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Front-end FPGAs in the LHCb upgrade

Front-end FPGAs in the LHCb upgrade. The issues What is known Work plan. Why. The use of FPGA in and near front end boards may help in (thoughts inspired by VELO upgrade considerations): reduce the number of optical links used in the TELL40 boards

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Front-end FPGAs in the LHCb upgrade

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  1. Front-end FPGAs in the LHCb upgrade The issues What is known Work plan Marina Artuso LHCb Electronics Upgrade Meeting

  2. Why • The use of FPGA in and near front end boards may help in (thoughts inspired by VELO upgrade considerations): • reduce the number of optical links used in the TELL40 boards • Provide an intermediate layer of processing prior to the TELL40 boards (extended BCO tag, chip ID, …)2 • Advantages: • Reconfigurable • May provide an effective way to perform the lowest level clustering, sorting, extended address/time stamp options • Interface specific detector algorithms to a common back end (TELL40) device Marina Artuso LHCb Electronics Upgrade Meeting

  3. The issues • Radiation level expected is a major constrain: for a specific application we need to know: • Radiation level expected in the board location for the planned duration of the data taking • Functionality needed in the FPGA to be adopted Marina Artuso LHCb Electronics Upgrade Meeting

  4. Starting point: survey of what is known • Sources: • Alice Detector Data Link project [200 MB/s @1.6 KRad] • “Problems and solutions to the use of FPGA’s in radiation zone” seminar by Czaba Soos [http://indico.cern.ch/conferenceDisplay.py?confId=39740] • NASA, XILINX… web sites Marina Artuso LHCb Electronics Upgrade Meeting

  5. Concerns in FPGA performance • Single-Event Upsets (SEUs) • Single-Event Transients (SETs) • Single-Event Functional Interrupt (SEFI) • Configuration loss • Data corruption • Damaging effects (Single Event Gate Rupture, Single Event Latch up) Marina Artuso LHCb Electronics Upgrade Meeting

  6. Some definitions • SEU: state change due to the charge collected by the circuit sensitive node, if higher than a critical linear energy transfer (LET) • SET: Voltage transient induced by charge deposition propagating through FPGA, latched if arrive at a clock edge, propagation distance decreases as the square of the technology feature size Marina Artuso LHCb Electronics Upgrade Meeting

  7. The ALICE DDL Project • High speed point to point optical link designed to interface the readout electronics of the ALICE sub-detectors (except inner tracker) to the DAQ computers in a standard way • Speed 200 MB/s/link • Max radiation fluence 3.9x1011 n/cm2,8x109 p/cm2, 1.5x1011 1 MeV neq/cm2 Marina Artuso LHCb Electronics Upgrade Meeting

  8. Results from Alice DDL Project Configuration loss measurements for SRAM & flash memory FPGA s= probability that the particle flips a bit cm2/logic cell Radiation tolerant ~1 KRad Marina Artuso LHCb Electronics Upgrade Meeting

  9. Data corruption measurement Mitigation techniques can be used to detect/correct data corruption. Error rate is application specific Marina Artuso LHCb Electronics Upgrade Meeting

  10. A brighter spot: radiation tolerance trend as a function of feature size Ultra thin oxide features reduced interface trap and oxide trap charge

  11. New devices • XILINX: • VIRTEX-4QV 300 KRad TID wafer lot verification • XILINX VIRTEX-5 (65 nm) • Lots of useful information at http://www.xilinx.com/esp/aero_def/radiation_effects.htm • ALTERA STRATIX (0.13 μm-0.065 μm), recently 40 nm unveiled (stratix IV) Marina Artuso LHCb Electronics Upgrade Meeting

  12. Plans • Define problem(s): • Are there different front end interfaces that have similar functionality (configuration memory size, register cell size, memory cell size…) • Which are the levels of radiation that we are tackling with (few KRad-several 100 Krad) • Useful mitigation techniques • Design demonstrator system & test at suitable level of irradiation. Marina Artuso LHCb Electronics Upgrade Meeting

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