SA571NG ON Semiconductor, SA571NG Datasheet - Page 4

SA571NG

Manufacturer Part Number

SA571NG

Description

IC COMPANDOR DUAL GAIN 16-DIP

Manufacturer

ON Semiconductor

Type

Compandorr

Datasheet

1.SA571NG.pdf (11 pages)

Specifications of SA571NG

Applications

Cellular Radio, Players

Mounting Type

Through Hole

Package / Case

16-DIP (0.300", 7.62mm)

Product

General Purpose Audio Amplifiers

Operating Supply Voltage

6 V to 18 V

Supply Current

4.2 mA

Maximum Power Dissipation

400 mW

Maximum Operating Temperature

+ 85 C

Mounting Style

Through Hole

Minimum Operating Temperature

- 40 C

Supply Voltage (max)

18 V

Supply Voltage (min)

6 V

Operating Temperature (min)

-40C

Operating Temperature (max)

85C

Operating Temperature Classification

Industrial

Mounting

Through Hole

Pin Count

Package Type

PDIP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

SA571NG
SA571NGOS

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Part Number

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Quantity

Price

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Circuit Description

block diagram, are a full−wave rectifier, a variable gain cell,

an operational amplifier and a bias system. The arrangement

of these blocks in the IC result in a circuit which can perform

well with few external components, yet can be adapted to

many diverse applications.

flows from the rectifier input, to an internal summing node

which is biased at V

an external filter capacitor tied to the C

the average value of the input current controls the gain of the

variable gain cell. The gain will thus be proportional to the

average value of the input signal for capacitively−coupled

voltage inputs as shown in the following equation. Note that

for capacitively−coupled inputs there is no offset voltage

capable of producing a gain error. The only error will come

from the bias current of the rectifier (supplied internally)

which is less than 0.1 mA.

input signal levels is determined by the rectifier filter

capacitor. A small capacitor will yield rapid response but

will not fully filter low frequency signals. Any ripple on the

gain control signal will modulate the signal passing through

the variable gain cell. In an expander or compressor

application, this would lead to third harmonic distortion, so

there is a trade−off to be made between fast attack and decay

times and distortion. For step changes in amplitude, the

change in gain with time is shown by this equation.

with the ratio I

current which flows from the DG input to an internal

summing node biased at V

applies for capacitively−coupled inputs. The output current,

compensates for temperature and cancels out odd harmonic

distortion. The only distortion which remains is even

harmonics, and they exist only because of internal offset

voltages. The THD trim terminal provides a means for

nulling the internal offsets for low distortion operation.

compensated) has the non−inverting input tied to V

the inverting input connected to the DG cell output as well

OUT

The SA571 compandor building blocks, as shown in the

The full−wave rectifier rectifies the input current which

The speed with which gain changes to follow changes in

The variable gain cell is a current−in, current−out device

A compensation scheme built into the DG cell

The

, is fed to the summing node of the op amp.

G(t) + (G

operational

t + 10kW

OUT

G T

initial

REF

G T

. The rectified current is averaged on

amplifier

controlled by the rectifier. I

* G

| V

* V

RECT

REF

final

REF

| avg

) e

. The following equation

(which

| avg

) G

RECT

final

terminal, and

internally

REF

http://onsemi.com

is the

, and

SA571

as brought out externally. A resistor, R

the summing node and allows compressor or expander gain

to be determined only by internal components.

This allows a +13 dBm (3.5 V

which, with a series resistor and proper transformer, can

result in +13 dBm with a 600 W output impedance.

summing nodes, a regulated supply voltage for the rectifier

and DG cell, and a bias current for the DG cell. The low

tempco of this type of reference provides very stable biasing

over a wide temperature range.

shows the basic input−output transfer curve for basic

compressor or expander circuits.

The output stage is capable of ± 20 mA output current.

A bandgap reference provides the reference voltage for all

The typical performance characteristics illustration

2.2mF

3, 14

2, 15

Figure 2. Basic Input−Output Transfer Curve

20kW

10kW

+20

+10

−10

−20

−30

−40

−50

−60

−70

−80

Figure 3. Typical Test Circuit

−40

EXPANDOR INPUT LEVEL (dBm)

COMPRESSOR OUTPUT LEVEL

0.1mF

= 15V

1, 16

2.2mF

−30 −20 −10

RMS

5, 12

8.2kW

30kW

20kW

) output into a 300 W load

−

10mF

REF

, is brought out from

8, 9

+10

200pF

6, 11

7, 10

SA571NG ON Semiconductor, SA571NG Datasheet - Page 4

SA571NG

Specifications of SA571NG

Available stocks

Related parts for SA571NG