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Technical Description

TUNING MECHANISM AND DIAL D R I V E

In the MX 113, the unique design and careful manufac-

ture of the mechanical assembly gives smooth flywheel
tuning.

By controlling the relationship of mass and mechanical

resistance, and by dividing the workloads in the dial drive

system, it becomes nearly impossible to detect any backlash.

Yet, the entire dial drive is a model of mechanical stability.

For added ease and increased tuning accuracy, a section

of the dial pointer is illuminated.

FM SECTION

The Radio Frequency (RF) section houses the complete

FM-RF front-end and part of the AM RF circuit.

A seven-section variable capacitor is the heart of the RF

section. Four sections of the variable capacitor are in the
FM front end and the remaining three are in the AM section.
By interleaving the sections (AM-FM-AM-FM-etc.) spurious
responses are significantly reduced. The four FM sections

of the variable tuning capacitor provides a high degree of

RF selectivity and excellent spurious rejection. Using the
latest "state of the art" field effect transistors with a well-
designed variable tuning capacitor has provided the

MX 113 with an excellent RF front-end.

A dual insulated gate metal oxide silicon field effect

transistor (MOS-FET) is used as first and second RF ampli-

fier. Each gate of the transistor is internally protected by

back-to-back diodes against incoming transients that may

occur due to severe external conditions. Use of MOS-FET's

greatly reduces the cross-modulation products over a

wider dynamic range. A wider dynamic range permits the

input circuits to accept extremely strong signals without

overload. Since both RF amplifiers have insulated gate
configurations, external neutralization is not required.

This design results in a very stable RF amplifier circuit.

Low temperature coefficient components for the FM local

oscillator prevent frequency drift. The frequency stability

inherent in the local oscillator makes automatic frequency

control (AFC) unnecessary. The rate of drift of the local
oscillator is less than ten parts per million per degree
centrigrade.

The mixer design uses a JFET for high sensitivity and

freedom from overload. The mixer delivers the composite

FM signal at the 10.7 MHz intermediate frequency. The

path of the IF signal is controlled by the front panel

SELECTivity pushbutton.

At the OUT position, the SELECTivity switch directs the

signal through an IF preamplifier stage, that uses a J-FET
and a double-tuned IF transformer. The signal then goes to
the FM-IF and discriminator module for further amplifica-

tion. Activating the SELECTivity pushbutton routes the

signal to two double-tuned transformers, a ceramic filter

network, and a single-gate MOS-FET. The sides of the IF
curve are compressed by this circuit narrowing the IF band-
pass. In this mode of operation weak stations adjacent to

strong stations can be tuned with surprising clarity.

All of the RF circuits, including the selectivity circuit

and the AM sections of the variable capacitor are encased

in a metal module. Each FM-RF section is isolated in a

separate compartment by metal shielding. Careful design
and manufacturing increase the protection against radiation

and interference. The MX 113 exceeds the FCC require-

ments for suppression of local oscillator radiation.

Antenna connections for either 300 ohm twin lead trans-

mission line or 75 ohm coaxial cable are provided on the
back panel of the MX 113. The normal input impedance of

the RF amplifier is 75 ohms. Impedance match to 300 ohms

is provided by a Mclntosh designed, negligible loss, balun

transformer. Connections for both 300 ohm twin lead and

75 ohm coaxial cable are made with push type terminals.

FM-IF AND DISCRIMINATOR SECTION

The MX 113 uses linear-phase IF filters. Each filter was

designed from a FORTRAN computer program for minimum-

phase and constant delay. The mathematical complexity of

the filter design procedure is almost beyond belief. Using

numerical integration in the S-Plane, an "IBM" 1130 high

speed computer spent eighteen minutes on the mathematics
for the design of the IF filter. It would have taken a human

engineer, working twenty-four hours a day, seven days a
week, and working error-free three-hundred years to per-

form the same mathematical calculations!

The IF filter has equal time delay in its pass band region.

Any error in time delay causes FM distortion. All other IF
filters have delay distortion, some as much as 100% of
the 10.7 MHz transit delay. The MX 113 has less than 1.0%
delay distortion from antenna input to discriminator output!

This makes possible the overall low distortion performance

limit for the FM tuner and multiplex section of the MX 113.

Amplification of the intermediate frequency signal is

provided by two high gain integrated circuits, each contain-

ing 16 transistors, 3 zener diodes, 5 diodes, and 23 re-

sistors, all on a signal monolithic silicon chip. The excep-

tionally high gain of the integrated circuit assures "hard

limiting" at very low levels of input signals.

Paralleling the main signal path through the FM-IF and

detector module, a secondary amplifying and de-modulat-

ing process is used to activate the tuning meter and to pro-
vide testpoint TP1 and TP2 with a signal to be used with

the Mclntosh Maximum Performance Indicator.