NE567D.602 NXP Semiconductors, NE567D.602 Datasheet - Page 10

NE567D.602

Manufacturer Part Number

NE567D.602

Description

Manufacturer

NXP Semiconductors

Datasheet

1.NE567D.602.pdf (18 pages)

Specifications of NE567D.602

Operating Temperature (max)

70C

Operating Temperature (min)

Package Type

Pin Count

Mounting

Surface Mount

Lead Free Status / Rohs Status

Compliant

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minimum lock-up time is not achievable. We must simply wait for the

about 10 cycles per bit, corresponding to an information transfer rate

Philips Semiconductors

SPEED OF OPERATION

Minimum lock-up time is related to the natural frequency of the loop.

The lower it is, the longer becomes the turn-on transient. Thus,

maximum operating speed is obtained when C

When the signal is first applied, the phase may be such as to initially

drive the controlled oscillator away from the incoming frequency

rather than toward it. Under this condition, which is of course

unpredictable, the lock-up transient is at its worst and the theoretical

transient to die out.

The following expressions give the values of C

highest operating speeds for various band center frequencies. The

minimum rate at which digital information may be detected without

information loss due to the turn-on transient or output chatter is

of f

In cases where turn-off time can be sacrificed to achieve fast

turn-on, the optional sensitivity adjustment circuit can be used to

move the quiescent C

voltage). However, sensitivity to beat frequencies, noise and

extraneous signals will be increased.

OPTIONAL CONTROLS

The 567 has been designed so that, for most applications, no

external adjustments are required. Certain applications, however,

will be greatly facilitated if full advantage is taken of the added

control possibilities available through the use of additional external

components. In the diagrams given, typical

values are suggested where applicable. For best results the

resistors used, except where noted, should have the same

temperature coefficient. Ideally, silicon diodes would be

low-resistivity types, such as forward-biased transistor base-emitter

junctions. However, ordinary low-voltage diodes should be adequate

for most applications.

2002 Sep 25

Tone decoder/phase-locked loop

/10 baud.

130

260

voltage lower (closer to the threshold

(Figure 19)

is at a minimum.

and C

which allow

out-band signal rejection. This will inevitably slow the response time.

SENSITIVITY ADJUSTMENT

When operated as a very narrow-band detector (less than 8%), both

If, however, the output stage is biased closer to the threshold level,

the turn-on time can be improved. This is accomplished by drawing

additional current to terminal 1. Under this condition, the 567 will

also give an output for lower-level signals (10 mV or lower).

By adding current to terminal 1, the output stage is biased further

away from the threshold voltage. This is most useful when, to obtain

maximum operating speed, C

Normally, frequencies just outside the detection band could cause

false outputs under this condition. By desensitizing the output stage,

the out-band beat notes do not feed through to the output stage.

Since the input level must be somewhat greater when the output

stage is made less sensitive, rejection of third harmonics or in-band

harmonics (of lower frequency signals) is also improved.

and C

are made quite large in order to improve noise and

DECREASE

SENSITIVITY

567

Figure 19. Sensitivity adjustment

V+

50k

and C

V+

1.0k

2.5k

(Figure 19)

are made very small.

INCREASE

SENSITIVITY

SILICON

DIODES FOR

TEMPERATURE

COMPENSATION

(OPTIONAL)

NE567/SE567

567

DECREASE

SENSITIVITY

INCREASE

SENSITIVITY

SL00556

Product data

NE567D.602 NXP Semiconductors, NE567D.602 Datasheet - Page 10

NE567D.602

Specifications of NE567D.602

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