Simulation der Energierekonstruktion der verbesserten Flüssigargon-Kalorimeter-Auslese bei ATLAS

The Large Hadron Collider (LHC) at CERN is designed to accelerate particles close to the speed of light and to collide them. Several particle detectors investigate the proton-proton collisions. One of them is the ATLAS detector, which consists of different sub-detectors. The purpose of one of them, the Liquid-Argon (LAr) calorimeter, is to measure the energy of particles. The deposited energy from particles is processed, analysed and reconstructed in the end by filter algorithms in the readout electronics. Since there are many particle interactions for each bunch crossing the ATLAS detector has a trigger system to select only the interactions of physical interest. For 2018 an upgrade of the LHC and ATLAS is planned to increase the luminosity. Which is a big challenge for the trigger system. Therefore an upgrade of the readout electronics of the LAr calorimeter is planned. Simulations are used and presented to evaluate the design of the future readout electronics. In this thesis the analog pulse shapes of the future readout electronics are simulated by a SPICE program. Those pulse shapes are then compared to measured pulse shapes by the demonstrator boards of the future readout. Furthermore filter algorithms for the energy reconstruction are being tested with software based simulations.