The most demanding WR applications in terms of timestamping are cosmic ray and
The most demanding WR applications in terms of timestamping are cosmic ray and
neutrino detectors that record the time of arrival of particles in individual
neutrino detectors that record the time of arrival of particles in individual
detector units distributed over up to kilometers. Based on the difference
detector units distributed over \textcolor{red}{distances up to several} kilometers.
in the time of arrival, the trajectory of particles are calculated. For these
Based on the difference
in the \textcolor{red}{times of arrival of the same particles detected by different unit}, the trajectories of these particles are calculated. For these
applications, a high precision and accuracy is required in harsh
applications, a high precision and accuracy is required in harsh
environmental conditions due to their locations \cite{biblio:TAIGA-WR-harsh-env}.
environmental conditions due to their locations \cite{biblio:TAIGA-WR-harsh-env}.
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@@ -508,7 +509,7 @@ Other applications of WR that use timestamping include the
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@@ -508,7 +509,7 @@ Other applications of WR that use timestamping include the