Td discovery use cases/ change name for include (#23)

* update date of doc

* query correction

* updates use case appendix

* update TDUC discovery- change name

---------

Co-authored-by: loumir <[email protected]>

Makefile

@@ -10,7 +10,6 @@ DOCVERSION = 1.0
 # Publication date, ISO format; update manually for "releases"
 DOCDATE = 2024-07-01
 
-
 # What is it you're writing: NOTE, WD, PR, REC, PEN, or EN
 DOCTYPE = WD
 

ObscoreTimeExtension.tex

@@ -578,19 +578,17 @@ \subsubsection{ t\_fold\_period,  t\_fold\_phaseReference}
 %JOIN lightmeter.stations
 %USING (stationid)
 
-
-
-
 \appendix
 \include{appendix_table_time_reference_Ada}
 
 \section{Query examples for join tables}\label{sec:query_examples}
-\include{Time_domain_discovery_Use-cases}
+\include{TDUC-discovery}
 
 % NOTE: IVOA recommendations must be cited from docrepo rather than ivoabib
 % (REC entries there are for legacy documents only)
 %\section{References}
-% note:TSSerialisationNote
+
+ % note:TSSerialisationNote
 
 \bibliography{ivoatex/ivoabib, ivoatex/docrepo, myref}
 \section{Previous work on the Time series characterization and description}.

TDUC-discovery.tex

@@ -0,0 +1,89 @@
+
+%%  Discovery of data products for Time domain use cases
+\lstset{captionpos=t}
+\begin{itemize}
+\item  Finding a light curve in a time interval for a sky position 
+ \begin{lstlisting} [language=SQL, captionpos=t, caption=Show me a list of all data matching a particular event (gamma ray burst) in time interval and space ]
+    I. DataType=light-curve
+   II. RA includes 16.00 hours
+  III. DEC includes +41.00
+   IV. Time start > MJD 55220 and Time stop < MJD 55221
+    V. Number of time slots > 1000 
+  \end{lstlisting}
+
+\item  Times series for a sky position, with date, length and exposure constraints
+\begin{lstlisting} [language=SQL, caption=Show me a list of all data which satisfies]
+    I. DataType=time-series
+   II. RA includes 16.00 hours
+  III. DEC includes +41.00
+  IV. Time resolution better than 1 minute
+   V. Time interval (start of series to end of series) > 1 week
+  VI. Observation data before June 10, 2008
+ VII. Observation data after June 10, 2007      
+  \end{lstlisting}   
+
+\item  Finding a light curve in folded mode for pulsar analysis 
+\begin{lstlisting} [language=SQL, caption=Show me a list of all data matching a light curve for a pulsar candidate]
+    I. DataType=light-curve
+   II. time resolution <  0.001 s 
+   III. time axis is folded 
+   IV. exposure time > 5s
+   \end{lstlisting}  
+
+\item  Finding MUSE cube time series
+\begin{lstlisting} [language=SQL, caption=Show me a list of all data products from MUSE data collection with more than 30 items]
+    I. DataType=time-cube
+   II. Data collection like  'MUSE'
+  III. Number of time slots > 30
+  \end{lstlisting}
+
+ % trouver des MASER sources radio variables avec un SNR suffisant --> convertit en t_exp_min > seuil 
+\begin{lstlisting} [language=SQL, caption= Show me a list of all data matching a light curve for a radio source ]
+    I. DataType=light-curve
+   II. Band corresponds to Radio %em_min > radio_min   and em_max < radiomax xxx 
+   III. Minimum time sample > 3s 
+   IV. Number of time slots > 10
+   \end{lstlisting} 
+ % trouver des light_curve comparables à celles de ma liste de source qui sont en TDB Barycenter
+ \begin{lstlisting} [language=SQL, caption=Show me a list of all data products using a specified Time system ]
+   Show me a list of all data products using a specified Time system  
+    I. DataType=light-curve or time-series
+    II. time scale=TDB
+    III. time reference position=BARYCENTER 
+  \end{lstlisting}
+
+ % identifier des transits de planetes 
+ TESS ?? 
+
+ % identifier des systemes d'étoiles binaires 
+ ADA ??
+
+ % nature article https://doi.org/10.1038/s41586-023-06787-x
+ \item  Here is an example of the data discovery steps one would launch in the VO for looking at specific binary systems 
+ in the supernova SN 2022jli \citep{2024Natur.625..253C}
+
+ % A 12.4-day periodicity in a close binary system after a supernova
+ % target position in ICRS 00 34 45.690 -08 23 12.16 %
+ % object name = SN 2022jli
+ \begin{lstlisting} [language=SQL, caption=Show me a list of light curves around object   \emph{SN 2022jli}]
+    I. DataType=light-curve 
+    II. target position close to SN 2022jli
+    III. em\_min >  10  and em\_max <  1.0E-8 % radio  and Xray , gammaray
+    VI. Observation data before Sept 31, 2023
+    VII. Observation data after Sept 01, 2022    
+   \end{lstlisting}
+
+  Check what the Fermi-Lat telescope may have seen in the mean time 
+  \begin{lstlisting} [language=SQL, caption=Show me a list of light curves around object   \emph{SN 2022jli}]
+     I. DataType=light-curve 
+    II. Data collection like Fermi-Lat 
+    IV. t\_min > 59823     %Observation data before sept 31, 2023
+    V. t\_max < 60218   % Observation data after sept 01, 2022
+  \end{lstlisting}
+
+   \begin{lstlisting} [language=SQL, caption=Show me a list of dynamic spectra around object   \emph{SN 2022jli}]]
+     I. DataType=dynamic-spectrum
+    II. target position close to SN 2022jli
+    \end{lstlisting} 
+
+  \end{itemize}