David Urner, Oxford University, RHUL – June 2005 1 StaFF Stabilization of Final Focus Motion Stabilization with Nano-Meter Precision David Urner Paul Coe.

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Presentation transcript:

David Urner, Oxford University, RHUL – June StaFF Stabilization of Final Focus Motion Stabilization with Nano-Meter Precision David Urner Paul Coe Armin Reichold Oxford University

David Urner, Oxford University, RHUL – June Task Development of active feedback systems for e.g. final focus quadrupoles or beam position monitors in the energy chicane. –Develop laser-interferometric methods to monitor relative position of 2 objects at nanometer scale at separations of order 10m. Timescales of Hz –Develop and implement algorithms for active stabilization. KEK: Integrated spectrum of vertical motion

David Urner, Oxford University, RHUL – June Measurement of Relative Motion Typical situation: –Need straightness monitor to measure relative motion. (Leave for development later). –Need distance meter to project out. (Develop first). Quadrupole ~10m Reference Structure Reference Structure Vertical & angular position measurement of ref. structure Straightness monitor to measure relative vertical movement between ref. structures

David Urner, Oxford University, RHUL – June A Straightness Monitor Made from Distance Meters Measure relative vertical motion of object A versus object B. (in fact measure 6D coordinates) A B

David Urner, Oxford University, RHUL – June A Straightness Monitor Made from Distance Meters Red lines: Michelson interferometer displacement meter nm resolution. Multilateration requires absolute distance meter with  m resolution: FSI. Both systems with same setup! A B

David Urner, Oxford University, RHUL – June A Straightness Monitor Made from Distance Meters Information related via central triangle Floor node A B Ceiling node 1

David Urner, Oxford University, RHUL – June A Straightness Monitor Made from Distance Meters 3 nodes on each object, with 3 distance meters to each triangle node Network has to be placed in vacuum tubes to achieve nm resolutions. Floor node A B Ceiling node 1

David Urner, Oxford University, RHUL – June Implement system at ATF/KEK relating positions of nano-BPM’s Advantage: –Nano-BPM have nm resolution: cross check of results –Test of distance meter in accelerator environment Nano-BPM Built by SLAC group Nano-BPM Built by KEK group

David Urner, Oxford University, RHUL – June Relevance of StaFF Experiment for Nano-BPM Studies Unfold nano-BPM resolution and broadening caused by mechanical relative motion between the two BPM setups. Each setup uses 3 BPM’s also establishing beam angles. Two sets can in principle measure relative displacements –Each beam bunch differs in position and angle → over- constrained system needed. 2-platform stability important for energy chicane –BPMs measure beam position, StaFF measures relative position motion.

David Urner, Oxford University, RHUL – June Spider web Design with Opto- Geometrical Simulation: Simulgeo

David Urner, Oxford University, RHUL – June Spider web Design with Opto- Geometrical Simulation: Simulgeo

David Urner, Oxford University, RHUL – June Spider web Design with Opto- Geometrical Simulation: Simulgeo Allows objects to be placed (6D) in hierarchal structure –Reference placements. –Fixed placements (with error). –Variible placements (the objects to measure). Objects can be points, mirrors, distance meters… –Distance meter assume measurement between points with error. Big matrix inversion takes into account all errors and constrains 6D position of all points.

David Urner, Oxford University, RHUL – June Spider web Design with Opto- Geometrical Simulation: Simulgeo Resolution of distancemeter: 1nm Mount precision of distancemeter: 1nm Angle precision of distancemeter holder: 10  rad. SLAC BPM: reference KEK BPM variable (6D): Position: x:32 y:19 z:2 nm Angle: x:0.01 y:0.01 z:0.1  rad ~1  m absolute distance resolution needed to determine constants required to solve geometry.

David Urner, Oxford University, RHUL – June Progress Since last Meeting Chose grid setup based on simulation results. Presented proposal for experiment at KEK. Started to setup first prototype of displacement meter. Started to design vacuum system.

David Urner, Oxford University, RHUL – June Some things we learned from the Simulgeo simulation Distance meter holder: SLAC BPM: reference KEK BPM variable (6D): Position: x:32 y:19 z:2 nm Angle: x:0.01 y:0.01 z:0.1  rad Distance meter holder Focusing optics Focusing optics Fiber inputs/outputs 1 cm Virtual spot - Virtual spot of 100  m: Angle precision of distancemeter holder: 10  rad. - Angle precision needed: 0.1  rad!!!

David Urner, Oxford University, RHUL – June Distance Meter Michelson at least 4 measurements to determine length of fringe spacing. –Imbalance of arm length requires very stability in frequency FSI: scan over large frequency range, count number of fringes and infer absolute distance. Collimating lens produces plane waves. Virtual spot can be achieved by dual lens system and cylindrical waves.

David Urner, Oxford University, RHUL – June Triangle Nodes Distance meter heads located in triangle nodes. Floor node –Overall resolution improves if firmly anchored. –Dome anchored separately from interferometers. Ceiling nodes: position stability unimportant. All triangle nodes –Angular stability of node needed to about 10  rad.

David Urner, Oxford University, RHUL – June BPM Nodes One wide angle retro- reflector (cateye) for each node –Removes angular stability problem for retro-reflector node. Challenges: –Relative position between retro-reflector needs to be known to 1nm Requires measurement between 3 nodes on each nano-BPM.(blue lines). –Attachment of vacuum lines to BPM’s Requires zero-force design.

David Urner, Oxford University, RHUL – June Steps needed to build an optical anchor R&D at Oxford: –Michelson Interferometer prototype in Lab. –FSI with same setup. –Build frequency stabilized laser. –Test zero force mounting mechanics prototype. –Design vacuum system. –Build triangle and BPM nodes ready for KEK. –Write algorithm and software for active stabilization. –Closing of feedback loop. R&D at KEK: –Run single arm prototype in accelerator environment. –Measure angular deflection of I beam. –Mount floor and BPM nodes. –Survey mounted nodes. –Mount vacuum tubes. –Install interferometer. –Setup and first test of system. Nov 05 Jun 06 Aug 05 Sep 05 Dec 05 Aug 06 Dec 06 Jan 06 Apr 06

David Urner, Oxford University, RHUL – June Stabilization Actively stabilize setup using input from interferometers: –Both Nano-BPM setups are mounted on actuators. –Use movers on SLAC setup for coarse angle adjustment. –Use piezo movers on KEK setup for small adjustments. We measure the relative motion of the two reference frames of the SLAC and KEK BPM’s –Closed loop feedback system relates the KEK reference bar to the KEK nano-BPM’s. –Independent information from relative motion measurement relating SLAC carbon fibre frame to the SLAC nano-BPM’s. –Overall feedback loop has to integrate 3 measurements! Hz (or preferably even slower) is unusual frequency range for feedback system and might require some fundamental study.

David Urner, Oxford University, RHUL – June An Interesting Stabilization Task Integrate information from StaFF and KEK stabilization feedback loop. Anticipate interesting effects if two feedback systems are combined BPM groups would like us to extend stabilization range into the hour range. We need help! –Simulation of double feedback system. –Development of algorithms, which are able to cancel slow drifts. KEK SLAC Closed loop feedback for each BPM Take into account relative motion Between BPM and tube

David Urner, Oxford University, RHUL – June An Interesting Stabilization Task Integrate information from StaFF and KEK stabilization feedback loop. Anticipate interesting effects if two feedback systems are combined BPM groups would like us to extend stabilization range into the hour range. We need help! –Simulation of double feedback system –Development of algorithms, which are able to cancel slow drifts KEK SLAC Closed loop feedback for each BPM Take into account relative motion Between BPM and tube

David Urner, Oxford University, RHUL – June An Interesting Stabilization Task Integrate information from StaFF and KEK stabilization feedback loop. Anticipate interesting effects if two feedback systems are combined BPM groups would like us to extend stabilization range into the hour range. We need help! –Simulation of double feedback system. –Development of algorithms, which are able to cancel slow drifts. KEK SLAC Closed loop feedback for each BPM Take into account relative motion Between BPM and tube