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Theory of Operation—492/492P Service Vol. 1 (SN B030000 & up)

the amount of negative feedback decreases.  Each diode in
the  array  is  biased  to  conduct  at  successive  amplitude
points,  until  all  are  conducting.  As  each  diode  conducts,

more current is drawn from the feedback loop which in
creases the gain of the amplifier. The resultant output volt
age is a non-linear function of the input of the +15 to

+40 V range. This voltage is applied to the varactor diode

port (Vv) to tune and sweep the oscillator.

Cavity Oscillator

Refer to the Cavity 2nd LO description in the 2nd Con

verter section.

To circumvent this problem, the outputs of the tandem

DAC units are summed together so that the two units are

overlapped by three bits (that is, the MSB of the low-order

DAC is weighted equally with the third least significant bit,

or 2E-10 bit). The overlap means that the lower DAC will
have sufficient range to monotonically tune the output of the
converter over the entire range of the analyzer, but only if

the proper codes of the lower DAC device can be found.

Now, suppose that the tandem DAC is loaded as follows:

Upper order:

1 0 0 0 0 0 0 0 0 0 0 0

Lower order:

1 1 1 1 1 1 1 1 1 1 1 1 1

CENTER FREQUENCY CONTROL

Refer to the block diagram adjacent to Diagram 39. The

Center Frequency Control circuits form the electrical inter

face between the front-panel controls and the converter

stages in the 492/492P. The circuit receives digital informa

tion and instructions from the microcomputer, and converts
it to a coarse and fine tuning voltage that is applied to the
other elements of the Frequency Control system.

The Center Frequency Control circuits consist of the fol

lowing major blocks:

1) the Digital Control circuit, which buffers

and

decodes the

addresses and other data to control the other circuits;

) the coarse and fine storage registers (latches), which

store the numerical bytes that control the DAC (digital-to-
analog converter) stages;

3) the coarse and fine DAC stages, which convert the digi
tal inputs from the storage registers into analog current and
voltage equivalent values;

4) the coarse and fine track/hold amplifiers, which store the
analog output values during the approximation routine, and

compare the stored value and the approximated value for
the microcomputer;

5) the write-back circuits, which inform the microcomputer

when the stored value and the approximated values are
equal.

Operating Modes

Some explanation of the design principles of the circuit is

required  before  the  operation  of  the  circuit  can  be  dis
cussed. DAC devices are now available that can furnish the
resolution  required  to  tune  the  analyzer  in  small  enough
steps. To achieve the necessary amount of resolution,  two
DAC devices are used in tandem. However, this method can

cause some errors and non-monotonic behavior in the over

all converter circuit.

The contents of the devices are shown overlapped to

illustrate the bit weighting. Now assume that the low-order

device is to be incremented one bit. The MSB of the low-
order device must be moved into the high-order device be
fore the low-order device can be incremented. Thus, the two
must appear as shown below:

High-order:

1 0 0 0 0 0 0 0 0 1 0 0

Low-order:

0 1 1 1 1 1 1 1 1 1 1 1

If the high-order device operated with no overall linearity

inaccuracy, the operation would  now be complete,  and  the
low-order  incrementation  could  occur.  However,  the  DAC
device can vary by one LSB of the correct value;  Fig.  5-27
illustrates  a  graph  of  the  best  and  worst  case  output  in
stances.  Note that even in the worst case, the output  may
move only once every two  or three state changes,  but the

output is always monotonic and within one LSB of the cor
rect value.

Fig. 5-27. DAC variance graph.

REV AUG 1981

5-67