Specifications
47
Custom signal processing IC
Turning back to the block diagram of the digital IF (Figure 3-2), after the
ADC gain has been set with analog gain and corrected with digital gain, a
custom IC begins processing the samples. First, it splits the 30 MHz IF samples
into I and Q pairs at half the rate (15 Mpairs/s). The I and Q pairs are given
a high-frequency boost with a single-stage digital filter that has gain and
phase approximately opposite to that of the single pole analog prefilter. Next,
I and Q signals are low-pass filtered with a linear-phase filter with nearly
ideal Gaussian response. Gaussian filters have always been used for swept
spectrum analysis, because of their optimum compromise between frequency
domain performance (shape factor) and time-domain performance (response
to rapid sweeps). With the signal bandwidth now reduced, the I and Q pairs may
be decimated and sent to the processor for FFT processing or demodulation.
Although FFTs can be performed to cover a segment of frequency span up to
the 10 MHz bandwidth of the anti-alias filter, even a narrower FFT span, such
as 1 kHz, with a narrow RBW, such as 1 Hz, would require FFTs with 20 million
data points. Using decimation for narrower spans, the number of data points
needed to compute the FFT is greatly reduced, speeding up computations.
For swept analysis, the filtered I and Q pairs are converted to magnitude
and phase pairs. For traditional swept analysis, the magnitude signal is
video-bandwidth (VBW) filtered and samples are taken through the display
detector circuit. The log/linear display selection and dB/division scaling
occur in the processor, so that a trace may be displayed on any scale
without remeasuring.
Additional video processing features
The VBW filter normally smoothes the log of the magnitude of the signal,
but it has many additional features. It can convert the log magnitude to a
voltage envelope before filtering, and convert it back for consistent behavior
before display detection.
Filtering the magnitude on a linear voltage scale is desirable for observing
pulsed-RF envelope shapes in zero span. The log-magnitude signal can also
be converted to a power (magnitude squared) signal before filtering, and
then converted back. Filtering the power allows the analyzer to give the
same average response to signals with noise-like characteristics, such as
digital communications signals, as to CW signals with the same rms voltage.
An increasingly common measurement need is total power in a channel or
across a frequency range. In such a measurement, the display points might
represent the average power during the time the LO sweeps through that
point. The VBW filter can be reconfigured into an accumulator to perform
averaging on either a log, voltage or power scale.
Frequency counting
Swept spectrum analyzers usually have a frequency counter. This counter
counts the zero crossings in the IF signal and offsets that count by the known
frequency offsets from LOs in the rest of the conversion chain. If the count
is allowed to run for a second, a resolution of 1 Hz is achievable.
Because of its digitally synthesized LOs and all-digital RBWs, the native
frequency accuracy of the PSA Series analyzer is very good (0.1% of span).
In addition, the PSA analyzer includes a frequency counter that observes
not just zero crossings, but also the change in phase. Thus, it can resolve
frequency to the tens of millihertz level in 0.1 second. With this design, the
ability to resolve frequency changes is not limited by the spectrum analyzer,
but rather is determined by the noisiness of the signal being counted.