Specifications

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More advantages of the all-digital IF
We have already discussed a number of features in the PSA Series: power/
voltage/log video filtering, high-resolution frequency counting, log/linear
switching of stored traces, excellent shape factors, an average-across-the
display-point detector mode, 160 RBWs, and of course, FFT or swept
processing. In spectrum analysis, the filtering action of RBW filters causes
errors in frequency and amplitude measurements that are a function of the
sweep rate. For a fixed level of these errors, the all-digital IF’s linear phase
RBW filters allow faster sweep rates than do analog filters. The digital
implementation also allows well-known compensations to frequency and
amplitude readout, permitting sweep rates typically twice as fast as older
analyzers, and excellent performance at even four times the sweep speed.
The digitally implemented logarithmic amplification is very accurate.
Typical errors of the entire analyzer are much smaller than the measurement
uncertainty with which the manufacturer proves the log fidelity. The log
fidelity is specified at ±0.07 dB for any level up to –20 dBm at the input mixer
of the analyzer. The range of the log amp does not limit the log fidelity at low
levels, as it would be in an analog IF; the range is only limited by noise around
–155 dBm at the input mixer. Because of single-tone compression in upstream
circuits at higher powers, the fidelity specification degrades to ±0.13 dB for
signal levels up to –10 dBm at the input mixer. By comparison, analog log
amps are usually specified with tolerances in the ±1 dB region.
Other IF-related accuracies are improved as well. The IF prefilter is analog
and must be aligned like an analog filter, so it is subject to alignment errors.
But it is much better than most analog filters. With only one stage to
manufacture, that stage can be made much more stable than the 4- and
5-stage filters of analog IF-based spectrum analyzers. As a result, the gain
variations between RBW filters is held to a specification of ±0.03 dB, ten
times better than all-analog designs.
The accuracy of the IF bandwidth is determined by settability limitations in
the digital part of the filtering and calibration uncertainties in the analog
prefilter. Again, the prefilter is highly stable and contributes only 20 percent
of the error that would exist with an RBW made of five such stages. As a
result, most RBWs are within 2 percent of their stated bandwidth, compared
to 10 to 20 percent specifications in analog-IF analyzers.
The most important purpose of bandwidth accuracy is minimizing the
inaccuracy of channel power and similar measurements. The noise bandwidth
of the RBW filters is known to much better specifications than the 2 percent
setting tolerance, and noise markers and channel-power measurements are
corrected to a tolerance of ±0.5 percent. Therefore, bandwidth uncertainties
contribute only ±0.022 dB to the amplitude error of noise density and
channel-power measurements.
Finally, with no analog reference-level-dependent gain stages, there is no
“IF gain” error at all. The sum of all these improvements means that the
all-digital IF makes a quantum improvement in spectrum analyzer accuracy.
It also allows you to change analyzer settings without significantly impacting
measurement uncertainty. We will cover this topic in more detail in the
next chapter.