mirror of
https://gitlab.science.ru.nl/mthesis-edeboone/m.internship-documentation.git
synced 2024-11-16 04:13:31 +01:00
Thesis: Beacon: moved tProp into RadioInter chapter
This commit is contained in:
parent
0e53c270da
commit
53c1b2fe81
1 changed files with 42 additions and 39 deletions
|
@ -56,49 +56,52 @@ Before going in-depth on the synchronisation using either of such beacons, the s
|
|||
% <<<<
|
||||
% time delay
|
||||
An in-band solution for synchronising the detectors is effectively a reversal of the method of interferometry in Section~\ref{sec:interferometry}.
|
||||
The distance between the transmitter $T$ and the antenna $A_i$ incur a time delay $(\tProp)_i$ caused by the finite propagation speed of the radio signal.
|
||||
The distance between the transmitter $T$ and the antenna $A_i$ incur a time delay $(\tProp)_i$ caused by the finite propagation speed of the radio signal (see \eqref{eq:propagation_delay}).
|
||||
\\
|
||||
|
||||
Since the signal is an electromagnetic wave, its instantaneous velocity $v$ depends solely on the refractive index~$n$ of the medium as $v = \frac{c}{n}$.
|
||||
In general, the refractive index of air is dependent on factors such as the pressure and temperature of the air the signal is passing through and the frequencies of the signal.
|
||||
However, in many cases, the refractive index can be taken constant over the trajectory to simplify models.
|
||||
\Todo{continuity}
|
||||
|
||||
%\begin{figure}%<<<
|
||||
% \centering
|
||||
% \begin{subfigure}{0.49\textwidth}%<<<
|
||||
% %\centering
|
||||
% \includegraphics[width=\textwidth,height=\textheight,keepaspectratio]{beacon/antenna_setup_two.pdf}
|
||||
% \caption{
|
||||
% Schematic of two antennas ($A_i$) at different distances from a transmitter ($T$).
|
||||
% Each distance incurs a specific time delay $(\tProp)_i$.
|
||||
% The maximum time delay difference for these antennas is proportional to the baseline distance (green line).
|
||||
% \protect \Todo{use `real' transmitter and radio for schematic}
|
||||
% }
|
||||
% \label{fig:beacon_spatial_setup}
|
||||
% \end{subfigure}%>>>
|
||||
% \begin{subfigure}{0.49\textwidth}%<<<
|
||||
% %\centering
|
||||
% \includegraphics[width=\textwidth]{beacon/auger/1512.02216.figure2.beacon_beat.png}
|
||||
% \caption{
|
||||
% From Ref~\cite{PierreAuger:2015aqe}.
|
||||
% The beacon signal that the \gls{Auger} has employed in \gls{AERA}.
|
||||
% The beating between 4 frequencies gives a total period of $1.1\us$ (indicated by the arrows).
|
||||
% With a synchronisation uncertainty below $100\ns$ from the \gls{GNSS}, it fully resolves the period degeneracy.
|
||||
% \protect \Todo{incorporate into text}
|
||||
% }
|
||||
% \label{fig:beacon:pa}
|
||||
% \end{subfigure}%>>>
|
||||
%\end{figure}%>>>
|
||||
|
||||
As such, the time delay due to the propagation from the transmitter to an antenna can be written as
|
||||
\begin{equation}\label{eq:propagation_delay}% <<<
|
||||
\phantom{,}
|
||||
(\tProp)_i = \frac{ \left|{ \vec{x}_{T} - \vec{x}_{A_i} }\right| }{c} n_\mathrm{eff}
|
||||
,
|
||||
\end{equation}% >>>
|
||||
where $n_\mathrm{eff}$ is the effective refractive index over the trajectory of the signal.
|
||||
\\
|
||||
%Since the signal is an electromagnetic wave, its instantaneous velocity $v$ depends solely on the refractive index~$n$ of the medium as $v = \frac{c}{n}$.
|
||||
%In general, the refractive index of air is dependent on factors such as the pressure and temperature of the air the signal is passing through and the frequencies of the signal.
|
||||
%However, in many cases, the refractive index can be taken constant over the trajectory to simplify models.
|
||||
%
|
||||
%%\begin{figure}%<<<
|
||||
%% \centering
|
||||
%% \begin{subfigure}{0.49\textwidth}%<<<
|
||||
%% %\centering
|
||||
%% \includegraphics[width=\textwidth,height=\textheight,keepaspectratio]{beacon/antenna_setup_two.pdf}
|
||||
%% \caption{
|
||||
%% Schematic of two antennas ($A_i$) at different distances from a transmitter ($T$).
|
||||
%% Each distance incurs a specific time delay $(\tProp)_i$.
|
||||
%% The maximum time delay difference for these antennas is proportional to the baseline distance (green line).
|
||||
%% \protect \Todo{use `real' transmitter and radio for schematic}
|
||||
%% }
|
||||
%% \label{fig:beacon_spatial_setup}
|
||||
%% \end{subfigure}%>>>
|
||||
%% \begin{subfigure}{0.49\textwidth}%<<<
|
||||
%% %\centering
|
||||
%% \includegraphics[width=\textwidth]{beacon/auger/1512.02216.figure2.beacon_beat.png}
|
||||
%% \caption{
|
||||
%% From Ref~\cite{PierreAuger:2015aqe}.
|
||||
%% The beacon signal that the \gls{Auger} has employed in \gls{AERA}.
|
||||
%% The beating between 4 frequencies gives a total period of $1.1\us$ (indicated by the arrows).
|
||||
%% With a synchronisation uncertainty below $100\ns$ from the \gls{GNSS}, it fully resolves the period degeneracy.
|
||||
%% \protect \Todo{incorporate into text}
|
||||
%% }
|
||||
%% \label{fig:beacon:pa}
|
||||
%% \end{subfigure}%>>>
|
||||
%%\end{figure}%>>>
|
||||
%
|
||||
%As such, the time delay due to the propagation from the transmitter to an antenna can be written as
|
||||
%\begin{equation}\label{eq:propagation_delay}% <<<
|
||||
% \phantom{,}
|
||||
% (\tProp)_i = \frac{ \left|{ \vec{x}_{T} - \vec{x}_{A_i} }\right| }{c} n_\mathrm{eff}
|
||||
% ,
|
||||
%\end{equation}% >>>
|
||||
%where $n_\mathrm{eff}$ is the effective refractive index over the trajectory of the signal.
|
||||
%\\
|
||||
|
||||
\Todo{continuity}
|
||||
If the time of emitting the signal at the transmitter $\tTrueEmit$ is known, this allows to directly synchronise the transmitter and an antenna since
|
||||
\begin{equation}\label{eq:transmitter2antenna_t0}%<<<
|
||||
\phantom{,}
|
||||
|
|
Loading…
Reference in a new issue