THAT4301A Datasheet, PDF(7/12 Page) List of Unclassifed Manufacturers – THAT Analog Engine® IC Dynamics Processor

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THAT4301A Datasheet, PDF (7/12 Pages) List of Unclassifed Manufacturers – THAT Analog Engine® IC Dynamics Processor

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THAT 4301 Dynamics Processor IC

Page 7

Theory of Operation

THAT 4301 Dynamics Processor combines THAT

Corporationâs proven Voltage-Controlled Amplifier

(VCA) and RMS-Level Detector designs with three

general-purpose opamps to produce an Analog En-

gine useful in a variety of dynamics processor appli-

cations. For details of the theory of operation of the

VCA and RMS-Detector building blocks, the inter-

ested reader is referred to THAT Corporationâs data

sheets on the 2150 Series VCAs and the 2252

RMS-Level Detector. Theory of the interconnection of

exponentially-controlled VCAs and log-responding

level detectors is covered in THAT Corporationâs ap-

plication note AN101, The Mathematics of

Log-Based Dynamic Processors.

The VCA â in Brief

THAT 4301 VCA is based on THAT Corporationâs

highly successful complementary log-antilog gain cell

topology, as used in THAT 2150-Series IC VCAs, and

the modular 202 Series VCAs. THAT 4301 is inte-

grated using a fully complementary, BiFET process.

The combination of FETs with high-quality, comple-

mentary bipolar transistors (NPNs and PNPs) allows

additional flexibility in the design of the VCA over

previous efforts.

Input signals are currents to the VCA IN pin. This

pin is a virtual ground, so in normal operation an in-

put voltage is converted to input current via an ap-

propriately sized resistor (R1 in Figure 2, Page 4).

Because dc offsets present at the input pin and any

dc offset in preceeding stages will be modulated by

gain changes (thereby becoming audible as thumps),

the input pin is normally ac-coupled (C1 in Figure 2).

The VCA output signal is also a current, inverted

with respect to the input current. In normal opera-

tion, the output current is converted to a voltage via

inverter OA3, where the ratio of the conversion is de-

termined by the feedback resistor (R2, Figure 2) con-

nected between OA3âs output and its inverting input.

The signal path through the VCA and OA3 is

noninverting.

The gain of the VCA is controlled by the voltage

applied to ECâ, EC+, and SYM. Gain (in decibels) is

proportional to EC+ â EC-, provided EC+ and SYM are

at essentially the same voltage (see below). The con-

stant of proportionality is â6.5 mV/dB for the voltage

at ECâ, and 6.5 mV/dB for the voltage at EC+ and SYM.

As mentioned, for proper operation, the same

voltage must be applied to EC+ and SYM, except for a

small (Â±2.5 mV) dc bias applied between these pins.

This bias voltage adjusts for internal mismatches in

the VCA gain cell which would otherwise cause small

differences between the gain of positive and negative

half-cycles of the signal. The voltage is usually ap-

plied via an external trim potentiometer (R5 in Figure

2), which is adjusted for minimum signal distortion

at unity (0 dB) gain.

The VCA may be controlled via EC-, as shown in

Figure 2, or via the combination of EC+ and SYM.

This connection is illustrated in Figure 13. Note that

this figure shows only that portion of the circuitry

needed to drive the positive VCA control port; cir-

cuitry associated with OA1, OA2 and the RMS detector

has been omitted.

Positive Control In

Signal In

47uF 20K0 1%

50K VCA SYM

C2 47pF

300K

20K0 1%

OA1

EC-

VCC THAT4301

VEE

IN RMS OUT

SYM

VCA OUT

EC+

GND

OA3

OA2

Signal

Out

Figure 13. Driving the VCA via the Positive Control Port

While the 4301âs VCA circuitry is very similar to

that of the THAT 2150 Series VCAs, there are several

important differences, as follows:

1) Supply current for the VCA is fixed internally.

Approximately 2mA is available for the sum of input

and output signal currents. (This is also the case in a

2150 Series VCA when biased as recommended.)

2) The signal current output of the VCA is inter-

nally connected to the inverting input of an on-chip

opamp. In order to provide external feedback around

this opamp, this node is brought out to a pin.

3) The control-voltage constant is approximately

6.5 mV/dB, due primarily to the higher internal oper-

ating temperature of the 4301 compared to that of

the 2150 Series.

4) The input stage of the 4301 VCA uses inte-

grated P-channel FETs rather than a bias-current

corrected bipolar differential amplifier. Input bias

currents have therefore been reduced.

The RMS Detector â in Brief

The 4301âs detector computes rms level by recti-

fying input current signals, converting the rectified

current to a logarithmic voltage, and applying that

voltage to a log-domain filter. The output signal is a

dc voltage proportional to the decibel-level of the rms

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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