LTC3520 Datasheet, PDF(11/24 Page) Linear Technology – Synchronous 1A Buck-Boost and 600mA Buck Converters

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LTC3520 Datasheet, PDF (11/24 Pages) Linear Technology – Synchronous 1A Buck-Boost and 600mA Buck Converters

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LTC3520

OPERATION

The LTC3520 combines a synchronous buck DC/DC

converter and a four-switch buck-boost DC/DC converter

in a single 4mm x 4mm QFN package. The buck-boost

converter utilizes a proprietary switching algorithm which

allows its output voltage to be regulated above, below, or

equal to the input voltage. The buck converter provides a

high efï¬ciency lower voltage output and supports 100%

duty cycle operation to extend battery life. In Burst Mode

operation, the total quiescent current for both converters

is reduced to 55ÂµA (typical). Both converters operate

synchronously from a common internal oscillator whose

frequency is programmed via an external resistor. In ad-

dition, the LTC3520 contains an uncommitted gain block

which can be conï¬gured as a comparator for low battery

detection or as a power-good indicator. Alternatively, the

gain block can be utilized in conjunction with an external

PNP to create an LDO, thereby allowing the LTC3520 to

generate a third low noise output voltage.

BUCK CONVERTER OPERATION

PWM Mode Operation

When the PWM2 pin is held high, the LTC3520 buck converter

uses a constant-frequency, current mode control architec-

ture. Both the main (P-channel MOSFET) and synchronous

rectiï¬er (N-channel MOSFET) switches are internal. At

the start of each oscillator cycle, the P-channel switch is

turned on and remains on until the current waveform with

superimposed slope compensation ramp exceeds the error

ampliï¬er output. At this point, the synchronous rectiï¬er is

turned on and remains on until the inductor current falls to

zero or a new switching cycle is initiated. As a result, the

buck converter operates with discontinuous inductor cur-

rent at light loads which improves efï¬ciency. At extremely

light loads, the minimum on-time of the main switch will

be reached and the buck converter will begin turning off for

multiple cycles in order to maintain regulation.

Burst Mode Operation

Burst Mode operation is enabled by either connecting

PWM2 to ground through a resistor, RBURST, or by shorting

PWM2 to ground. The buck converter will automatically

transition between PWM mode at high load current and

Burst Mode operation at light currents. Typical curves for

the Burst Mode entry threshold are provided in the Typical

Performance Characteristics section of this datasheet.

Under dropout and near dropout conditions, Burst Mode

operation will not be entered.

The value of RBURST controls the load current at which

Burst Mode operation will be entered. Larger resistor

values will cause Burst Mode operation to be entered at

lighter load currents. However, if the value of RBURST is

too large, then the buck converter will not enter Burst

Mode operation at any current, especially when operating

with VIN close to the buck output voltage. Conversely, if

RBURST is too small, the ripple in Burst Mode operation

may become objectionable, especially at high input volt-

ages. For most applications, choosing RBURST = 301k

represents a reasonable compromise.

The output voltage ripple in Burst Mode operation is de-

pendent upon the value of RBURST, the input voltage, the

output voltage, the inductor value and the output capaci-

tor. The Burst Mode operation output voltage ripple can

be reduced by increasing the size of the output capacitor,

increasing the value of the inductor or increasing the

value of RBURST.

Low Dropout Operation

As the input voltage decreases to a value approaching the

output regulation voltage, the duty cycle increases toward

the maximum on-time. Further reduction of the supply

voltage will force the power P-channel MOSFET switch

to remain on for more than one cycle until 100% duty

cycle operation is reached and the power switch remains

on continuously. In this dropout state, the output voltage

will be determined by the input voltage less the resistive

voltage drop across the main switch and series resistance

of the inductor.

Slope Compensation

Current mode control requires the use of slope compensa-

tion to prevent subharmonic oscillations in the inductor

current waveform at high duty cycle operation. This is ac-

complished internally on the LTC3520 through the addition

of a compensating ramp to the current sense signal. In

some current mode ICs, current limiting is performed by

clamping the error ampliï¬er voltage to a ï¬xed maximum.

3520f

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