Your responsibilities
Are you a passionate hardware developer who loves to tackle challenging problems that help advance basic science? Do you enjoy working with modern technologies? Then come join us to develop a next generation electronics board for data acquisition at the Compact Muon Solenoid (CMS) experiment, one of the major detectors at the LHC.
At CMS, we face the task of processing collisions between proton bunches at up to 40 MHz, which would generate an immense data rate. Our level-1 (L1) trigger, employing custom firmware logic in hundreds of FPGAs, selects promising events in microseconds for data acquisition and further detailed analysis. We're currently upgrading the trigger and data acquisition systems for the future high-luminosity phase of the LHC.
One of our R&D activities is exploring the potential of a complementary system called L1 Data Scouting, which would analyze a data stream containing all events but with just the coarse grain L1 trigger information. To fully exploit the potential of such a system, we would like to develop a novel data acquisition board based on the latest generation FPGAs and high-speed network technology - and you will be the architect of this board.
This R&D is in the broader context of the NextGen Triggers project, a 5-year collaboration between the LHC experiments and the CERN Research and Computing Departments to push forward the use and impact of innovative Artificial Intelligence technologies and high-performance computing architectures for the LHC experiments' trigger selection, data processing, and theoretical interpretation.
Responsibilities:
Your profile
Skills
Eligibility criteria:
Job closing date: 12.01.2025 at 23:59 CET.
Contract duration: 24 months, with a possible extension up to 36 months maximum.
Working hours: 40 hours per week
Target start date: 01-February-2025
Job reference: EP-CMG-OS-2024-193-GRAP
Field of work: Applied Physics
What we offer
About us
At CERN, the European Organization for Nuclear Research, physicists and engineers are probing the fundamental structure of the universe. Using the world's largest and most complex scientific instruments, they study the basic constituents of matter - fundamental particles that are made to collide together at close to the speed of light. The process gives physicists clues about how particles interact, and provides insights into the fundamental laws of nature. Find out more on http://home.cern.
We are on a Quest. A Journey into discovery like no other. Bring your expertise to our unique work and develop your knowledge and skills at pace. Join world-class subject matter experts on unique projects, in a Quest for greater knowledge and deeper understanding.
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Diversity has been an integral part of CERN's mission since its foundation and is an established value of the Organization. Employing a diverse workforce is central to our success.