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WP2 Alignment Task: Status Report

WP2 Alignment Task: Status Report. Introduction Alignment Monitoring – LHCb VELO Weak Modes – LHCb VELO AIDA Alignment Web page AIDA Telescope (WP9) Resolution – GEANT4 Material Description. LHCb VELO. Highest precision vertex detector at LHC.

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WP2 Alignment Task: Status Report

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  1. WP2 Alignment Task: Status Report Introduction Alignment Monitoring – LHCb VELO Weak Modes – LHCb VELO AIDA Alignment Web page AIDA Telescope (WP9) Resolution – GEANT4 Material Description

  2. LHCb VELO • Highest precision vertex detector at LHC VELO Resolution vs pitch for 2 projected angle bin Moves for each LHC fill

  3. Monitoring With thanks to Giulio Dujany, CERN summer student

  4. Alignment monitoring • Variation of alignment, e.g. • Temperature effect • Mechanical variation • Monitoring in DQ offline procedure: • residual bias • Other physics parameters (PV, IP, etc.)

  5. Monitoring of sensor alignment • Residual along radial and azimuthal direction • Misalignment for x, y, z translation and rotation around x, y, z axis • Geometrical consideration to extract misalignment from the residual bias distribution Simplified formula

  6. Monitoring of Sensor Alignment • Misalignment evaluated: • Survey measurements • Alignment based on 2010 data • Alignment based on 2011 data RMS 0.86 ± 0.04 RMS 2.06 ± 0.09 Tx RZ Ty RMS 0.053 ± 0.003 RMS 0.130 ± 0.006 RMS 0.64 ± 0.03 RMS 2.44 ± 0.11

  7. Alignment stability on 2011 data • 2011 alignment • 3 period considered: June, July and August • VELO alignment stable in the considered period. • Method is used to monitor routinely the alignment stability

  8. Monitoring: 2 half alignment Fully open Closed pos. • VELO centred around the beam for each fill when the beam declared stable • Primary Vertex method: • Reconstruct PV using tracks in left or in the right side • Evaluation of misalignment by the distance between the two vertices X

  9. Monitoring: 2 half alignment 2010 data 2011 data • Stability of 2 half alignment by PV method: • within ± 5 m for Tx

  10. Weak Mode

  11. S. Ogilvy VELO: weak mode study • Weak mode: • Negligible effect on residuals and 2  Alignment procedure not sensitive to weak mode • Distortions on IP or other physics quantities • Main weak modes (strong dependence on detector geometry): • Twist around the z axis: R’z=Rz+ ·z • z- scaling • x or y shearing Mean IPy vs phi Collision Data MC weak mode

  12. S. Ogilvy VELO: weak mode study • Different constraints for different track samples • Collision data • Beam gas events • Sensitivity to some of this mode selecting the proper type of tracks

  13. Communication

  14. AIDA Alignment Web Page • Collect Alignment Contacts & Literature http://sborghi.home.cern.ch/sborghi/AIDAalignment/AIDAalignment/Home.html Will move to AIDA WP2 page

  15. AIDA Connections

  16. WP9 – MEDIPIX Telescope Daniel Hynds, Paula Collins et al. • Stunning performance Telescope • High track rate,1μm resolution,1ns timing • Huge testbeam programme of sensor testing performed this year • LHCb, ATLAS, RD50 sensors Will provide support software from WP2

  17. Plans and Summary Work towards AIDA Aims: Alignment Stability Monitoring Weak Modes Study Web Page • Dedicated PhD Student • Generalise Alignment work for AIDA • Forge links other expts • Apply software to pixel testbeam (WP9)

  18. Material Description Matt Reid et al. • Data / Simulation discrepancy at low PT • Material / multiple scattering • Dominant material component is 300μm Aluminium foil – very complex shape • Now studying tools CAD Drawings  GDML Thanks to John Apostolakis, Gabriele Cosmo

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