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ATF nanoBPM system - nanoGrid ATF2 Movers TTF HOM – dipole / monopole
Test Facility Experimental Program ILC Division RD report June 12, 2006 Marc Ross ATF2 cavity BPMs ATF nanoBPM system - nanoGrid ATF2 Movers TTF HOM – dipole / monopole ESA/LCLS bunch length ILCTA 6/12/2006
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ATF2 Cavity BPM SLAC group will provide the full cavity system from the hybrid combiner to data server 70 + channels Beam tests April 10 – 22. Single ATF2 cavity between the two triplets (no mover) First look is ‘good’ Data analysis started Full system delivery delayed (was to have been June 5) – delay is mid-August. Following discussions with group at ATF2 meeting Our first cavity BPM System Test result documentation (acceptance) Mechanical Calibration algorithm 4/24/2006 Marc Ross - SLAC
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ATF2 Cavity BPM Production electronics
6 GHz receiver board layout Realistic system design including packaging and mounting hardware Tested successfully at ATF April 2006 4/24/2006 Marc Ross - SLAC
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System design Local configuration 4/24/2006
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Beam Tests of ATF2 electronics (Y. Honda)
4/24/2006 Marc Ross - SLAC
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Beam Tests 4/24/2006 Marc Ross - SLAC
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Beam Tests 4/24/2006 Marc Ross - SLAC
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Schedule 4/24/2006 Marc Ross - SLAC
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Do the Nanogrids Help? Data from 13 April 2006 at 22:56:
96 events at nominal position 64 events at +/-20 microns to calibrate Resolution, no nanogrids 19.1 nm Resolution, with nanogrids 15.6 nm 4/24/2006 Marc Ross - SLAC
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ATF Laserwire extraction line near old Compton IP
requires special optics need wire scanner to confirm backup lens – real one delayed and lost in the mail (Oxford) now testing fully corrected lens for operation in November two graduate students to be posted at ATF all year Miryam Qureishi (Oxford) and Lawrence Deacon (RHUL) Guidance from Pavel Karataev (RHUL) 4/24/2006 Marc Ross - SLAC
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ATF laser – wire scan (May 25)
First scans Optics and laser aberrations (factor 10 scale error) σ = /- 0.4 µm 4/24/2006 Marc Ross - SLAC
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ATF2 Mover System 4/24/2006 Marc Ross - SLAC
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Mover shipping and requirements:
4/24/2006 Marc Ross - SLAC
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TTF HOM studies – plan for August
Goals: install and commission the HOM BPM DOOCs server beam tests of HOM SVD algorithm fast processor HOM board (FNAL) HOM phase feedback 7 shifts; 2 weeks of beam time July 28 to August 13 A lot of time allocated 3 DESY, 5 Fermilab, 2 SLAC, 2 Saclay staff, ANL, JLab, Cockroft. Steve Molloy (SLAC) and Nathan Eddy (Fermi) working on analysis 4/24/2006 Marc Ross - SLAC
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Phase Measurement from Monopole modes
Phase of monopole modes determined by beam phase. Use fast (5GS/s, 6GHz BW) scope directly measuring HOM signals Compare HOM monopole phases with 1.3 GHz reference Not completely straightforward since TTF trigger jitter > 1 cycle of 1.3GHz Plot phase vs. machine cycle for TM011-7 and TM011-8, and phase difference between modes Note: measurent uses “accidental” data, taken during other experiment, not optimized. 4/24/2006 Marc Ross - SLAC
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Higher Order Monopole Modes
2300 – 2500 MHz Both couplers for 1 cavity shown 0.1 degree (L-band) precision 0.2 ps Note that different lines have different couplings to the 2 couplers Monopole lines due to beam, and phase is related to beam time of arrival Fundamental 1.3GHz line also couples out – provides precise RF to beam phase for control 4/24/2006 Marc Ross - SLAC
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Beam Phase vs. RF Measurement During 5 Degree Phase Shift
2 cavities, same structure give 0.34 degree L-band RMS phase difference Measure 5 degree phase shift commanded by control system 4/24/2006 Marc Ross - SLAC
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What is System Resolution, Drift
Compare 2 couplers on same cavity, RMS difference 0.12 degrees L-band. Electronics noise ~0.08 degrees cavity to cavity difference (0.3 degrees may be due to microphonics) Compare 2 cavities for long (7 hour) run. RMS difference 0.69 degrees L-band. Combination of electronics drift and cavity to cavity phase shifts. 4/24/2006 Marc Ross - SLAC
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Summary of Phase System Performance
System noise ~0.08 degrees L-band, 1 minute timescales. Also measured ~0.1 degree for 10 minutes Cavity to cavity difference ~0.3 degrees, possibly microphonics. Drift <0.7 degrees over 7 hours – probably dominated by real cavity to cavity variations. Cable length change of 10 degrees results in <0.25 degree (consistent with 0) change in measured phase 4/24/2006 Marc Ross - SLAC
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ESA/LCLS bunch length monitor
This is a ‘single-pass’ device – intended as a ‘relative’ monitor to complement LOLA Two devices to be built for LCLS BC1 Deadline November 2006 Testing until November 2007 ‘CSR’ or focused wave (BL11) and gap monitor (BL12) Both may use pyroelectric devices Beam tests in ESA this month Accurate mm-wave measurements are difficult Full system relies on integration with LOLA (29-4) No LOLA in ESA 4/24/2006 Marc Ross - SLAC
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BL12 Bunch Length Monitor
Located just after the BL11 monitor Uses gap and diode detectors Only vacuum component is conventional ceramic gap Initially instrument with 100GHz diodes Add higher frequency diodes as needed Diodes used in pairs to reduce effect of beam motion 20cm waveguide used to disperse pulse (~1ns), keep peak power reasonable on diodes. 20dB gain horns on diodes 4/24/2006 Marc Ross - SLAC
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BL12 4/24/2006 Marc Ross - SLAC
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BL12 Development Plan Similar diodes operating at 100GHz have been tested in End Station B. Additional test in end station B in April 2006, using same electronics as LCLS Will use pair of diodes to check measurement noise. Initial test in LCLS will be done with a pair of 100GHz detectors. As shorter bunch length measurements are required, additional diodes and waveguide can be added Use of optical breadboard makes installation of new diodes (on optical clamp mount) straightforward. Will try using a pyroelectric detector mounted next to the gap. Should be able to measure total mm-wave power, and compare with toroid current measurement to get bunch length signal Very simple and inexpensive system if it works. In principal extends to very short bunch lengths Must be calibrated with LOLA 4/24/2006 Marc Ross - SLAC
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ESA Bunch Length Monitor
simple ceramic gap and diode detector diode and waveguide form crude bandpass filter 200 to 400 um bunch length sensitivity (ILC) Two 100 GHz detectors track with RMS error of 1.5% 100GHz Diode, WR10 waveguide and horn WR10 and WR90 waveguides at ceramic gap 4/24/2006 Marc Ross - SLAC
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Summary – ongoing work and developments since April 2006
ATF cavity BPM’s (UK, UCB, LLNL, KEK) Near a spectrometer result with 2 triplets+1 (?) Nanogrid tests – first results ATF2 BPM cavities (Pohang, KEK, UCL) 1/3 copper cavities done Electronics delayed 2 months system issues ATF extraction kicker (LLNL, KEK) delivered in June To be used in September 2006 TTF HOM (DESY, KEK, Saclay, FNAL) System implementation in August Phase measurements excellent (April 21) LCLS BLM first results in May
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