1 / 17

FVTX Data Acquisition System

FVTX Data Acquisition System. Mark Prokop Accelerator Operation &Technology Division RF Engineering Group. Introduction. Overview of the Engineering Problem System Implementation Concluding remarks. Engineering Problem.

makara
Download Presentation

FVTX Data Acquisition System

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. FVTX Data Acquisition System Mark Prokop Accelerator Operation &Technology Division RF Engineering Group

  2. Introduction • Overview of the Engineering Problem • System • Implementation • Concluding remarks

  3. Engineering Problem • Transport data from the detectors to the PHENIX data collection system • Meet requirements • Abide with the constraints

  4. Data Transport

  5. Requirements • Physics • Signal-to-noise, radiation length • data capture and integrity • Timing • LVL-1 • DCM • Radiation • 100k-200k Rad Integrated dose over 10 years • 1.0x10-7 to 1.6x10-5 /bit/hour upset rates • Physical

  6. Constraints • Mechanical • Thermal • PHENIX System • Data Collection rates • Collocated with VTX • IR Shared with other detector systems • PHENIX Environment • Noise • Magnetic Fields • Interference

  7. DAQ System

  8. System Design Approach • Radiation Tolerance to 20kRad • Radiation immunity for FPGA configuration data • Built-in test and diagnostics • B-Field Immunity • Flexible Grounding options • EMI environment tolerant • Moderate design challenge • Compatible with existing PHENIX data collection system • Meet LVL-1 timing

  9. ROC Features • Radiation tolerant FPGA and SERDES • Combines data from 52 FPHX chips • Synchronization • Removal of sync words • ~17:1 data rate reduction

  10. ROC Concept PCB

  11. FEM Features • VME Based • Xilinx FPGA • 4 FEMs per VME card • 1:1 FEM to ROC ratio • Store data by BCO clock and buffer for 64 BCO clocks • Combine 4 FEM data streams and transmit to single DCM • ~23:1 data rate reduction

  12. Integrated System

  13. System Performance 1 • No impact on signal-to-noise or radiation length • Capturing all event data • Radiation Tolerance • Immunity to configuration upsets • Fits Mechanical and Thermal Design Parameters • Fully Compatible with PHENIX Data systems • Meets LVL-1 Timing • Meets DCM Data requirements

  14. System Performance 2 • Sensor-to-ROC interconnect designed for EMI environment • Co-Designed with VTX • Designed for immunity to B-field • Fully compatible with existing PHENIX data collection system

  15. Concluding Remarks • Status • Next steps

  16. Current Status • Demonstrated ROC and FEM functionality • System data collection requirements analyzed: LVL-1 and DCM requirements met • No critical R&D issues for electronics hardware

  17. Next Steps • Demonstrate 2.5 Gbit/sec FO Link • Full up Prototype ROC, FEM and FO communications including integration with PHENIX data collection system (DCM) • Engineering systems electronics and interconnections for Noise, EMI and Grounding requirements

More Related