Methods for the application of programmable logic devices in electronic protection systems for high energy particle accelerators

The present thesis was realised within the framework of the Doctoral Student programme at the European Organisation for Nuclear Research CERN, which is situated near Geneva. The aim of this thesis was to develop a method for reliable rmware implementation and to use that method to implement a new rmware for the Safe Machine Parameters (SMP) system. That system relies heavily on the Field Programmable Gate Arrays (FPGA) and it is one of the key machine protection systems of the Large Hadron Collider (LHC). The conception of the SMP hardware originates from the fully tested Beam Interlock System (BIS) being a result of another PhD thesis [1]. For that reason the reliable SMP hardware was preserved unchanged. The rst version of the SMP was ready for the LHC startup in the year 2008. Nevertheless the quality of the SMP rmware was objectionable. There were new requirements and therefore the SMP speci cation was extended. On that occasion it was decided that the existing SMP rmware will not be continued and that it should be started from scratch. For the new version the rmware implementation should be carried out on the basis of the strictly de ned approach, which will ensure high quality and therefore reliability of the SMP. The starting point of the work was the IEC 61508 standard, which was supposed to be matched for the speci c needs of the facility carrying out the high energy physics experiments like CERN. As the result of that thesis a full electronic protection system lifecycle was proposed, form the conception through the risk analysis to the implementation and deployment. The method proposed was applied to the critical rmware implementation of the SMP. Examples of the most critical functions realised by the SMP system are shown in the nal chapters of the thesis. The second version of the SMP was deployed to be used in the LHC accelerator in the year 2010. Since then it performs its role without failures and therefore it is foreseen to be operated without any changes up to the end of the LHC project. The second result of the thesis is the proposed lifecycle, which can be used for the evaluation of the existing project or for the implementation of the new programmable protection systems for the high energy particle experiments at CERN or in the similar scienti c laboratory.