ADP222ACPZ-1218-R7 AD [Analog Devices], ADP222ACPZ-1218-R7 Datasheet - Page 19

ADP222ACPZ-1218-R7

Manufacturer Part Number

ADP222ACPZ-1218-R7

Description

Dual, 300 mA Output, Low Noise

Manufacturer

AD [Analog Devices]

Datasheet

1.ADP222ACPZ-1218-R7.pdf (24 pages)

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Data Sheet

ENABLE FEATURE

The

enable and disable the VOUTx pins under normal operating

conditions. Figure 67 shows a rising voltage on ENx crossing

the active threshold, where V

voltage on ENx crosses the inactive threshold, V

As shown in Figure 67, the ENx pins have built-in hysteresis.

This prevents on/off oscillations that can occur due to noise on

the ENx pins as it passes through the threshold points.

The active/inactive thresholds of the ENx pins are derived from

the VIN voltage. Therefore, these thresholds vary with changing

input voltage. Figure 68 shows typical ENx active/inactive thresholds

when the input voltage varies from 2.5 V to 5.5 V.

The

start to limit the inrush current when the output is enabled. The

start-up time for the 2.8 V option is approximately 240 µs from

the time the ENx active threshold is crossed to when the output

reaches 90% of its final value. The start-up time is somewhat

dependent on the output voltage setting and increases slightly as

the output voltage increases.

1.2

1.0

0.8

0.6

0.4

0.2

ADP222/ADP223/ADP224/ADP225

2.3

1.4

1.2

1.0

0.8

0.6

0.4

0.2

ENx FALL

ENx RISE

0.5

Figure 68. Typical Enable Thresholds vs. Input Voltage

2.7

Figure 67. Typical ENx Pin Operation, V

= 5.5V

0.6

3.1

0.7

3.5

ENABLE VOLTAGE (V)

0.8

3.9

OUTx

(V)

turns on. When a falling

0.9

4.3

1.0

4.7

use the ENx pins to

use an internal soft

= 5.5 V

1.1

5.1

OUTx

turns off.

5.5

1.2

Rev. B | Page 19 of 24

PARALLELING OUTPUTS TO INCREASE OUTPUT

CURRENT

The

reference voltage for each LDO. The reference voltages are

trimmed to plus or minus a couple of millivolts of each other.

This allows paralleling of the LDOs to increase the output

current to 600 mA. The adjust pins of each LDO are tied

together and a single output voltage divider sets the output

voltage. Even though the output voltage of each LDO is slightly

different, at high load currents, the resistance of the package

and the board layout absorbs the difference. Figure 70 shows

the schematic of a typical application where the LDO outputs

are paralleled.

QUICK OUTPUT DISCHARGE (QOD) FUNCTION

The

force the voltage on each output to zero when the respective

LDO is disabled. This ensures that the outputs of the LDOs are

always in a well-defined state, regardless if it is enabled or not.

The

function. Figure 71 compares the turn-off time of a 3.3 V output

LDO with and without the QOD function. Both LDOs have a

1 kΩ resistor connected to each output. The LDO with the

QOD function discharges the output to 0 V in less than 1 ms,

whereas the 1 kΩ load takes over 5 ms to do the same.

ADP224/ADP225

ADP223

ADP222/ADP223

OFF

3.5

3.0

2.5

2.0

1.5

1.0

0.5

Figure 70. Paralleling Outputs for Higher Output Current

= 3.3V

ADP222/ADP223/ADP224/ADP225

ENx

3.3V

2.8V

1.8V

1.2V

100

+ C1

ADP225

1µF

200

Figure 69. Typical Start-Up Time

300

EN1

EN2

GND

ADJ2

include an output discharge resistor to

use a single band gap to generate the

do not include the output discharge

400

TIME (µs)

500

VOUT1

VOUT2

ADJ1

VIN

600

700

VOUT2 = 2.8V

800

+ C2

1µF

900

1000

ADP222ACPZ-1218-R7 AD [Analog Devices], ADP222ACPZ-1218-R7 Datasheet - Page 19

ADP222ACPZ-1218-R7

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