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Improving Collimator Setup Efficiency

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1 Improving Collimator Setup Efficiency
G. Valentino, R.W. Assmann, R. Bruce, F. Burkart, M. Cauchi, D. Deboy, S. Redaelli, A. Rossi, D. Wollmann. LHC Collimation Study Group, 1

2 Acknowledgements Collimation Team: R. Assmann, R. Bruce, F. Burkart, M. Cauchi, D. Deboy, A. Rossi, D. Wollmann. BE/OP: A. Macpherson, S. Redaelli, E. Veyrunes University of Malta: N. Sammut Gianluca Valentino

3 Outline Introduction Collimator Setup in 2011
LHC collimation system setup method Summary of collimation setups performed in 2011 Collimator Setup in 2011 Collimator Control software in 2010 Modifications to the software for 2011 Comparison of Collimator Setup Performance in 2010 and 2011 Measured beam size and gap offsets Time required for collimator setup Conclusions and Future Work Gianluca Valentino

4 Collimator Setup Procedure
Reference collimator 1 Collimator i 2 Reference collimator Collimator i BLM BLM Beam Beam 3 Reference collimator Collimator i Define beam edge by hor, ver or skew reference collimator Center collimator i Re-center reference collimator Beam size: Open collimator to BLM Beam Collimator i 4 Reference collimator BLM Beam D. Wollmann Gianluca Valentino

5 Collimator Setups Performed
Injection (450 GeV): 25/02/2011 – 01/03/2011 86 collimators 3.5 TeV Flat Top: 06/03/2011 – 08/03/2011 80 collimators 3.5 TeV after squeeze to beta* 1.5m / 10m / 1.5m / 1.5m: 11/03/2011 16 collimators 3.5 TeV during collisions: 11/03/2011 Gianluca Valentino

6 Collimator Control Application in 2010
Increment Jaw Position by clicking Apply! BLM Signal Chart (1 Hz, 1.3 sec running sum) Collimator Motor Positions Chart (1 Hz) S. Redaelli Gianluca Valentino

7 Collimator Setup in 2011 Modifications to original application from S. Redaelli done by G. Valentino, with input from R. Assmann, R. Bruce, S. Redaelli, and D. Wollmann. Main goals: Guarantee high quality of setup (independent of user) Reduce risk for human errors during the setup (unnecessary beam dumps) Optimize total setup time Reduce stress on users Gianluca Valentino

8 Semi-Automatic Feature
Introduction of a semi-automatic feature: Automatic step-wise movement of collimator jaws (can choose from 5 – 100 µm steps) The software automatically moves in the collimator until the resulting BLM signal exceeds a user-defined threshold. Gianluca Valentino

9 Initialization Procedure
Move collimators in parallel to the beam by class (TCSG, TCLA, TCT) and plane Limitation: Multiple Collimators stop moving! Gianluca Valentino

10 Setup Procedure Setup each collimator in sequence (define reference edge using TCP in plane) Threshold Interesting: See 40s decay of loss spike! Automatic stop after crossing BLM threshold Fine adjustment after initialization D. Wollmann Gianluca Valentino

11 Automatic Logging of Setup Data
Automatically log collimator setup data to file All user-generated events (initialization procedure, collimator movements) are saved No need for manual filling in of excel sheets Gianluca Valentino

12 Collimation Vistar Jaw Gap shown to scale
Improved Collimator fixed status display (available in the CCC and online) Modifications of the collimator status display by E. Veyrunes and S. Redaelli done by G. Valentino with input from collimation team and BE/OP Left Jaw Position in mm PRS status Right Jaw Position in mm MDC status Jaw Gap shown to scale Gianluca Valentino

13 Collimator Vistar Gianluca Valentino

14 Difference in Beam Offset: B1 2010 and 2011
Gianluca Valentino

15 Difference in Beam Offset: B2 2010 and 2011
Gianluca Valentino

16 Beam Size Ratio: 450 GeV B1 2010 vs 2011
2010 Average: 1.20 2010 Std Dev: 0.28 2011 Average: 1.10 2011 Std Dev: TCLA.B5R3.B1 TCSG.B5R3.B1 TCSG.5L3.B1 TCSG.A5R3.B1 TCSG.B5R3.B1 TCSG.4R3.B1 TCP.6L3.B1 σmeas. / σnominal Gianluca Valentino

17 Beam Size Ratio: 450 GeV B2 2010 vs 2011
2010 Average: 1.13 2010 Std Dev: 0.24 2011 Average: 1.10 2011 Std Dev: TCP.6R3.B2 TCSG.A5L3.B2 TCSG.A5L3.B2 TCSG.B5L3.B2 σmeas. / σnominal Gianluca Valentino

18 Beam Size Ratio: 3.5 TeV B1 2010 vs 2011
2010 Average: 1.21 2010 Std Dev: 0.22 2011 Average: 1.22 2011 Std Dev: Tilt in TCLA.A7R7.B1 Tilt in TCTH.4L2.B1 σmeas. / σnominal Gianluca Valentino

19 Beam Size Ratio: 3.5 TeV B2 2010 vs 2011
2010 Average: 1.10 2010 Std Dev: 0.24 2011 Average: 1.12 2011 Std Dev: Tilt in TCSG.A5L3.B2 σmeas. / σnominal Gianluca Valentino

20 Collimator Setup Time Comparison
The time taken to set up collimators is the most important indicator of the efficiency of a set up algorithm. Data from the logbook cross-checked with Timber. Average Time per Collimator = Time used for set up / Number of collimators Total Shift Time = Time used for setup + Time taken to get the LHC back to the operating point in case of a beam dump*. * For 2010, these values were taken from S. Redaelli’s Chamonix 2011 talk on “Optimization of the Nominal Cycle”. Gianluca Valentino

21 Collimator Setup Time Comparison
2010: 2011: Date Setup Type Avg Time / collimator (mins) Total Shift time (hrs) #beam dumps 05 – 07 May 450 GeV 5.34 8.35 1 12 – 16 Jun 3.5 TeV flat top 9.35 27.27 4 17 Jun 3.5 TeV squeeze 10.8 8.26 20 Jun 3.5 TeV collisions 8.48 Human Error: Jaws moved in based on rough idea of the orbit Date Setup Type Avg Time / collimator (mins) Total Shift time (hrs) #beam dumps 25 Feb - 1 Mar 450 GeV 12 18.52 2 6 –8 Mar 3.5 TeV flat top 13 17.77 11 Mar 3.5 TeV squeeze 5.5 3.5 TeV collisions 3.6 1.33 Gianluca Valentino

22 Beam Intensity at 3.5 TeV, 2010 vs 2011
2010: Rapid decrease in beam intensity during setup 2011: Gentle shaving of the beam Gianluca Valentino

23 Change of β-tron local cleaning inefficiency (3. 5 TeV, 1
Change of β-tron local cleaning inefficiency (3.5 TeV, 1.3s integration) D. Wollmann Gianluca Valentino

24 Conclusions New semi-automatic collimator setup tool works.
Quality of collimator setup compares well with last year. Improvement by factor ~1.5 in setup time at flat top. Improvement by factor ~5 in setup times for after squeeze and collisions. No dumps with new software. Ongoing work to improve the system, particularly setup time per collimator. Gianluca Valentino

25 Future Work: 30 Hz BLM Signal
Next year: 30 Hz BLM signal should increase the setup speed further. How can we exploit this as much as possible? This is related to ongoing work by F. Burkart on halo population studies. 40 seconds loss decay Gianluca Valentino

26 Future Work: Integrate code into OP software
Modifications were done in a copy of the collimation control software. Done to allow for testing and debugging of the new code while in parallel having a production version of the collimator control software available. New semi-automatic collimation software is now fully tested and has proven to be efficient in collimation setup. Collaborate with OP (S. Redaelli et al.) in implementing the modifications into the OP software. Gianluca Valentino

27 Other Future Work Identify automatically the collimator causing the loss signal during setup. Dynamic variation of step size, possibly helped by obtaining feedback from other BLM running sums. “Real-time” BLM signal loss simulator to test future setup algorithms. LHC MD time requested for testing new algorithms. Gianluca Valentino

28 END Gianluca Valentino

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