LTC3448_15 Datasheet, PDF(8/20 Page) Linear Technology – 1.5MHz/2.25MHz, 600mA Synchronous Step-Down Regulator with LDO Mode

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LTC3448_15 Datasheet, PDF (8/20 Pages) Linear Technology – 1.5MHz/2.25MHz, 600mA Synchronous Step-Down Regulator with LDO Mode

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LTC3448

OPERATIO (Refer to Functional Diagram)

the VOUT pin and both the main and synchronous switches

are turned off. The control loop is stabilized by the load

capacitor and requires a minimum value of 2ÂµF. The

LTC3448 will change back to switching mode and turn off

the LDO when the load current exceeds approximately

11mA.

When MODE is connected to an intermediate voltage level

(i.e., VOUT), this switchover is automatic. If MODE is pulled

high to VIN, the LDO remains on and the switcher off

regardless of the load current. The LDO is capable of

providing a maximum of approximately 15mA before the

load regulation will degrade to unacceptable levels. If

MODE is pulled to GND, the switcher remains on and the

LDO off regardless of the load current.

4.5

4.0

VOUT = 1.2V

3.5

3.0

VOUT = 1.5V

2.5

VOUT = 1.8V

2.0

1.5

1.0

0.5

TA = 25Â°C

L = 2.2ÂµH

VIN (V)

3448 F02

Figure 2. ILDO(ON) vs VIN, VOUT

5.0

4.5

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

VIN = 3.6V

VOUT = 1.5V

TA = 25Â°C

8 10 12

INDUCTOR VALUE (ÂµH)

3448 F03

Figure 3. ILDO(ON) vs LOUT

Some applications may be able to anticipate the transition

from high to low and low to high load currents. In these

cases it may be desirable to switch between modes by

controlling the MODE pin with a processor signal. In these

applications it is important that the MODE pin is pulled

high no earlier than 50Âµs after the RUN pin is pulled high.

This will ensure proper start-up of internal reference

circuitry.

The load current ILDO(ON) below which the switcher will

automatically turn off and the LDO turn on is independent

of the external capacitor, and to first order, independent

of supply and output voltage. There is an inverse relation-

ship between ILDO(ON) and the value of the inductor.

These dependencies are shown in Figures 2 and 3.

Automatic operation with inductor values below 1ÂµH is

not recommended.

At the low load currents at which the switcher to linear

regulator transition occurs, the switcher is operating in

pulse skipping mode. During each switching cycle in this

mode, while the synchronous switch (bottom MOSFET) is

on, the inductor current decays until the reverse current

comparator is triggered. At this occurrence, the bottom

MOSFET is turned off. Ideally, this occurs when the

inductor current is precisely zero. In reality, because of on-

chip delays, this current will be negative at higher output

voltages.

The internal algorithm which controls the LDO turn-on

load current level makes certain assumptions about the

amount of charge transferred to the output on each

switching cycle. These assumptions are no longer met

when the inductor current begins to reverse. This causes

the load current at which the transition takes place to move

to lower levels at higher output voltages. For this reason

use of the LDO auto mode is not recommended for output

levels above 2V. For output voltages above 2V, the MODE

pin should be driven externally.

Short-Circuit Protection

When the output is shorted to ground, the main switch

cycle will be skipped, and the synchronous switch will

remain on for a longer duration. This allows the inductor

current more time to decay, thereby preventing runaway.

3448f

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