The selective read-out processor for the CMS electromagnetic calorimeter

This paper describes the selective read-out processor (SRP) proposed for the electromagnetic calorimeter (ECAL) of the CMS experiment at LHC (CERN). The aim is to reduce raw ECAL data to a level acceptable by the CMS DAQ system. For each positive level 1 trigger, the SRP is guided by trigger primitive generation electronics to identify ECAL regions with energy deposition satisfying certain programmable criteria. It then directs the ECAL read-out electronics to apply predefined zero suppression levels to the crystal data, depending whether the crystals fall within these regions or not. About 200 of high speed 1.6 Gbit/s I/O channels, asynchronous operation at up to 100 kHz level 1 trigger rate, a stringent real-time requirement of 5 μs latency and flexibility in choice of selection algorithms are the main challenges of the SRP application. The architecture adopted for the SRP is based on modern parallel optic pluggable modules and high density FPGA devices with embedded processors and multi-gigabit transceivers. Implementation studies to validate proposed solutions are presented. The performance of envisaged selection algorithms is investigated with the CMS detector simulation software. The robustness of optical communication channels is estimated via direct measurements and calculations. The feasibility to perform data reduction operations within the allocated timing budget is verified by running a representative SRP firmware on a development board with a Xilinx Virtex2Pro FPGA device.