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Thesis: Introduction: Random Writes
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%<<<
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%<<<
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% Intro Cosmic Ray
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% Intro Cosmic Ray
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In the beginning of the $\mathrm{20^{th}}$~century, various types of radiation were discovered.
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In the beginning of the $\mathrm{20^{th}}$~century, various types of radiation were discovered.
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With the balloonflight of Victor Hess \Todo{ref} in \Todo{year}, one type was determined to come from beyond the atmosphere and named ``Cosmic Rays''.
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With the balloonflight of Victor Hess \Todo{ref} in 1912, one type was determined to come from beyond the atmosphere and therefore labelled ``Cosmic Rays''.
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With many discoveries following, the field of (astro-)particle physics evolved.
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With many discoveries following, the field of (astro-)particle physics evolved.
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\\
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\\
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% Current state, (nudge to radio)
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% Current state, (nudge to radio)
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Large collaborations are now detecting cosmic rays with a variety of methods over a large range of energy\Todo{ref figure}.
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Large collaborations are now detecting cosmic rays with a variety of methods over a large range of energy (see Figure~\ref{fig:cr_flux}).
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Still, questions on their origin remain.\Todo{list questions or remove}
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Still, questions on their origin remain.\Todo{list questions or remove}
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% Radio
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% Radio
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In the last decade, the detection using radio antennas has received significant attention \Todo{ref}, such that collaborations such as \gls{GRAND} are building observatoria that fully rely on radio measurements.
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In the last decade, the detection using radio antennas has received significant attention \Todo{ref}, such that collaborations such as \gls{GRAND} are building observatoria that fully rely on radio measurements.
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%
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For such radio arrays, the analyses require an accurate timing of signals within the array.
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For such radio arrays, the analyses require an accurate timing of signals within the array.
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Generally, \gls{GNSS} is used to synchronise the detectors.
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Generally, \glspl{GNSS} are used to synchronise the detectors.
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However, advanced analyses require an even higher accuracy.
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However, advanced analyses require an even higher accuracy than currently achieved with these systems.
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This thesis investigates a relatively straightforward method (and its limits) to obtain this required timing accuracy for radio arrays.
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In this thesis, methods (and their limits) to obtain this accuracy for radio arrays are investigated.
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% >>>
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% >>>
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\section{Cosmic Particles}%<<<<<<
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\section{Cosmic Particles}%<<<<<<
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%\hrule
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%\hrule
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% Cosmic Particles = CR + Photon + Neutrino
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% Cosmic Particles = CR + Photon + Neutrino
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There is a variety of extra terrestrial particles with which the Earth is bombarded.\Todo{rephrase}
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There is a variety of extra terrestrial particles with which the Earth is bombarded.
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These can be classified into three main types: charged nuclei (typically protons $Z=1$ up to iron $Z=26$), photons and neutrinos, each with different propagation effects.
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These can be classified into three main types: charged nuclei (typically protons $Z=1$ up to iron $Z=26$), photons and neutrinos, each with different propagation effects.
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The charged nuclei are the bulk of the measured particles.
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The charged nuclei are the bulk of the measured particles.
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The various magnetic fields that they travel through deflect\Todo{word} them due to their charge.
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The various magnetic fields that they travel through deflect them due to their charge.
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They do not point back to their sources because of this.
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Because of this, they do not point back to their sources.
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Photons do not suffer from being charged, and thus have the potential to identify their sources.
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Photons do not suffer from being charged, and thus have the potential to identify their sources.
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However, they can be absorbed and created by multiple mechanisms.\Todo{rephrase/expand}
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However, they can be absorbed and created by multiple mechanisms.\Todo{rephrase/expand}
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With an approximate size of $ $\Todo{size} and an average magnetic field of $5\mathrm{\;\mu G}$\Todo{}, the Milky Way can only contain particles up to an energy of about $10^{17}\eV$\Todo{fill}.
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With an approximate size of $ $\Todo{size} and an average magnetic field of $5\mathrm{\;\mu G}$\Todo{}, the Milky Way can only contain particles up to an energy of about $10^{17}\eV$\Todo{fill}.
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Still, particles with higher energies have been observed (see Figure~\ref{fig:}).
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Still, particles with higher energies have been observed (see Figure~\ref{fig:}).
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These higher energy particles must thus come from beyond our galaxy.
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These higher energy particles must thus come from beyond our galaxy.
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\Todo{rewrite paragraph}
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Likewise, with an rapidly increasing flux for lower energies, one component can be assorted\Todo{rephrase} as coming from within the galaxy.
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Likewise, with an rapidly increasing flux for lower energies, one component can be assorted\Todo{rephrase} as coming from within the galaxy.
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These different components have a different width.\Todo{rephrase}
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These different components have a different width.\Todo{rephrase}
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The hadronic component is greatly collimated, while the electromagnetic component.
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The hadronic component is greatly collimated, while the electromagnetic component.
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\\
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\\
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\Todo{rewrite paragraph}
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\begin{figure}%<<< airshower:depth
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\begin{figure}%<<< airshower:depth
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\centering
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\centering
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Processes in an air showers also generate radiation that can be picked up as coherent radio signals.
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Processes in an air showers also generate radiation that can be picked up as coherent radio signals.
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%% Geo Synchro
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%% Geo Synchro
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Due to the magnetic field of the Earth, the electrons in the air shower generate radiation.
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Due to the magnetic field of the Earth, the electrons in the air shower generate radiation.
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Termed geomagnetic emission in Figure~\ref{fig:airshower:polarisation}, this has a polarisation that is dependent on the magnetic field vector $B$ and the air shower velocity $v$.
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Termed geomagnetic emission in Figure~\ref{fig:airshower:polarisation}, this has a polarisation that is dependent on the magnetic field vector $\vec{B}$ and the air shower velocity $\vec{v}$.
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\Todo{expand?}
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\Todo{expand?}
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\\
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\\
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%% Askaryan / Charge excess
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%% Askaryan / Charge excess
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@ -149,6 +153,7 @@ Additionally, the shower travels faster than the speed of light in the atmospher
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This generates an
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This generates an
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The detection of the radio signals is limited to an
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The detection of the radio signals is limited to an
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This is limited by the so-called Cherenkov angle.
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This is limited by the so-called Cherenkov angle.
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\Todo{finish paragraph}
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\begin{figure}%<<< airshower:polarisation
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\begin{figure}%<<< airshower:polarisation
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\label{fig:airshower:polarisation:askaryan}
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\label{fig:airshower:polarisation:askaryan}
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\end{subfigure}
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\end{subfigure}
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\caption{
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\caption{
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From \protect \cite{Schoorlemmer:2012xpa} \protect\cite{Huege:2017bqv}
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From \protect \cite{Schoorlemmer:2012xpa, Huege:2017bqv}
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\protect \Todo{Krijn?}
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\protect \Todo{Krijn?}
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Radio Emission mechanisms: \subref{fig:airshower:polarisation:geomagnetic} geomagnetic and \subref{fig:airshower:polarisation:askaryan} charge-excess)
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The Radio Emission mechanisms and the resulting polarisations of the radio signal: \subref{fig:airshower:polarisation:geomagnetic} geomagnetic and \subref{fig:airshower:polarisation:askaryan} charge-excess)
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See text for explanation.
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}
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}
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\label{fig:airshower:polarisation}
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\label{fig:airshower:polarisation}
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\end{figure}%>>>>>>
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\end{figure}%>>>>>>
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These standalone detectors typically receive their timing from a \gls{GNSS}.
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These standalone detectors typically receive their timing from a \gls{GNSS}.
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Previously, for timing of water-Cherenkov detectors, this timing accuracy was better than the resolved data\Todo{rephrase}.
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Previously, for timing of water-Cherenkov detectors, this timing accuracy was better than the resolved data.
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Even for the first analyses of radio data, this was sufficient.
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Even for the first analyses of radio data, this was sufficient.
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However, for advanced analyses such as radio interferometry, the timing accuracy must be improved.
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However, for advanced analyses such as radio interferometry, the timing accuracy must be improved.
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% Structure summary
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% Structure summary
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In this thesis, a solution to enhance the timing accuracy of air shower radio detectors is worked out\Todo{word}.
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In this thesis, a solution to enhance the timing accuracy of air shower radio detectors is demonstrated.
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First, an introduction to radio interferometry is given in Chapter~\ref{sec:interferometry}.
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First, an introduction to radio interferometry is given in Chapter~\ref{sec:interferometry}.
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This will be used later on and gives an insight into the timing accuracy requirements.
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This will be used later on and gives an insight into the timing accuracy requirements.
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Chapter~\ref{sec:disciplining} introduces the concept of a beacon transmitter to synchronise an array of radio antennas and constrains the achievable timing accuracy using the techniques described in the preceding chapter.
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Chapter~\ref{sec:disciplining} introduces the concept of a beacon transmitter to synchronise an array of radio antennas and constrains the achievable timing accuracy using the techniques described in the preceding chapter.
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Chapter~\ref{sec:single_sine_sync} shows\Todo{word} how a sine wave beacon can synchronise an array while using the radio interferometric approach to resolve\Todo{word} an airshower.
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Chapter~\ref{sec:single_sine_sync} establishes a method to synchronise an array using a single sine wave beacon while using the radio interferometric approach to resolve\Todo{word} an airshower.
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Finally, Chapter~\ref{sec:gnss_accuracy} investigates the limitations of the current hardware of \gls{GRAND} and its ability to record and reconstruct a beacon signal.
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Finally, Chapter~\ref{sec:gnss_accuracy} investigates the limitations of the current hardware of \gls{GRAND} and its ability to record and reconstruct a beacon signal.
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\end{document}
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\end{document}
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