LTC3419 Datasheet, PDF(8/16 Page) Linear Technology – Dual Monolithic 600mA Synchronous Step-Down Regulator

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LTC3419 Datasheet, PDF (8/16 Pages) Linear Technology – Dual Monolithic 600mA Synchronous Step-Down Regulator

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LTC3419

OPERATION

The LTC3419 uses a constant-frequency, current mode

architecture. The operating frequency is set at 2.25MHz.

Both channels share the same clock and run in-phase.

The output voltage is set by an external resistor divider

returned to the VFB pins. An error ampliï¬er compares the

divided output voltage with a reference voltage of 0.6V and

regulates the peak inductor current accordingly.

Main Control Loop

During normal operation, the top power switch (P-channel

MOSFET) is turned on at the beginning of a clock cycle

when the VFB voltage is below the reference voltage. The

current into the inductor and the load increases until the

peak inductor current (controlled by ITH) is reached. The

RS latch turns off the synchronous switch and energy

stored in the inductor is discharged through the bottom

switch (N-channel MOSFET) into the load until the next

clock cycle begins, or until the inductor current begins to

reverse (sensed by the IRCMP comparator).

The peak inductor current is controlled by the internally

compensated ITH voltage, which is the output of the er-

ror ampliï¬er. This ampliï¬er regulates the VFB pin to the

internal 0.6V reference by adjusting the peak inductor

current accordingly.

Light Load Operation

There are two modes to control the LTC3419 at light load

currents: Burst Mode operation and pulse-skipping mode.

Both automatically transition from continuous operation

to the selected mode when the load current is low.

To optimize efï¬ciency, Burst Mode operation can be selected

by grounding the MODE pin. When the load is relatively

light, the peak inductor current (as set by ITH) remains

ï¬xed at approximately 60mA and the PMOS switch operates

intermittently based on load demand. By running cycles

periodically, the switching losses are minimized.

The duration of each burst event can range from a few

cycles at light load to almost continuous cycling with

short sleep intervals at moderate loads. During the sleep

intervals, the load current is being supplied solely from

the output capacitor. As the output voltage droops, the

error ampliï¬er output rises above the sleep threshold,

signaling the burst comparator to trip and turn the top

MOSFET on. This cycle repeats at a rate that is dependent

on load demand.

For applications where low ripple voltage and constant-

frequency operation is a higher priority than light load

efï¬ciency, pulse-skipping mode can be used by connect-

ing the MODE pin to VIN. In this mode, the peak inductor

current is not ï¬xed, which allows the LTC3419 to switch

at a constant-frequency down to very low currents, where

it will begin skipping pulses.

Dropout Operation

When the input supply voltage decreases toward the

output voltage the duty cycle increases to 100%, which

is the dropout condition. In dropout, the PMOS switch is

turned on continuously with the output voltage being equal

to the input voltage minus the voltage drops across the

internal P-channel MOSFET and the inductor.

An important design consideration is that the RDS(ON)

of the P-channel switch increases with decreasing input

supply voltage (see Typical Performance Characteristics).

Therefore, the user should calculate the worst-case power

dissipation when the LTC3419 is used at 100% duty cycle

with low input voltage (see Thermal Considerations in the

Applications Information section).

Soft-Start

In order to minimize the inrush current on the input bypass

capacitor, the LTC3419 slowly ramps up the output voltage

during start-up. Whenever the RUN1 or RUN2 pin is pulled

high, the corresponding output will ramp from zero to

full-scale over a time period of approximately 750Î¼s. This

prevents the LTC3419 from having to quickly charge the

output capacitor and thus supplying an excessive amount

of instantaneous current.

Short-Circuit Protection

When either regulator output is shorted to ground, the

corresponding internal N-channel switch is forced on for

a longer time period for each cycle in order to allow the

inductor to discharge, thus preventing inductor current

runaway. This technique has the effect of decreasing

switching frequency. Once the short is removed, normal

operation resumes and the regulator output will return to

its nominal voltage.

3419f

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