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Proposal to use electromagnetic correction coils for RT trajectory correction.

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Presentation on theme: "Proposal to use electromagnetic correction coils for RT trajectory correction."— Presentation transcript:

1 Proposal to use electromagnetic correction coils for RT trajectory correction

2 Proposal to use electromagnetic correction coils for RT trajectory correction HS, module review Sept 2009

3 HS, module review 9-2009 Background (1/2) 4000 MB quads, need about 80 correctors close to quads for beam-based feedback (BBF); Pre-choice of 80 locations impossible?  equip all 4000 quads with correctors Frequency range covered by BBF: sub-Hz to ~1 Hz In order to - have some feedback gain at f_cl =1 Hz (f_cl = f_s/gain) - to average over several BPM readings the BBF will run at a sampling frequency f_s=50 Hz; i.e. the corrections are applied every pulse: requested settling time of corrections is 5 ms ( in-between 2 beam pulses )

4 HS, module review 9-2009 Background (2/2) Technical implementation in 2008: - additional windings onto quad jokes in order to produce “a sort of dipole correction field” Pre-Choice of non-laminated MB quads for stabilization and mechanical engineering (late 2008) excludes correction coil (bandwidth problem) Present design approach: Extend dynamic range of stabilization actuators by 100 ! and make BBF corrections by displacing the MB quads. Fullscale = +- 5 um compared to +- 50nm

5 HS, module review 9-2009 Problems with present implementation Actuator dynamics, in particular for the (long) heavy magnets Absolute position of quad in beam reference frame not know (Hexapod design with sub-nm position readout in each leg) BPMs (50 nm required resolution) will move with quad. Needs sophisticated bookkeeping of past displacements. BPM close to “zero” and for longer elongations non- linear (monopole and quadrupole mode signals) Machine protection: non-energized position of quad (vertical) is max.down, not middle; might need interlocks.

6 HS, module review 9-2009 Implementation Required corrector strength (Bdl): 200 T/m *10 um * 2m (@ 1.5 TeV) = 4 mT * m = 0,4 T * 1 cm -  very week magnet assumed strength: scales with length of Q   corrector@ Q1: 0,1 mTm 1 cm long 0.1 - 0.4 T magnets - end-field problems? - interference with quad field? - will create synchrotron radiation? (200 times higher bending radius)

7 HS, module review 9-2009 First sketch ( after discussion with Michele Modena and Alexey Vorozhtsov) BPM QUAD The present space reservation in the module integration includes the space for the coils. Close to the beampipe there is 2-3 cm free space Small window frame magnet or a variant with magnetic shielding towards the quad can go into that free space. Alexey will make a first design …

8 HS, module review 9-2009 Conclusions The presently proposed solution for high excursion piezo actuators for BBF and Stabilization will possibly work, but it has several known (and unknown) complications. A simple proposal of small electromagnets for the BBF will decouple BBF and stabilization. The stabilization equipment can then be optimized for its original task. Having positive answers to the questions of: - extra synchrotron light at high energies? (when) - a preliminary magnet design (1 month) this option should become our CDR baseline.

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