LTC3569_15 Datasheet, PDF(17/26 Page) Linear Technology – Triple Buck Regulator with 1.2A and Two 600mA Outputs and Individual Programmable References

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LTC3569_15 Datasheet, PDF (17/26 Pages) Linear Technology – Triple Buck Regulator with 1.2A and Two 600mA Outputs and Individual Programmable References

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LTC3569

applications information

The second consideration is stray capacitance on the FB

pin traces and the RT pin trace to GND. This is taken into

account by cutting the ground plane beneath these traces.

However, wherever the ground plane is cut, add additional

decoupling capacitors across the break to provide a path

for high-frequency ground return currents to flow.

Finally, the third consideration is stray impedance between

the SW node and the inductor when operating with a slave

power stage. It is important to keep the stray inductance of

the slave power device to a minimum, by keeping the trace

from slave SW to the main SW as short as possible. This

requirement is necessary to ensure that the slave power

deviceâs share of the inductor current does not exceed that

of the master as well as to keep the current density in the

slave device under control. The inductor should be placed

close to the master SW pin to minimize stray impedance

and allow the master to control the inductor current.

Thermal Considerations

In the majority of applications, the LTC3569 does not dis-

sipate much heat due to its high efficiency. However, in

applications where the LTC3569 is running at high ambient

temperature with low supply voltage and high duty cycles,

such as in dropout, the heat dissipated may exceed the

maximum junction temperature of the part. If the junction

temperature reaches approximately 150Â°C, the LTC3569

will be turned off and 2k resistive pull-downs are tied to

all the SW nodes.

To prevent the LTC3569 from exceeding maximum junc-

tion temperature, the user will need to do some thermal

analysis. The goal of the thermal analysis is to determine

whether the power dissipated exceeds the maximum junc-

tion temperature of the part. Temperature rise is:

tRISE = PDâ¢ Î¸JA

Where PD is the power dissipated by the regulator and

Î¸JA is the thermal resistance from the junction of the die

to the ambient temperature.

The junction temperature, TJ, is given by:

TJ = tRISE + TA.

Where TA is the ambient temperature.

As an example, consider the case when the LTC3569 is

in dropout at an input voltage of 2.7V with load currents

of 1000mA, 500mA and 500mA for bucks 1, 2 and 3

respectively, at an ambient temperature of 85Â°C. From

the Typical Performance Characteristics, the RDS(ON) of

buck1 is 0.190â¦, and for buck2 and buck3 it is 0.265â¦.

Therefore, power dissipated by the LTC3569 is:

PD = I12 RDS(ON)1 + I22 RDS(ON)2 + I32 RDS(ON)3

= 190mV + 66.25mW + 66.25mV

= 322.5mW

At 85Â°C ambient the junction temperature is:

TJ = 322.5mWâ¢68Â°C/W + 85Â°C = 106.9Â°C.

This junction temperature is below the absolute maximum

junction temperature of 125Â°C.

Design Example 1: 2.5V, 1.8V and 1.2V From a

Li-Ion Battery

As a design example, consider using the LTC3569 in a

portable application with a Li-Ion battery source. The bat-

tery provides an SVIN from 2.9V to 4.2V. The loads require

2.5V, 1.8V and 1.2V with current requirements of up to

800mA, 400mA and 400mA respectively when active. The

first load, with the 2.5V rail has no standby requirements,

however loads 2 and 3 each require a current of 1mA in

standby. Since two of the loads require low current opera-

tion, Burst Mode operation is selected. With VIN(MAX) at

4.2V and VOUT(MIN) = 1.2V, the maximum clock frequency

is 3.57MHz based on minimum on-time requirements.

To simplify the board layout, the fixed 2.25MHz internal

frequency is selected.

For more information www.linear.com/LTC3569

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