Theory of Operation—492/492P Service Vol. 1 (SN B030000 & up)
Table 5-6
PROGRESSION OF GAIN REDUCTION
Input
Level
Point
1
Point
2
Point
3
Point
4
Beyond Logging Range
X -1 0 dB
0.00316
0.01
0.316
0.1-
-----
—
-0.216
X Level
0.01
0.316
0.1
0.316-
-0.684
X+10 dB
0.0316
0.1
0.316
1.0^
-0.684 —
...
~1
-0.684
X + 20 dB
0.1
0.316
1.0
1.684
η
-0.684-----
I I
-0.684—
Ί
-0.684
X + 30 dB
0.316
1.0
1.684
2.368 d
I---- 0.684
........I r
-0.684-----
I I
' -0.684 —
----
1
-0.684
X + 40 dB
1.0
1.684
2.368
3.052 J
X + 50 dB
3.16
Beyond Logging Range
Switching in the other, non-selected filter sections, is ac
complished as described in the 1st Filter Select circuit para
graphs. Also as described in those paragraphs, the design
of the filter for each bandwidth is determined by the require
ments for each band and ranges from no filter at all to a
complex two crystal arrangement. An important design dif
ference is that the 2nd Filter Select circuit contains a vari
able resistor in the attenuator that follows the input switch
in all except the 100 kHz circuit. The purpose of this adjust
ment is to allow calibration of all other circuits to match the
100 kHz circuit. The Band Leveling circuit furnishes com
pensation gain to obtain equal signal levels for all bands.
Thus, the calibration is required only to remove variations
between the filters by adjustments R1065, R3035, R3025,
and R3015.
It is in the 1 MHz section that no filter is used. This is
because this circuit section is preceded by the 1 MHz (wide)
filter between the 2nd and 3rd Converters and the 1.2 MHz
filter in the VR Input circuit. Those filters accomplish the
required function. Thus, instead of a filter, an attenuator that
includes the calibration adjustment is contained in the
1 MHz selection circuit. This attenuator compensates (off
sets) the gain loss associated with a filter in the other reso
lution circuits.
The 100 kHz filter is a double-tuned LC circuit that is
designed for a good time-domain response shape. Variable
capacitors C2050 and C5055 provide for filter tuning. A
6 dB attenuator (resistors R2048, R2047, and R2049) is in
cluded at the filter input. This attenuator and the filter form a
reference to which the levels of the other circuits are cali
brated. Impedance matching is accomplished at both input
and output by series capacitors C1047 and C6052.
The 10 kHz filter uses a two-pole monolithic crystal filter.
The impedances at the input and output are matched to
50 Ω by T4040 and T6045. An attenuator that contains the
calibration adjustment is included at the filter input for filter
variation compensation.
The 1 kHz filter also uses a two-pole monolithic crystal
filter with impedance matching transformers T5030 and
T6040 at the input and output. An attenuator that contains
the calibration adjustment is included at the filter input for
filter variation compensation.
The 100 Hz filter uses a pair of high-Q crystals in a bal
anced two-pole ladder configuration. These crystals are
matched for both frequency and temperature characteris
tics. Input and output impedance matching is accomplished
primarily by transformers T4019 and T7015. Two small ca
pacitors in the same transformer circuit as the crystals
(C6011 and C7011) are adjustable to cancel the parallel ca
pacitance effect of the crystals. An attenuator that contains
the calibration adjustment is included at the filter input for
filter variation compensation.
Post VR Amplifier Circuit \2 C /
The Post VR Amplifier circuit provides the final VR sys
tem gain to bring the signal to the required output level and
provides the final bandpass filtering to assure clean perfor
mance. The circuit consists of two stages of gain followed
by a filter.
From the 2nd Filter Select circuit, the signal is applied
through jumper JJ to the input of common emitter amplifier
REV FEB 1983
5-27
