SA572N ON Semiconductor, SA572N Datasheet - Page 5

SA572N

Manufacturer Part Number

SA572N

Description

IC COMPANDOR 2CHAN GAIN 16-DIP

Manufacturer

ON Semiconductor

Type

Compandorr

Datasheets

1.SA572N.pdf (12 pages)

2.SA572N.pdf (12 pages)

Specifications of SA572N

Applications

Automatic Level Control, Stereo Expander

Mounting Type

Through Hole

Package / Case

16-DIP (0.300", 7.62mm)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

H&T Electronics

Part Number:

SA572N

Quantity:

216

Company:

Meier Automation Equipment Co., Limited

Part Number:

SA572NG

Manufacturer:

ON/安森美

Quantity:

20 000

Current page: 5 of 12
Download datasheet (137Kb)

Philips Semiconductors

SA572 BASIC APPLICATIONS

Description

The SA572 consists of two linearized, temperature-compensated

gain cells ( G), each with a full-wave rectifier and a buffer amplifier

as shown in the block diagram. The two channels share a 2.5V

common bias reference derived from the power supply but otherwise

operate independently. Because of inherent low distortion, low noise

and the capability to linearize large signals, a wide dynamic range

can be obtained. The buffer amplifiers are provided to permit control

of attack time and recovery time independent of each other.

Partitioned as shown in the block diagram, the IC allows flexibility in

the design of system levels that optimize DC shift, ripple distortion,

tracking accuracy and noise floor for a wide range of application

requirements.

Gain Cell

Figure 4 shows the circuit configuration of the gain cell. Bases of the

differential pairs Q

inputs of OPA A

of Q

be derived from the transistor model equation in the forward active

region.

where I

1998 Nov 03

Programmable analog compandor

-Q

= V

Q3Q4

and the V

= 140 A

= 280 A

= 6.8k

IC/IS)

. The negative feedback through Q

Q1Q2

-Q

of Q

and Q

-Q

equal. The following relationship can

are both tied to the output and

Figure 4. Basic Gain Cell Schematic

holds the V

TRIM

THD

REF

where I

control current of the gain cell.

If all transistors Q

can be simplified to:

The first term of Equation 3 shows the multiplier relationship of a

linearized two quadrant transconductance amplifier. The second

term is the gain control feedthrough due to the mismatch of devices.

In the design, this has been minimized by large matched devices

and careful layout. Offset voltage is caused by the device mismatch

and it leads to even harmonic distortion. The offset voltage can be

trimmed out by feeding a current source within 25 A into the THD

trim pin.

The residual distortion is third harmonic distortion and is caused by

gain control ripple. In a compandor system, available control of fast

attack and slow recovery improve ripple distortion significantly. At

the unity gain level of 100mV, the gain cell gives THD (total harmonic

distortion) of 0.17% typ. Output noise with no input signals is only

6 V in the audio spectrum (10Hz-20kHz). The output current I

must feed the virtual ground input of an operational amplifier with a

resistor from output to inverting input. The non-inverting input of the

operational amplifier has to be biased at V

–

is the differential output current of the gain cell and I

is DC coupled.

140 A

6.8k

= 140 A

= 280 A

= 6.8k

V+

through Q

280 A

are of the same size, equation (2)

SR00697

REF

(2)

if the output current

Product specification

(3)

SA572

is the gain

SA572N ON Semiconductor, SA572N Datasheet - Page 5

SA572N

Specifications of SA572N

Available stocks

Related parts for SA572N