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Common Measurement Settings
R&S
®
FSW
405
User Manual 1173.9411.02 ─ 19
automatically adjusted. The automatic coupling adapts the resolution bandwidth to the
currently set frequency span/100.
The 6 dB bandwidths 200 Hz, 9 kHz and 120 kHz and the available channel filters are
not changed by the coupling.
With a span/RBW ratio of 100 and a screen resolution of 1000 pixels, each frequency
in the spectrum is displayed by 10 pixels. A span/RBW ratio of 1000 provides the high-
est resolution.
A higher span/RBW ratio (i.e. low RBW values and large frequency spans), however,
results in large amounts of data.
6.5.1.5
How Data is Measured: the Sweep Type
In a standard analog
frequency sweep
, the local oscillator of the analyzer sweeps the
applied signal quasi analog from the start to the stop frequency to determine the fre-
quency spectrum.
Alternatively, the analyzer can sample signal levels over time at a defined frequency
and transform the data to a spectrum by Fast Fourier Transformation (
FFT
). Although
this measurement method requires additional calculations, it can provide results much
faster than the frequency sweep, in particular for small RBWs.
Which sweep mode is appropriate for the current measurement depends on the span,
RBW, VBW and sweep time settings. By default ("Auto" sweep type), the R&S
FSW
automatically uses the sweep type with the highest sweep rate depending on these
measurement settings.
Restrictions for FFT mode
FFT mode is not available when using 5-Pole filters, Channel filters or RRC filters, or
the Quasi peak detector. In this case, sweep mode is used.
The same applies when an external generator (option R&S
FSW-B10) is active.
Optimization
In FFT mode, FFT analysis is performed to determine a spectrum of frequencies. Sev-
eral analysis steps are required to cover the entire span. The partial span which is cov-
ered by one FFT analysis depends on the RBW. The partial span cannot be defined
directly, but it can be optimized according to measurement requirements.
Narrow partial spans provide a higher dynamic range, and also allow you to perform
measurements near a carrier with a reduced reference level. With a wide partial span,
the carrier and the useful signal are likely to be measured at the same time, in which
case the powers of both signals are summarized, so the reference level must be high
enough to consider this factor. With a narrow partial span, this is less likely to happen,
so the reference level can be reduced.
For an optimal dynamic range
, the narrowest possible partial span (depending on
the RBW) is used. Furthermore, the autorange function for the internal IF gain calcula-
tion is activated to obtain the best control range of the A/D converter.
Bandwidth, Filter and Sweep Configuration