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CEPC DA due to magnets' error Sha Bai, Dengjie Xiao, Yiwei Wang, Huiping Geng, Dou Wang, Tianjian Bian, Feng Su, Jie Gao The first IHEP-BINP CEPC Accelerator.

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Presentation on theme: "CEPC DA due to magnets' error Sha Bai, Dengjie Xiao, Yiwei Wang, Huiping Geng, Dou Wang, Tianjian Bian, Feng Su, Jie Gao The first IHEP-BINP CEPC Accelerator."— Presentation transcript:

1 CEPC DA due to magnets' error Sha Bai, Dengjie Xiao, Yiwei Wang, Huiping Geng, Dou Wang, Tianjian Bian, Feng Su, Jie Gao The first IHEP-BINP CEPC Accelerator Collaboration Workshop 2016-01-12 Institute of High Energy Physics Chinese Academy of Sciences Budker Institute of Nuclear Physics

2 Error study motivation To provide physical design for magnet manufacture, including bending magnet, quadrupole, sextupole and correctors……, and also the magnet alignment during installation. To give the optimal DA after error correction.

3 From: LEP Design Report---------LEP2 P177 LEP Alignment parameters

4 Magnet Field error 1 From: LEP Design Report---------LEP P18

5 Magnet Field error 2 From: LEP Design Report---------LEP P19

6 Magnet Field error 3 From: LEP Design Report---------LEP P19

7 bendquadsextbendquadsext Dx(mm)0.20.15 0.30.10.15 Dy(mm)0.20.15 0.20.10.15 Tilt(mrad)0.10.20.50.1 0.5 B*L3e-4 2e-35e-4 4e-3 quadrupole (s) 3e-48e-4 sextupole(s) 6e-45e-52e-46e-4 Octupole(s) 7e-56e-47e-55e-41.7e-3 Decapole(s) 5e-49e-52e-41.3e-46.9e-43.4e-3 Dodecapol e(s) 6e-45e-41.4e-41e-36.5e-3 Quadrupol e(r) 1e-43e-42e-4 Sextupole(r) 1e-4 3e-32.9e-41.2e-3 Multipole(r) 1e-4 3e-42e-41e-32e-2 BEPCIICEPC

8 CEPC DA with misalignment errors Without errorWith dipole misalignment With sextupole misalignment With quadrupole misalignment Coupling factor  =0.003 for emitty

9 With only horizontal misalignment in quads main ring without FFS with only vertical misalignment in quads, there is no orbit.

10 Quadrupole alignment error analysis main ring without FFS DX, DY, DS=7e-5, beyond this, orbit disappear. DX, DY, DS=1e-5

11 Main error source Horizontal and vertical misalignment in Quadrupoles Quadrupoles with their centers misaligned to the reference orbit cause dipole error, which will cause an angular deflection of the beam, causing the closed orbit to oscillate around the design orbit. Move the tune far from the resonance line Reduce the error source Solution

12 Orbit correction result in CEPC main ring without FFS without pretzel Before correction After correction

13 BPM readings statistics X CORRECTION SUMMARY: RMS before correction 2.020892 mm RMS after correction 0.009701 mm Y CORRECTION SUMMARY: RMS before correction 1.520581 mm RMS after correction 0.006212 mm

14 Orbit correction result in CEPC main ring without FFS with pretzel  After orbit correction, pretzel orbit can be recovered. Target pretzel orbitPretzel orbit after correction

15 Correctors strength statistics X CORRECTION : 1800 correctors used Max strength ~ 43urad RMS ~ 3.9urad Y CORRECTION: 1800 correctors used Max strength ~ 16urad RMS ~ 3.7urad

16 Misalignment error analysis – whole ring DA with 10 -4 m quad misalignment error Horizontal orbit with 10 -4 m quad misalignment error Vertical orbit with 10 -4 m quad misalignment error DA with 10 -15 m quad misalignment error Horizontal orbit with 10 -15 m quad misalignment error Vertical orbit with 10 -15 m quad misalignment error

17 Misalignment error analysis – FFS & ring DA with 10 -4 m FFS quad misalignment error Horizontal orbit with 10 -4 m FFS quad misalignment error Vertical orbit with 10 -4 m FFS quad misalignment error DA with 10 -4 m ring quad misalignment error Horizontal orbit with 10 -4 m ring quad misalignment error Vertical orbit with 10 -4 m ring quad misalignment error

18 CEPC DA with field errors two multipoles at each side of quadrupole model in SAD(with only ¾ ring) With ¾ ring (B,Q,S) B*L errors2% (1 σ x, 3.5 σy ) With ¾ ring (B,Q,S) B*L and multipole errors 1.5%, 2% (0, 0) Coupling factor  =0.003 for emitty

19 CEPC DA with field errors two multipoles at each side of quadrupole model in SAD(with only ¾ ring) With all FFS B*L and multipole errorsenlarge with ¾ ring and FFS (B,Q,S) B*L errors & multipole errors Coupling factor  =0.003 for emitty 1.5%, 2% (0, 0)

20 Magnet field error on DA Quad and Sextupole are set to be MULT model in SAD (whole ring including FFS) With Bend B*L error (whole ring including FFS) μx= 0.0720634 μy= 0.2261286 Orbit in X & Y With Bend B*L error (whole ring including FFS) With Quad B*L error (whole ring including FFS) μx= 0.0815080 μy= 0.1937457 With Sext B*L error (whole ring including FFS) Tune no change With Bend magnet field errors, orbit is changed, and tune is also changed a little bit Orbit correction is needed With Quadrupole and sextupole field errors, orbit has no change. With Quad field errors, tune is change. Bend is set to be bend, but Quad and Sextupole are set to be MULT Tracking in 240 turns, coupling factor κ=0.003 for ε y

21 Magnet field error on DA Quad and Sextupole are set to be MULT model in SAD (whole ring including FFS) With all (B,Q,S) B*L field errors, whole ring including FFS. Tune has changed a lot: μ x =0.0510854 μ y = 0.1526778 Orbit correction and tune adjust are needed Bend set to bend, and Quad and Sext set to be MULT in SAD Tracking in 240 turns, coupling factor κ=0.003 for ε y

22 Multipole errors effect on DA quadrupole/sextupole multipole model in SAD Bend multipole errors (whole ring including FFS) Quad multipole errors (whole ring including FFS) Sextupole multipole errors(whole ring including FFS) (B,Q,S)multiple errors (whole ring including FFS) Off-momentum DA is not changed obviously, with 2% (1σ x, 10σ y ) Tune is kept, no effect on tune Orbit is kept to be zero, no effect on orbit Bend is set to be bend, but quadrupole and sextupole are set to be MULT When bend set to be MULT, it doesn’t work in SAD Tracking in 240 turns, Coupling factor  =0.003 for emitty

23 Multipole error analysis quadrupole/sextupole multipole model in SAD (B,Q,S)multipole error 10 -4 (order of magnitude) (B,Q,S)multipole error 5x10 -5 (order of magnitude) (B,Q,S)multipole error 10 -5 (order of magnitude) Multipole error can not be corrected. The DA due to multipole error can be only depended on the DA which is without error The magnet design requirement is from: the maximum DA limit. If the maximum DA limit is not satisfied, we can reduce the multipole error, this may put forward higher requirements on the magnet design

24 Tune correction globally DA with Quad B*L errorDA after tune correction globally With all quad B*L errors in CEPC whole ring including FFS, correct tune of whole ring with the six quads in straight line Dynamic aperture is not improved Reason: the quad B*L error destroy the period and the chromaticity correction. Solution: correct tune in part, both in cell and straight line, refit sextupole to do chromaticity correction

25 CEPC field error summary The multipole errors in the main ring seems to have a large effect on the 2% off-momentum DA. The field errors in the FFS seems to have a large effect on the vertical on-momentum DA. With all B,Q,S multipole errors in CEPC whole ring including FFS, the 2% off-momentum DA reduced to about 1/3~1/2. Method 1 : Optimization of DA (precondition: best DA without error )  orbit correction ( for misalignment errors )  tune correction ( for quad B*L error )  FMA analysis, add octupole, decapole, dodecapole……. Method 2 : Reduce errors (maybe high level requirement in magnet manufature ) reduce the errors to the DA that we can accept Although could be corrected in simulation, may not the case in real situation…… Cure DA

26 Error correction Misalignment & bending magnet strength error Quad strength error Multipole error Orbit correction with correctors & BPM Tune correction & chromaticity correction Impossible to correct & adjust level to requirement

27 Magnet requirement in manufacture common level of magnet manufacture in world The misalignment for dipole, quadruple and sextupole could be dozens of microns (30 microns is high level) Corrector dipoles requirement : uniformity of magnetic field ~ 1% No requirement on magnet field strength error (since could be tuned by current) Multipole error at a level of 2e-4 is the best, different order has difference, lower order is more difficult.

28 Summary Misalignment errors ~ 10 -4 m of CEPC main ring without FFS could be corrected by adding correctors and BPMs. For whole ring with FFS, situation could be complex, but needs to be tried to do orbit correction. With correctors and BPMs adding in the beam line, SAD harsh table has no space. SAD can not deal with large ring. MAD can’t give correct DA. We have to change to other program. Tune correction and chromaticity correction are not needed for magnet design requirement, but needs to do in DA optimization. Multipole errors can not be corrected in real situation, it depends on the DA optimization without errors, but the results are not unbearable with 2% reduced to about 1/3~1/2.

29 Thank you !

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