1 / 19

IoP HEPP/APP annual meeting 2010

Feedback on Nanosecond Timescales: maintaining luminosity at future linear colliders Ben Constance John Adams Institute, University of Oxford. IoP HEPP/APP annual meeting 2010. Introduction. The problems associated with achieving high luminosity at linear colliders

fuller
Download Presentation

IoP HEPP/APP annual meeting 2010

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. Feedback on Nanosecond Timescales: maintaining luminosity at future linear colliders Ben Constance John Adams Institute, University of Oxford IoP HEPP/APP annual meeting 2010

  2. Introduction • The problems associated with achieving high luminosity at linear colliders • Focus on ‘cold’ colliders – International Linear Collider bias… • Feedback system requirements • Description of the FONT interaction-point feedback system • FONT5 installation at the ATF, KEK Japan • Winter 2009/10 beam test results • Plans for spring 2010 Ben Constance IoP HEPP/APP annual meeting 2010 1

  3. The International Linear Collider and its beam structure ~31 km • The ILC beam design is as follows: • Pulsed operation at 5Hz, each pulse contains 2625 bunches • Bunches separated by 370ns and contain 2x1010 particles • Structure driven by factors such as: • Klystron RF power sources and damping rings • Superconducting accelerating cavities • The long bunch spacing can be exploited for digital feedback Ben Constance IoP HEPP/APP annual meeting 2010 2

  4. The ILC luminosity goal • Luminosity target of 1034 cm-2s-1 (same as the LHC target) • Single collision opportunity, therefore very small beams at IP • Just 5.7nm by 639nm at the interaction point • Need synchrotron cooling with damping rings • We can use very strong focussing not possible in a ring • Focus the beam so tightly at the IP that it is unstable afterwards • The positions of the beams must be very stable • Careful machine and beam alignment plus feedback systems Ben Constance IoP HEPP/APP annual meeting 2010 3

  5. Fast IP feedback systems • Many effects can misalign the few nm beams, e.g. • Ground motion • Temperature fluctuations (cooling water, electronics) • Mechanical vibration • Bunch-by-bunch feedback • Determine the offset error of the first bunch after the IP • Calculate a correction to the next bunch’s position • Apply nm level correction before the next bunch reaches IP (< 370ns) • Repeat for entire train • IPFB makes use of beam-beam deflection after the IP • As the beams pass each other, they each receive a large kick • This kick is determined by the beams’ relative offset • Trivial to measure >100μm deflection after IP Ben Constance IoP HEPP/APP annual meeting 2010 4

  6. Beam-beam kick simulation Ben Constance IoP HEPP/APP annual meeting 2010 5

  7. The FONT project at the JAI • Feedback on Nanosecond Timescales • At JAI we are working on a digital bunch-by-bunch IPFB system for ILC • Measure deflection of one beam and correct the other • Delay loop ensures we retain and improve previous correction Ben Constance IoP HEPP/APP annual meeting 2010 6

  8. ATF2 • FONT is currently being tested at ATF2 • The Accelerator Test facility in KEK, Japan • Designed to demonstrate ILC-like beam sizes • Single 1.3GeV electron beam, 150ns bunch spacing • Single linac, damping ring, extraction line • New final focus system Ben Constance IoP HEPP/APP annual meeting 2010 7

  9. FONT5 at the ATF2 extraction line FONT5 installation region Final doublet and beam dump Ben Constance IoP HEPP/APP annual meeting 2010 8

  10. ATF2 design goals • Demonstrate a 35nm beam size • New final focus installed • Beam characterisation and tuning very much in progress • Demonstrate nanometre–level stability • This needs micron stability at the entrance to final focus • FONT5 system has been commissioned to provide this • We have micron-resolution processors • Our kickers can provide micron-level corrections at ~1GeV • Resolution of FB system defined by smallest correction possible • A kick that provides 1μm correction at 1GeV provides 1nm correction at 1TeV • FONT goals at ATF and ILC are compatible Ben Constance IoP HEPP/APP annual meeting 2010 9

  11. P1 P2 P3 To dump K1 QD10X QF11X K2 QD12X QF13X QD14X QF15X FB board DAQ FONT5 ATF2 beamline installation • Three stripline BPMs made to existing ATF ext. line specification • Two fast fixed-gap stripline kickers recovered from NLCTA (vertical orientation) • Next-generation FONT5 digital feedback board installed and operational • Flexible configuration allows a variety of feedback algorithms Control / feedback loops Ben Constance IoP HEPP/APP annual meeting 2010 10

  12. FONT5 digital feedback board • Single feedback board controls multiple loops and all DAQ • Based around a powerful Xilinx Virtex5 FPGA • 9 ADC input channels at 357 MSPS (TI ADS5474) • 4 DAC output channels (AD9744) • Basic algorithm includes: • Removal of beam intensity fluctuations • Correction of extracted train shape • Compensation for kicker pulse droop • All signal mixing, DSP, amplification • plus rise of kicker takes place in < 130ns! Ben Constance IoP HEPP/APP annual meeting 2010 11

  13. ATF pulse structure and feedback algorithm • We extract a three-bunch train • Repetition rate 2/3 Hz • Spacing variable from 140 – 154ns • Bunch charge from 1x109 up to 5x109 e- • FONT5 intra-train feedback • Aim is to reduce pulse-to-pulse jitter, i.e. correct jitter that is correlated between bunches • First bunch is a pilot bunch and is not corrected • 3 FONT BPM signals used to calculate intensity-independent position readings • Position values used to calculate 1 or 2 feedback signals and apply to kickers • Feedback signal applied to the 2nd bunch • The corrected 2nd bunch is then measured to produce a feedback for the 3rd bunch, and so on Ben Constance IoP HEPP/APP annual meeting 2010 12

  14. Results from winter 2009/10 beam tests • P2 – to – K1 feedback loop closed and analysed • Position feedback performed • (see simulations to the right) Ben Constance IoP HEPP/APP annual meeting 2010 13

  15. Beam test results (2) • Upstream corrector dipole magnet used to introduce a variety of beam offsets Ben Constance IoP HEPP/APP annual meeting 2010 14

  16. Latest beam test results (3) – jitter reduction • We allowed the feedback to operate on a nice beam 17/02/10 Ben Constance IoP HEPP/APP annual meeting 2010 15

  17. Latest beam test results (4) – jitter reduction • Repeated this experiment 18/02/10 for 25 minutes Ben Constance IoP HEPP/APP annual meeting 2010 16

  18. Plans for spring 2010 • Two-loop angle feedback • Intend to close K1 and K2 FB loops simultaneously • Interaction between the two kickers means we must couple the loops • Coupling parameters easily determined • by calibration Ben Constance IoP HEPP/APP annual meeting 2010 17

  19. Summary • Any future linear collider will require nm level stability at the IP • IPFB will be required • The FONT5 feedback system is installed and operational at ATF2 • Single-loop position feedback demonstrated • We will move on to two-loop angle feedback demonstration in the spring Ben Constance IoP HEPP/APP annual meeting 2010 18

More Related