new version of abstract

diff --git a/DPG14/trb3_collaboration.tex b/DPG14/trb3_collaboration.tex
new file mode 100644 (file)
index 0000000..0d03a4f
--- /dev/null
+++ b/DPG14/trb3_collaboration.tex
@@ -0,0 +1,28 @@
+\documentclass{scdpg}
+\begin{document}
+\scBookLanguage{de}
+\begin{scCollaboration}
+\scCollaborationName{TRB3}
+\scAuthor{}{Jörn}{Adamczewski-Musch}{1}
+\scAuthor{}{Matthias}{Hoek}{2}
+\scAuthor{}{Wolfgang}{Koenig}{1}
+\scAuthor{}{Grzegorz}{Korcyl}{3}
+\scAuthor{}{Sergey}{Linev}{1}
+\scAuthor{}{Ludwig}{Maier}{4}
+\scAuthor{}{Jan}{Michel}{5}
+\scAuthor{}{Andreas}{Neiser}{2}
+\scAuthor{}{Marek}{Palka}{3}
+\scAuthor{}{Manuel}{Penschuck}{5}
+\scAuthor{}{Michael}{Traxler}{1}
+\scAuthor{}{Cahit}{Ugur}{1}
+\scAuthor{}{Adrian}{Zink}{6}
+\scAffiliation{1}{GSI Helmholtzzentrum f\"ur Schwerionenforschung GmbH Darmstadt}
+\scAffiliation{2}{Institut f\"ur Kernphysik, Johannes Gutenberg-Universit\"at Mainz}
+\scAffiliation{3}{Department of Physics, Jagiellonian University Cracow, Poland}
+\scAffiliation{4}{Physik-Department E12, Technische Universit\"at M\"unchen}
+\scAffiliation{5}{Institut f\"ur Kernphysik, Goethe-Universit\"at Frankfurt}
+\scAffiliation{6}{Physikalisches Institut IV, Universit\"at Erlangen-N\"urnberg}
+\scConference{Frankfurt 2014}
+\scEmail{j.michel@gsi.de}
+\end{scCollaboration}
+\end{document}

diff --git a/DPG14/trb_collaboration_dpg_14.tex b/DPG14/trb_collaboration_dpg_14.tex
index f02bdf95afdd61dd203f562e07298df2acf51eab..50515a5aa0c723a058aa61fd29f99f34a127428c 100644 (file)
--- a/DPG14/trb_collaboration_dpg_14.tex
+++ b/DPG14/trb_collaboration_dpg_14.tex
@@ -5,6 +5,7 @@
 \scLanguage{en}
 \scTitle{TRB3-based DAQ systems - A collaborative approach}
 \scAuthor{*}{Jan}{Michel}{1}
+\scCollaborationName{TRB3}
 \scAffiliation{1}{Goethe-Universit\"at Frankfurt}
 \scBeginText
 
@@ -12,22 +13,22 @@ Modern detector systems have become complex and the demands on data-
 and event-rates made designing a fitting data acquisition scheme a major task. On 
 the other hand, many small research groups need a fast way to set up a small system 
 for testing of detector prototypes. 
+
 During the past years, the data acquisition system of the HADES detector at GSI has 
-been rebuilt. During this time, a huge set of electronic components, a network data 
+been upgraded. Within this project, a huge set of electronic components, a network data 
 transport protocol and software for data storage as well as control and monitoring 
-of the detector has been developed. This framework has been further developed, a new
+of the detector were developed. This framework has been further extended, a new
 versatile FPGA platform (TRB3) has been built and can be adapted to many different 
 needs by AddOn and front-end modules.
 
 The full toolchain has been successfully used by various sub-groups of the FAIR 
 experiments CBM, PANDA and HADES. Several other detector groups are interested in 
-and are actively contributing to the project.
-
-This talk will focus on the advantages such a collaborative community has for all 
-participants. Among these is the small amount of work to be contributed by the 
-individual, the fast installation time of new set-ups and versatile software 
-environment to which all users contribute.
+the project and are actively contributing. This talk will focus on the advantages
+such a collaborative community has for all partners. Among these is the small 
+amount of work to be contributed by the individual, the fast installation time 
+of new set-ups and the versatile software environment to which all users contribute.
 
+This work has been supported by BMBF, HIC for FAIR, and GSI.
 
 \scEndText
 \scConference{Frankfurt 2014}