LTC3589-2_15 Datasheet, PDF(43/50 Page) Linear Technology – 8-Output Regulator with Sequencing and I2C

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LTC3589-2_15 Datasheet, PDF (43/50 Pages) Linear Technology – 8-Output Regulator with Sequencing and I2C

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LTC3589/LTC3589-1/

LTC3589-2

OPERATION

The power dissipated by an LDO regulator is estimated by:

PD(LDO) =(VIN(LDO)â VLDO ) â¢ I LDO (W)

Where VLDO is the programmed output voltage, VIN(LDO)

is the LDO supply voltage, and ILDO is the output load

current. If one of the switching regulator outputs is used

as an LDO supply voltage, remember to include the LDO

supply current in the switching regulator load current for

calculating power loss.

An example using the equations above with the parameters

in Table 19 shows an application that is at the maximum

junction temperature of 125Â°C at an ambient temperature

of 85Â°C. LDO2, LDO3, and LDO4 are powered by step-

down switching regulator 2 and the buck-boost switching

regulator. The total load on those two switching regula-

tors is the sum of the application load and the LDO load.

This example is with the LDO regulators at one half rated

current and the switching regulators at three quarters

rated current.

Table 19. TJ Calculation Example

OUTPUT

VIN VOUT APP LOAD TOTAL EFF

LOAD

LDO1_VSTB 3.8V 1.2V 10mA 10mA

LDO2

1.8V 1.2V 100mA 100mA

LDO3

3.3V 1.8V 100mA 100mA

LDO4

3.3V 2.5V 100mA 100mA

VOUT1

VOUT2

VOUT3

VOUT4

3.8V 1.2V

3.8V 1.8V

3.8V 1.25V

3.8V 3.3V

1.2A

0.65A

0.75A

0.70A

1.2A 80%

0.75A 90%

0.75A 85%

0.90A 90%

TOTAL POWER

INTERNAL JUNCTION TEMPERATURE AT 85Â°C AMBIENT

POWER

DISS

30mW

60mW

150mW

80mW

290mW

140mW

300mW

1180mW

125Â°C

Printed Circuit Board Layout

When laying out the printed circuit board, the following

checklist should be followed to ensure proper operation

of the LTC3589:

1. Connect the exposed pad of the package (Pin 41)

directly to a large ground plane to minimize thermal

and electrical impedance.

2. The switching regulator input supply traces and their

decoupling capacitors should be as short as possible.

Connect the GND side of the capacitors directly to the

ground plane of the board. The decoupling capacitors

provide the AC current to the internal power MOSFETs

and their drivers. It is important to minimize inductance

from the capacitors to the LTC3589 pins.

3. Minimize the switching power traces connecting SW1,

SW2, SW3, and buck-boost switch pins SW4AB and

SW4CD to the inductors to reduce radiated EMI and

parasitic coupling. Keep sensitive nodes such as the

feedback pins away from or shielded from the large

voltage swings on the switching nodes.

4. Minimize the length of the connection between the

step-down switching regulator inductors and the output

capacitors. Connect the GND side of the output capaci-

tors directly to the thermal ground plane of the board.

5. Minimize the length of the connection between the

buck-boost regulator output (BB_OUT) and the output

capacitor. Connect the GND side of the output capacitor

directly to the thermal ground plane of the board.

For more information www.linear.com/LTC3589

3589fg

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