THAT4305 Datasheet, PDF(6/20 Page) List of Unclassifed Manufacturers

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THAT4305 Datasheet, PDF (6/20 Pages) List of Unclassifed Manufacturers – Pre-trimmed Analog Engine® IC

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Page 6

THAT4305 Pre-trimmed Analog Engineï£¨

sion ratios, while limiters have high ratios. In such

applications, the signal path has static gain so long

as the input signal remains below some threshold,

but gain is reduced when the signal rises above the

threshold. Compression ratio is defined as the num-

ber of dB the input signal increases for a 1 dB in-

crease in output signal.

Feedforward Topologies

To make a compressor or limiter with a 4305,

typically, the input signal is applied to both the VCA

and the RMS detector. The RMS output signal is fed

forward to the VCA's negative control port (EC-) via a

dc-coupled op-amp based stage. This stage has gain

above some dc level (the threshold), and no trans-

mission below that level. This path, called the

"sidechain," â from detector output to VCA control

port â determines the compression behavior of the

circuit. As signal level rises, the dc voltage at the

RMS' output rises. Once the dc level exceeds the

threshold, the rms output signal is transmitted

through the sidechain and presented to the VCA con-

trol port, lowering the gain to signals passing

through the VCA. As a result, the output signal level

is reduced, or compressed, relative to rising input

signal levels.

Varying the threshold setting of the sidechain will

vary the point at which compression begins. Varying

the gain between the RMS output and the VCA con-

trol input varies the compression ratio.

Feedforward compressor topologies are espe-

cially versatile because they cannot become unstable

due to oscillation in the control loop. Unity gain in

the sidechain produces infinite compression (where

the output remains constant regardless of increases

in the input signal). With feedforward, negative com-

pression ratios are easily achievable. (Negative com-

pression occurs when the output signal decreases

as the input signal increases.) This approximates the

effect of playing music backwards, since the attack

is suppressed and the release is increased in vol-

ume.

Many other variations of the feedforward concept

are possible. These include implementing more than

one threshold, different ratios, additional time con-

stants, ac-coupling of some (or all) of the detector

output signal, and many more. See AN101A, The

Mathematics of Log-Based Dynamic Processors, for

more details of how the sidechain gain determines

compression ratios.

Feedback Topologies

An alternative configuration for compressor/lim-

iter design is to feed the output signal into the RMS

detector. The RMS output is fed back (dc coupled)

to the VCA's negative control port to reduce signal

levels. Similarly as with a feedforward designs, a

threshold in the sidechain serves to stop the com-

pression action at low signal levels.

The feedback topology behaves somewhat differ-

ently from feedforward. First, reaching infinite com-

pression requires infinite gain in the feedback loop

from RMS output to VCA control port. Of course, in-

finite gain is impossible, so practical feedback com-

pressors are usually limited to ratios no greater than

20 or so. Additionally, the gain in the feedback loop

alters the effective time constant of the detector,

shortening the attack as the ratio becomes higher.

This may or may not be appropriate, depending on

the desired effect.

Expander (Gate) Configurations

By changing the sign of the sidechain in a

feedforward compressor, it is possible to arrange

signal gain to decrease along with signal level, thus

producing an expander. This is typically applied

below a threshold (so, the threshold detectorâs po-

larity is reversed from that of a compressor) to re-

duce noise or crosstalk during pauses in program

material. This technique has long been used for

"cleaning up" individual drum tracks to reduce re-

verberation, interference from microphones picking

up adjacent drum sounds, and alter the attack/decay

characteristic of individual drum sounds.

Practical gates usually require very fast attack

times, and carefully programmable release times. In

a 4305, this is best accomplished by using the RMS

detector as a log rectifier with very short time con-

stants, and following the detector output with a

time-constant stage that applies the desired attack

and release behavior. This alters the 4305 detectorâs

natural response characteristics to peak, rather than

rms, time constants. We intend to produce an appli-

cation note showing examples of these circuits. Un-

til that is available, see DN 100, which shows a noise

gate application using THAT's 4301 Analog Engine.

THAT Corporation; 45 Sumner Street; Milford, Massachusetts 01757-1656; USA

Tel: +1 508 478 9200; Fax: +1 508 478 0990; Web: www.thatcorp.com

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