benefits of small physical

size, and very low power dissipation. But be careful not to

operate these inductors too far beyond their maximum

ratings for peak current, as this will saturate the core.

Powered Iron cores are low cost and have a more gradual

saturation curve. The cores with an open magnetic path, such

as rod or barrel, tend to generate high magnetic field

radiation. However, they are usually cheap and small. The

cores providing a close magnetic loop, such as pot−core and

toroid, generate low electro−magnetic interference (EMI).

standard product lines suitable for CS5141X. Table 2 lists

three vendors, their products and contact information.

The worse case of the diode average current occurs during

When choosing inductors, one might have to consider

The DC current through the inductor is equal to the load

The core materials have a significant effect on inductor

There are many magnetic component vendors providing

I L(PK) + I O )

V O (V IN * V O )

2(f S )(L)(V IN )

L(PK)

, calculated according to

CS51413EDR8G ON Semiconductor, CS51413EDR8G Datasheet - Page 15

CS51413EDR8G

Specifications of CS51413EDR8G

Available stocks

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