LTC3129-1_15 Datasheet, PDF(17/30 Page) Linear Technology – 15V, 200mA Synchronous Buck-Boost DC/DC Converter with 1.3A Quiescent Current

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LTC3129-1_15 Datasheet, PDF (17/30 Pages) Linear Technology – 15V, 200mA Synchronous Buck-Boost DC/DC Converter with 1.3A Quiescent Current

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LTC3129-1

Operation

high resistance values that would not be practical due to the

effects of noise and board leakages that would cause VOUT

regulation errors. The tap point on this divider is digitally

selected by using the VS1, VS2 and VS3 pins to program

one of eight fixed output voltages. The VS pins should be

grounded or connected to VCC to select the desired output

voltage, according to the following table. The VS1, VS2

and VS3 pins can also be driven by external logic signals

as long as the absolute maximum voltage ratings are not

exceeded. Note however that driving any of the voltage

select pins high to a voltage less than the VCC operating

voltage will result in increased quiescent current. Also

note that if the VS3 pin is driven above VCC, an external

1M resistor should be added in series. For other output

voltages, refer to the LTC3129 which has a feedback pin,

allowing any output voltage from 1.4V to 15.75V.

VOUT Program Settings for the LTC3129-1

VS3 PIN

VS2 PIN

VS1 PIN

VOUT

2.5V

VCC

3.3V

VCC

4.1V

VCC

5.0V

VCC

6.9V

VCC

8.2V

VCC

12V

VCC

15V

Note that in shutdown, or if VCC is below its UVLO thresh-

old, the internal voltage divider on VOUT is automatically

disconnected to eliminate any current draw on VOUT.

Thermal Considerations

The power switches of the LTC3129-1 are designed to op-

erate continuously with currents up to the internal current

limit thresholds. However, when operating at high current

levels, there may be significant heat generated within the

IC. In addition, the VCC regulator can also generate wasted

heat when VIN is very high, adding to the total power

dissipation of the IC. As described elsewhere in this data

sheet, bootstrapping of the VCC for 5V output applications

can essentially eliminate the VCC power dissipation term

and significantly improve efficiency. As a result, careful

consideration must be given to the thermal environment

of the IC in order to provide a means to remove heat from

the IC and ensure that the LTC3129-1 is able to provide

its full rated output current. Specifically, the exposed die

attach pad of both the QFN and MSE packages must be

soldered to a copper layer on the PCB to maximize the

conduction of heat out of the IC package. This can be ac-

complished by utilizing multiple vias from the die attach

pad connection underneath the IC package to other PCB

layer(s) containing a large copper plane. A typical board

layout incorporating these concepts is shown in Figure 4.

If the IC die temperature exceeds approximately 180Â°C,

overtemperature shutdown will be invoked and all switching

will be inhibited. The part will remain disabled until the die

temperature cools by approximately 10Â°C. The soft-start

circuit is re-initialized in over temperature shutdown to

provide a smooth recovery when the IC die temperature

cools enough to resume operation.

GND

VCC

VIN

CIN

CBST1

CBST2

GND

COUT

VOUT

31291 F04

Figure 4. Typical 2-Layer PC Board Layout (MSE Package)

For more information www.linear.com/LTC3129-1

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