AAT3223 Datasheet, PDF(11/17 Page) Advanced Analogic Technologies – 250mA NanoPower LDO Linear Regulator with Power -OK

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AAT3223 Datasheet, PDF (11/17 Pages) Advanced Analogic Technologies – 250mA NanoPower LDO Linear Regulator with Power -OK

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Ceramic Capacitor Materials: Ceramic capaci-

tors less than 0.1ÂµF are typically made from NPO

or C0G materials. NPO and C0G materials are

typically tight tolerance and are very stable over

temperature. Larger capacitor values are typically

composed of X7R, X5R, Z5U, and Y5V dielectric

materials. Large ceramic capacitors, typically

greater than 2.2ÂµF, are often available in the low-

cost Y5V and Z5U dielectrics. These two material

types are not recommended for use with LDO reg-

ulators since the capacitor tolerance can vary more

than Â±50% over the operating temperature range of

the device. A 2.2ÂµF Y5V capacitor could be

reduced to 1ÂµF over the full operating temperature

range. This can cause problems for circuit opera-

tion and stability. X7R and X5R dielectrics are

much more desirable. The temperature tolerance

of X7R dielectric is better than Â±15%.

Capacitor area is another contributor to ESR.

Capacitors that are physically large in size will have

a lower ESR when compared to a smaller sized

capacitor of equivalent material and capacitance

value. These larger devices can also improve cir-

cuit transient response when compared to an equal

value capacitor in a smaller package size.

Consult capacitor vendor data sheets carefully when

selecting capacitors for use with LDO regulators.

Enable Function

The AAT3223 features an LDO regulator enable /

disable function. This pin (EN) is compatible with

CMOS logic. For a logic high signal, the EN control

level must be greater than 2.0 volts. A logic low

signal is asserted when the voltage on the EN pin

falls below 0.5 volts. For example, the active high

version AAT3223 will turn on when a logic high is

applied to the EN pin. If the enable function is not

needed in a specific application, it may be tied to

the respective voltage level to keep the LDO regu-

lator in a continuously on state; e.g., the active high

version AAT3223 will tie VIN to EN to remain on.

Power-OK Function

The Power-OK (POK) function is a very useful

basic active low error flag. When the AAT3223

output voltage level is within regulation limits, the

POK output pin is a high impedance and should be

tied high to the LDO output through a high value

3223.2005.04.1.4

AAT3223

250mA NanoPowerâ¢ LDO

Linear Regulator with Power-OK

resistor (100kâ¦ is a good resistor value for this pur-

pose). An internal comparator has a reference

threshold set to trigger at 10% of the nominal

AAT3223 output voltage. If the output voltage level

drops below this preset threshold, the POK func-

tion will become active and turn on an open-drain

N-channel MOSFET to pull the POK output pin to

ground. There is a fixed 1ms delay circuit between

the POK comparator output and the N-channel

MOSFET gate. The purpose of the delay is to pre-

vent a false triggering of the POK output during

device turn-on or during very short duration load

transient events. If necessary, additional POK flag

delay can be added by placing a capacitor in paral-

lel with the POK pull-up resistor. The additional

delay time will be set by the RC time constant, the

pull-up resistor, and parallel capacitor values.

When the AAT3223 is in the shutdown state with

the EN pin low, the POK pin becomes low imped-

ance. The LDO output will be discharged through

the high value POK pull-up resistor. When entering

the shutdown state, there is no delay associated

with the POK output; the open-drain device turns

on immediately.

This offers the added advantage of having a hard

application turn-off when the LDO regulator is

turned off. This additional function has no adverse

effect on regulator turn-on time.

Short-Circuit and Thermal Protection

The AAT3223 is protected by both current limit and

over-temperature protection circuitry. The internal

short-circuit current limit is designed to activate

when the output load demand exceeds the maxi-

mum rated output. If a short-circuit condition were

to continually draw more than the current limit

threshold, the LDO regulator's output voltage will

drop to a level necessary to supply the current

demanded by the load. Under short-circuit or other

over-current operating conditions, the output volt-

age will drop and the AAT3223's die temperature

will rapidly increase. Once the regulator's power

dissipation capacity has been exceeded and the

internal die temperature reaches approximately

140Â°C, the system thermal protection circuit will

become active. The internal thermal protection cir-

cuit will actively turn off the LDO regulator output

pass device to prevent the possibility of over-tem-

perature damage. The LDO regulator output will

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