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Thesis: GRAND: finalising

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Eric Teunis de Boone 2023-11-14 12:17:18 +01:00
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documents/thesis/chapters/grand_characterisation.tex
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@ -44,7 +44,8 @@ These inputs are connected to their respective filterchains, leaving a fourth fi
Each filterchain bandpasses the signal between $30\MHz$ and $200\MHz$.
Finally, the signals are digitised by a four channel 14-bit \gls{ADC} sampling at $500\MHz$.
%The input voltage ranges from $-900\mV$ to $+900\mV$.
In our setup, the channels are read out after using one of two internal ``monitoring'' triggers.
In our setup, the channels are read out after one of two internal ``monitoring'' triggers fire.
%The ten-second trigger (TD) is linked to the \gls{1PPS} of the \gls{GNSS} chip.
\\
% timestamp = GPS + local oscillator
@ -89,21 +90,13 @@ The sum of the ``forward'' and ``backward'' time delays gives twice the relative
= (t_\mathrm{forward} + t_\mathrm{backward})/2
= ([\Delta t + t_\mathrm{cable}] + [\Delta t - t_\mathrm{cable}])/2
.
\end{equation}
\\
\end{equation}\\
% setup: signal
We used a signal generator to emit a single sine wave at frequencies $50$--$ 200 \MHz$ at $200\mathrm{\;mVpp}$ (see Figure~\ref{fig:grand:signal}).
Therefore, the time delays have been measured as phase differences.
% Frequencies above 50mhz not true measurement
In our setup, the cable length difference was approximately $3.17-2.01 = 1.06\metre$, resulting in an estimated cable time delay of roughly $5\ns$.
Figure~\ref{fig:channel-delays} shows this is in accordance with the measured delays.
At a frequency of $50\MHz$, the difference between the forward and backward phase differences is thus expected to be approximately half a cycle.
For higher frequencies, the phase differences can not distinguish more than one period.\Todo{rephrase}
However, because it is symmetric for both setups, this does not affect the measurement of the filterchain time delay.\Todo{prove}
We used a signal generator to emit a single sine wave at frequencies from $50\MHz$ to $200\MHz$ at $200\;\mathrm{mVpp}$.
Note that we measured the phases to determine the time delays for each channel.
In Figure~\ref{fig:grand:signal} the time delay between the channels is clearly visible in the measured waveforms as well as in the phase spectrum.
\\
\Todo{only 50MHz}
\begin{figure}% <<< fig:grand:signal
\begin{subfigure}{0.47\textwidth}
\includegraphics[width=\textwidth]{grand/split-cable/waveform_eid1_ch1ch2.pdf}
@ -112,71 +105,105 @@ However, because it is symmetric for both setups, this does not affect the measu
\hfill
\begin{subfigure}{0.47\textwidth}
\includegraphics[width=\textwidth]{grand/split-cable/waveform_eid1_ch1ch2_spectrum.pdf}
\label{fig:split-cable:waveform}
\label{fig:split-cable:waveform:spectra}
\end{subfigure}
\caption{
Waveforms of the sine wave measured in the ``forward'' setup and their spectra near the testing frequency of $50\MHz$..
Waveforms of the sine wave measured in the ``forward'' setup and their spectra around the testing frequency of $50\MHz$..
The sine wave was emitted at $200\;\mathrm{mVpp}$.
}
\label{fig:grand:signal}
\end{figure}% >>>
\begin{figure}% <<< fig:grand:phaseshift
\centering
\includegraphics[width=0.47\textwidth]{grand/split-cable/sine-sweep/ch2ch4fig8-histogram.50.pdf}
\caption{
Histogram of the measured phase shifts in Figure~\ref{fig:grand:phaseshift:measruement}.
}
\label{fig:grand:phaseshift}
\end{figure}% >>>
% Frequencies above 50mhz not true measurement
In our setup, the cable length difference was $3.17-2.01 = 1.06\metre$, resulting in an estimated cable time delay of roughly $5\ns$.
At a frequency of $50\MHz$, the difference between the forward and backward phase differences is thus expected to be approximately half a cycle.
Figures~\ref{fig:grand:phaseshift:measurements} and~\ref{fig:grand:phaseshift} show this is in accordance with the measured delays.
\\
\begin{figure}% <<< fig:grand:phaseshift:measurements
\centering
\begin{subfigure}{0.47\textwidth}
\includegraphics[width=0.47\textwidth]{grand/split-cable/sine-sweep/ch2ch4fig9-measurements.forward.50.pdf}
\includegraphics[width=\textwidth]{grand/split-cable/sine-sweep/ch2ch4fig9-measurements.forward.50.pdf}
\caption{}
\label{fig:grand:phaseshift:measurements:forward}
\end{subfigure}
\hfill
\begin{subfigure}{0.47\textwidth}
\includegraphics[width=0.47\textwidth]{grand/split-cable/sine-sweep/ch2ch4fig9-measurements.backward.50.pdf}
\includegraphics[width=\textwidth]{grand/split-cable/sine-sweep/ch2ch4fig9-measurements.backward.50.pdf}
\caption{}
\label{fig:grand:phaseshift:measurements:backward}
\end{subfigure}
\caption{
The measured phase shifts at $50\MHz$ converted to a time delay.
The measured phase differences between channels 2 and 4 at $50\MHz$ converted to a time delay for the \subref{fig:grand:phaseshift:measurements:forward}~forward and \subref{fig:grand:phaseshift:measurements:backward}~backward setups.
The dashed vertical lines indicate the mean time delay, the errorbar at the bottom indicates the standard deviation of the samples.
Crosses are TD-triggered events, circles are MD-triggered.
The measurements are time-ordered within their trigger type.
}
\label{fig:grand:phaseshift}
\label{fig:grand:phaseshift:measurements}
\end{figure}
%\begin{figure}% <<<<
% \centering
% \begin{subfigure}{0.45\textwidth}
% \includegraphics[width=\textwidth]{grand/split-cable/sine-sweep/ch1ch2fig2-combi-time-delays.pdf}
% \caption{
% Channels 1,2
% }
% \label{fig:channel-delays:1,2}
% \end{subfigure}
% \hfill
% \begin{subfigure}{0.45\textwidth}
% \includegraphics[width=\textwidth]{grand/split-cable/sine-sweep/ch2ch4fig2-combi-time-delays.pdf}
% \caption{
% Channels 2,4
% }
% \label{fig:channel-delays:2,4}
% \end{subfigure}
% \caption{
% Total and Filterchain Time Delays between \subref{fig:channel-delays:1,2} channels 1 and 2, and \subref{fig:channel-delays:2,4} 2 and 4.
% Dark grey vertical lines indicate the maximum measurable time delay per frequency.
% \protect \Todo{
% y-axes,
% larger text
% }
% }
% \label{fig:channel-delays}
%\end{figure}% >>>>
%
%Figure~\ref{fig:channel-delays} shows that in general the relative filterchain time delays are below $0.05\ns$, with exceptional time delays upto $0.2\ns$ between channels 2 and 4.
%\Todo{why}
%
%\Todo{discuss data}
\begin{figure}% <<< fig:grand:phaseshift
\centering
\includegraphics[width=0.47\textwidth]{grand/split-cable/sine-sweep/ch2ch4fig8-histogram.50.pdf}
\caption{
Histogram of the measured phase differences in Figure~\ref{fig:grand:phaseshift:measurements}.
The relative signal chain time delay for the portrayed means is $0.2\ns$.
}
\label{fig:grand:phaseshift}
\end{figure}% >>>
\cleardoublepage
% Conclusion
Figure~\ref{fig:channel-delays} shows the measured total time delays and the resulting signal chain time delays between both channels 1 and 2, and channels 2 and 4.
Apart from two exceptional time delays upto $0.2\ns$, the signal chain time delays are in general below $0.05\ns$.
\\
Note that the reported signal chain time delays must be taken to be indications due to systematic behaviours (see below).
\\
Still, even when taking $0.2\ns$ as the upper limit of any relative signal chain time delay, the electric field at the antenna are reconstructable to a sufficient accuracy to use either the pulsed or sine beacon methods (see Figures~\ref{fig:pulse:snr_time_resolution} and~\ref{fig:sine:snr_time_resolution} for reference) to synchronise an array to enable radio interferometry.
\\
Note that at higher frequencies the phase differences are phase-wrapped due to contention of the used period and the cable time delay.
Because it is symmetric for both setups, this should not affect the measurement of the signal chain time delay at the considered frequencies.
Nevertheless, the result at these frequencies must be interpreted with some caution.
\\
% Discussion
The time delays for both TD- and MD-triggered events in Figure~\ref{fig:grand:phaseshift:measurements} show a systematic behaviour of increasing total time delays for the forward setup.
However, in the backward setup, this is not as noticable.
\\
This skewing of the channel time delays in one of the setups is also found at other frequencies (see Figures~\ref{fig:grand:phaseshift:ch1ch2} and~\ref{fig:grand:phaseshift:ch2ch4}), raising questions on the stability of the setup.
Unfortunately, it is primarily visible in the larger datasets which correspond to measurements over larger timescales.
As the number of these large datasets is limited, further investigation with the current datasets is prohibited.
\\
The skewing might also be an artifact of the short waveforms ($N\sim500\;\mathrm{samples}$) the data acquisition system was able to retrieve at the time of measurement.
Since the data acquisition system is now able to retrieve the maximum size waveforms, this systematic behaviour can be investigated in a further experiment.
\\
\begin{figure}% <<<<
\centering
\begin{subfigure}{0.48\textwidth}
\includegraphics[width=\textwidth]{grand/split-cable/sine-sweep/ch1ch2fig2-combi-time-delays.pdf}
\caption{
Channels 1,2
}
\label{fig:channel-delays:1,2}
\end{subfigure}
\hfill
\begin{subfigure}{0.48\textwidth}
\includegraphics[width=\textwidth]{grand/split-cable/sine-sweep/ch2ch4fig2-combi-time-delays.pdf}
\caption{
Channels 2,4
}
\label{fig:channel-delays:2,4}
\end{subfigure}
\caption{
Total (\textit{upper}) and signal chain (\textit{lower}) time delays between \subref{fig:channel-delays:1,2} channels 1 and 2, and \subref{fig:channel-delays:2,4} 2 and 4.
The dark grey vertical lines in the upper panes indicate the maximum measurable time delays at each frequency.
Due to systematic effects in the measurements, the signal chain time delays depicted here must be taken as indicative of upper limits.
See text for discussion.
}
\label{fig:channel-delays}
\end{figure}% >>>>
% >>>
\end{document}