This document compares two techniques for large-signal network analysis - a sampler-based front-end and a mixer-based front-end. The sampler-based approach converts broadband signals to low frequencies simultaneously, allowing fast measurement but with lower dynamic range due to noise. The mixer-based method measures single frequencies, providing high dynamic range but slower measurement. Both can characterize nonlinear behavior in continuous wave and modulation modes.
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Sampling vs Mixer LSNA Front-Ends
1. Sampling-based
versus
Mixer-based
front-end
This slide set introduces the two common measurement techniques for
large-signal network analysis technology and discusses in details the pros
and cons of each technique.
1
2. Outline
LSNA based on Sampler-based Front-end
• Front-end
• Harmonic Sampling – Theory of Operation
Continuous Wave
Narrowband Modulation
Broadband Modulation
LSNA based on Mixer-based Front-end
• Front-end
• Theory of Operation
Conclusions
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2
3. LSNA: Sampler Front-end
Acquisition System
10 MHz Synchronisation
LO
Downconverter
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The broadband acquisition system consists of a sampler front-end in
combination with a low-frequency (intermediate frequency or IF) data
acquisition system.
The sampler front-end compresses broadband signals into a low-frequency
version, which then can be digitized and processed.
When dealing with large signals, additional signal conditioning is required to
keep the power incident to the samplers low enough to avoid sampler
compression. This can be realized using step attenuators.
Because of the compression of a large HF band into a limited IF band, the
signals cannot have a continuous spectrum. After sampling, it must be
possible to reconstruct the original signal and as such no overlap of spectral
content may happen during compression.
3
4. Harmonic Sampling - Signal Class: Continuous Wave
fLO=24.975 MHz = (1GHz-1MHz)/40
1 MHz
RF
2 MHz
40 fLO 80 fLO 120 fLO 3 MHz
Freq. (GHz)
1 2 3
IF Bandwidth
IF
1 2 3 10 Freq. (MHz)
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Here, the harmonic sampling process is explained in more details. Suppose
one wants to acquire a signal consisting of a fundamental at 1 GHz and
containing 3 harmonics using a data acquisition with an IF bandwidth of 10
MHz.
If one uses a sampler driven at 25 MHz, one will sample the signal
(repetition rate of 1 ns) each 40 ns, corresponding to the repeated sampling
(once each 40 periods) of the same value. As a result the output will be DC.
If we now de-synchronise the sample rate, by changing it to a frequency
lower than 25 MHz, suddenly a beating signal becomes available at the
output of the sampler that can be digitized.
If we select a sample frequency of 24.975 MHz, the 1 GHz component will
result into a 1 MHz component because the 40th spectral component of the
applied sample frequency is 1 MHz away of 1 GHz. The second harmonic
will be brought down to 2 MHz because the sampling signal has a spectral
component which is 2 MHz away from 2 GHz, etc ….
4
5. Harmonic Sampling - Signal Class: Narrowband Modulation
fLO=24.975 MHz = (1GHz-1MHz)/40
1 MHz
RF
2 MHz
40 fLO 80 fLO 120 fLO 3 MHz
Freq. (GHz)
1 2 3
IF
1 2 3
Freq. (MHz)
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Suppose now that the 1 GHz tone (and harmonics) is slowly modulated.
This results in skirts in the IF domain. As long as the skirts are limited (or
the modulation is mild) the signal can be detected properly (even using a
one-shot data-acquisition). When the modulation becomes broader, at a
certain moment the skirts will overlap and the original signal cannot be
reconstructed. The allowed modulation bandwidth depends on the IF
bandwidth and the number of harmonics of interest.
It is also important to notice that in “narrowband modulation”, the spacing of
the modulation frequencies at IF equals that of the spacing at RF.
5
6. Harmonic Sampling - Signal Class: Broadband Modulation
2BW
BW Adapted sampling process
RF
40 fLO 80 fLO 120 fLO
1 2 3 Freq. (GHz)
IF
Freq. (MHz)
BW of Periodic Broadband Modulation = 2* BW IF data acquisition
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When the modulation is periodic the modulation spectrum is not continuous
but discrete. At that moment, with some intelligent selections of the
sampling frequency, it is possible to fold the spectrum around each
harmonic together into a bandwidth, which is only half of the modulation
bandwidth.
As such the maximum modulation bandwidth in “broadband modulation”
mode is twice the IF bandwidth.
6
7. LSNA: Mixer Front-End
Network Analyser
1 + df GHz
Mixer Front-end
...
df GHz 5 + df GHz df GHz
...
1 GHz 1 GHz
20 + df GHz
LO
Test Set
Input 1 Port 1 Port 2 Input 2 Ref Channel
DUT Synchroniser
5 GHz 5 GHz
“Fixed Phase Relationship”
1 … 20 GHz 1 … 20 GHz
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Nowadays a Vector Network Analyser uses typically four receivers to
capture the incident and reflected waves at each port of the device under
test (DUT), using mixers to convert the HF spectral components to a fixed
intermediate frequency (IF), with the help of a local oscillator (LO).
As only one frequency is measured at a time, the phase relationship
between each measured spectral component is lost. To properly reconstruct
the signal at the DUT ports in nonlinear regime, one needs a phase
reference in the measurement system. This is the purpose of the
synchroniser.
The synchroniser is a very stable periodic pulse generator that generates a
comb of harmonic related spectral components in frequency domain.
Thanks to its stability, the phase relationship between each harmonic stays
fixed.
The output of the synchroniser is then captured using a fifth receiver...
7
8. Theory of Operation
nf0+df mf0+df
1
Synchroniser
reference 2
receiver
f nf0 mf0 VNA nf0 mf0
0
f0
DUT receiver
4 3
f nf0 mf0 VNA nf0 mf0
0
phase consistency between harmonics in phase consistency between receivers
by simultaneous measurement
1 2 3 one frequency at the time
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Now, suppose one wants to acquire a signal at the DUT consisting of a
fundamental at f0 and containing m harmonics using a mixer-based front-
end.
The synchroniser is then excited with a continuous wave signal at f0: its
output will generate a comb of harmonic-related spectral components with
the same frequency grid than the DUT signals.
Assuming that all the receivers are capturing simultaneously the same
harmonic of all the signals at the device under test and of the synchroniser,
then the phase of this harmonic of the DUT signals can be referenced to the
phase of the harmonic of the synchroniser. The phase relationship between
the harmonics of the synchroniser is fix. As such the phase between the
harmonics of the DUT signals is being fixed.
At the end, one obtains a stable phase – coherent signals at the device
under test. One should notice that a phase calibration is still required to
properly reconstruct the phase relationship between each harmonic.
8
9. Pros and Cons
Sampler Front-end:
• Advantage: very broadband phase-coherent measurement, it
converts all spectral contents into a low-frequency version at
once
Fast phase-coherent measurement
All spectral content of a signal is captured
Relatively easy to range signal for optimal sampler operation
CW and dense modulation signals
• Disadvantage: any noise and spurious within the measurement
bandwidth is measured too.
Lower dynamic range.
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The advantage of a sampler is that it converts all spectral contents into a
low-frequency version simultaneously. Because all spectral content is
downconverted, one can observe device behaviour like oscillation. Also it is
easy to detect overranging which is important to keep the sampler in its
linear domain of operation.
The disadvantage is that it converts at the same time any noise and
spurious within the measurement bandwidth. This reduces the dynamic
range of the system.
9
10. Pros and Cons (continued)
Mixer Front-end:
• Advantage: narrowband measurement, optimized around each
frequency
High dynamic range
CW and modulation signals, limited by synchroniser
• Disadvantage: only one spectral component measured at a time
Slower measurement, dependent on number of spectral
components to measure
Requires reference signal with similar spectral content as signal
to measure
Reference signal, mixers, LO may not drift during measurement
Only specified spectral components are measured, e.g.
oscillation cannot be observed
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At the other hand, the advantage of a mixer-based front-end is its
narrowband measurement principle that allows high dynamic range.
The main disadvantage is that only one frequency is measured at a time
which slows down the measurement speed. This can be important when
many tones need to be measured under periodic modulation conditions.
Also it is important that mixers, local oscillator, synchroniser stay very stable
during a measurement sweep to correctly reconstruct the signals.
10
11. Conclusions
Large-signal network analysis provides a uniform way to
characterise the input - output behaviour of nonlinear HF
components under almost realistic conditions
Two common measurement system exist:
• The LSNA sampler-based system allows fast characterisation of
nonlinear behaviour both in continuous wave and dense modulation
modes. However, the dynamic range suffers from the use of a
broadband measurement technique.
• The LSNA mixer-based system allows to characterise nonlinear
behaviour both in continuous wave and modulation modes, on a
specified frequency grid. While the dynamic range benefits from this
narrowband measurement technique, the system can only measure
one spectral component at a time, resulting in lower measurement
speed and possibly missing information.
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