ADP667 Analog Devices, ADP667 Datasheet - Page 5

ADP667

Manufacturer Part Number

ADP667

Description

+5 V Fixed, Adjustable Low-Dropout Linear Voltage Regulator

Manufacturer

Analog Devices

Datasheet

1.ADP667.pdf (8 pages)

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REV. 0

Dropout Detector

The ADP667 features an extremely low dropout voltage making

it suitable for low voltage systems where headroom is limited. A

dropout detector is also provided. The dropout detector output,

DD, changes as the dropout voltage approaches its limit. This is

useful for warning that regulation can no longer be maintained.

The dropout detector output is an open collector output from a

PNP transistor. Under normal operating conditions with the in-

put voltage more than 300 mV above the output, the PNP tran-

sistor is off and no current flows out the DD pin. As the voltage

differential reduces to less than 300 mV, the transistor switches

on and current is sourced. This condition indicates that regulation

can no longer be maintained. Please refer to Figure 10 in the

“Typical Performance Characteristics.” The current output can

be translated into a voltage output by connecting a resistor from

DD to GND. A resistor value of 100 k is suitable. A digital

status signal can be obtained using a comparator. The on-chip

comparator LBI may be used if it is not being used to monitor a

battery voltage. This is illustrated in Figure 5.

Output Capacitor Selection

An output capacitor is required on the ADP667 to maintain

stability and also to improve the load transient response. Ca-

pacitor values from 10 F upwards are suitable. All specifica-

tions are tested and guaranteed with 10 F. Capacitors larger

than 10 F will further improve the dynamic transient response

characteristics of the regulator. Tantalum or aluminum electro-

lytics are suitable for most applications. For temperatures below

about –25 C, solid tantalums should be used as many alumi-

num electrolytes freeze at this temperature.

Quiescent Current Considerations

The ADP667 uses a PNP output stage to achieve low dropout

voltages combined with high output current capability. Under

normal regulating conditions the quiescent current is extremely

low. However if the input voltage drops so that it is below the

desired output voltage, the quiescent current increases consider-

ably. This happens because regulation can no longer be main-

Figure 5. Dropout Status Output

LBI

SET

ADP667

GND

SHDN

OUT

LBO

100k

10µF

10k

+5V

OUTPUT

DROPOUT

STATUS

OUTPUT

–5–

tained and large base current flows in the PNP output transistor

in an attempt to hold it fully on. For minimum quiescent cur-

rent, it is therefore important that the input voltage is main-

tained higher than the desired output level. If the device is being

powered using a battery that can discharge down below the rec-

ommended level, there are a couple of techniques that can be

applied to reduce the quiescent current, but at the expense of

dropout voltage. The first of these is illustrated in Figure 6. By

connecting DD to SHDN the regulator is partially disabled with

input voltages below the desired output voltage and therefore

the quiescent current is reduced considerably.

Another technique for reducing the quiescent current near drop-

out is illustrated in Figure 7. The DD output is used to modify

the output voltage so that as V

age setpoint also drops. This technique only works when exter-

nal resistors are used to set the output voltage. With V

than V

reached, the DD output starts sourcing current into the SET

input through R3. This increases the SET voltage so that the

regulator feedback loop does not drive the internal PNP transis-

tor as hard as it otherwise would. As the input voltage continues

to decrease, more current is sourced, thereby reducing the PNP

drive even further. The advantage of this scheme is that it main-

tains a low quiescent current down to very low values of V

which point the batteries are well outside their useful operating

range. The output voltage tracks the input voltage minus the

dropout. The SHDN function is also unaffected and may be

used normally if desired.

OUT

, DD has no effect. As V

SHDN

Figure 6. IQ Reduction 1

Figure 7. IQ Reduction 2

GND

ADP667

SET

ADP667

GND

OUT

SET

SHDN

OUT

drops, the desired output volt-

47k

reduces and dropout is

332k

10µF

0.1µF

10µF

+5V

OUTPUT

ADP667

+5V

OUTPUT

greater

ADP667 Analog Devices, ADP667 Datasheet - Page 5

ADP667

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