LTC3633A-1_15 Datasheet, PDF(12/30 Page) Linear Technology – Dual Channel 3A, 20V Monolithic Synchronous Step-Down Regulator

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LTC3633A-1_15 Datasheet, PDF (12/30 Pages) Linear Technology – Dual Channel 3A, 20V Monolithic Synchronous Step-Down Regulator

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LTC3633A/LTC3633A-1

OPERATION

When running the LTC3633A channels out of phase, the

large current pulses are interleaved, effectively reducing

the amount of time the pulses overlap. Thus, the total

RMS input current is decreased, which both relaxes the

capacitance requirements for the VIN bypass capacitors

and reduces the voltage noise on the supply line.

One potential disadvantage to this configuration occurs

when one channel is operating at 50% duty cycle. In this

situation, switching noise can potentially couple from one

channel to the other, resulting in frequency jitter on one

or both channels. This effect can be mitigated with a well

designed board layout.

APPLICATIONS INFORMATION

A general LTC3633A application circuit is shown on the

first page of this data sheet. External component selection

is largely driven by the load requirement and switching

frequency. Component selection typically begins with

the selection of the inductor L and resistor RT. Once the

inductor is chosen, the input capacitor, CIN, and the out-

put capacitor, COUT, can be selected. Next, the feedback

resistors are selected to set the desired output voltage.

Finally, the remaining optional external components can be

selected for functions such as external loop compensation,

tracking/soft-start, input UVLO, and PGOOD.

Programming Switching Frequency

Selection of the switching frequency is a trade-off between

efficiency and component size. High frequency operation

allows the use of smaller inductor and capacitor values.

Operation at lower frequencies improves efficiency by

reducing internal gate charge losses but requires larger

inductance values and/or capacitance to maintain low

output ripple voltage.

Connecting a resistor from the RT pin to SGND programs

the switching frequency (f) between 500kHz and 4MHz

according to the following formula:

RRT

3.2E11

where RRT is in Î© and f is in Hz.

When RT is tied to INTVCC, the switching frequency will

default to approximately 2MHz, as set by an internal re-

sistor. This internal resistor is more sensitive to process

and temperature variations than an external resistor

(see Typical Performance Characteristics) and is best used

for applications where switching frequency accuracy is

not critical.

6000

5000

4000

3000

2000

1000

0 100 200 300 400 500 600 700

RT RESISTOR (kÎ©)

3633a F01

Figure 1. Switching Frequency vs RT

Inductor Selection

For a given input and output voltage, the inductor value and

operating frequency determine the inductor ripple current.

More specifically, the inductor ripple current decreases

with higher inductor value or higher operating frequency

according to the following equation:

âIL

ï£«

ï£ï£¬

VOUT

f â¢L

ï£¶

ï£¸ï£·

ï£«

ï£ï£¬1â

VOUT

VIN

ï£¶

ï£¸ï£·

Where ÎIL = inductor ripple current, f = operating frequency

and L = inductor value. A trade-off between component

size, efficiency and operating frequency can be seen from

this equation. Accepting larger values of âIL allows the

use of lower value inductors but results in greater inductor

core loss, greater ESR loss in the output capacitor, and

larger output voltage ripple. Generally, highest efficiency

operation is obtained at low operating frequency with

small ripple current.

3633a1fb

For more information www.linear.com/LTC3633A

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