LTC3523-2_15 Datasheet, PDF(8/16 Page) Linear Technology – Synchronous 600mA Step-Up and 400mA Step-Down DC/DC Converters

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LTC3523-2_15 Datasheet, PDF (8/16 Pages) Linear Technology – Synchronous 600mA Step-Up and 400mA Step-Down DC/DC Converters

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LTC3523/LTC3523-2

OPERATION

The LTC3523 and LTC3523-2 are synchronous step-up and

step-down converters housed in a 16-pin QFN package.

Operating from inputs down to 1.8V, the devices feature

ï¬xed frequency, current mode PWM control for exceptional

line and load regulation and transient response. With

low RDS(ON) and internal MOSFET switches, the devices

maintain high efï¬ciency over a wide range of load cur-

rent. Operation can be best understood by referring to

the Block Diagram.

Soft-Start

Both the step-up and step-down converters on the LTC3523

/LTC3523-2 provide soft-start. The soft-start time is typi-

cally 500Î¼s. The soft-start function resets in the event of

a commanded shutdown or thermal shutdown.

Oscillator

The frequency of operation is set by an internal oscilla-

tor to a nominal 1.2MHz for the LTC3523 and nominal

2.4MHz for the LTC3523-2. The oscillator is shared by

both converters.

Shutdown

The step-up and the step-down converters have inde-

pendent shutdown pins. To shut down a converter, pull

SHDNx below 0.35V. To enable a converter, pull SHDNx

above 1.0V.

Error Ampliï¬ers

Power converter control loop compensation is provided

internally for each converter. The noninverting input is

internally connected to the 1.2V reference for the step-up

and 0.6V for the step-down. The inverting input is connected

to the respective FBx for both converters. Internal clamps

limit the minimum and maximum error amp output voltage

for improved large signal transient response. A voltage

divider from VOUT to ground programs the output voltage

via the respective FBx pins from 1.8V to 5.25V for the step-

up and 0.615V to 5.5V for the step-down. From the Block

Diagram the design equation for programming the output

voltages is VOUT = 1.2V â¢ [1 + (R1/R2)] for the step-up and

VOUT = 0.6V â¢ [1 + (R3/R4)] for the step-down.

PWM Comparators

The PWM comparators are used to compare the converters

external inductor current to the current commanded by

the error ampliï¬ers. When the inductor current reaches

the current commanded by the error ampliï¬er the induc-

tor charging cycle is terminated and the rectiï¬cation cycle

commences.

Current Limit

The current limit comparator shuts off the N-channel switch

for the step-up and P-channel switch for the step-down

once its current limit threshold is reached. The current

limit comparator delay to output is typically 40ns. Peak

switch current is limited to approximately 1000mA for

the step-up and 650mA for the step-down independent

of input or output voltage.

Zero Current Comparator

The zero current comparator monitors the inductor cur-

rent to the output and shuts off the synchronous rectiï¬er

once this current reduces to approximately 20mA. This

prevents the inductor current from reversing in polarity

improving efï¬ciency at light loads.

Power Good Comparator

Both converters have independent open drain power good

comparators which monitor the output voltage via their

respective FBx pins. The comparator output will allow the

PGOODx to be pulled up high when the output voltage

(VOUT) has exceeded 91% of it ï¬nal value. If the output

voltage decreases below 91%, the comparator will pull

the PGOODx pin to ground. The step-up comparator has

3.3% of hysteresis and the step-down has 6.6% relative

to FBx voltage for added noise immunity.

Step-Down Overvoltage Comparator

The step-down overvoltage comparator guards against

transient overshoots greater than 10% of the output volt-

age by turning the P-channel switch off until the transient

has subsided.

3523fb

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