TC 25th October1 LHC Real-time requirements What is real-time? What is latency? The time between asking for something to be done and it being done The.

Slides:

Advertisements

Similar presentations

The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme.

Advertisements

20 September 2000 LHC slow timing implementations brainstorming on slow timing Wednesday 20 September M.Jonker.

Beam commissioning strategy Global machine checkout Essential 450 GeV commissioning System/beam commissioning Machine protection commissioning.

Chamonix 03 / Presentation 5.5 / J. Wenninger1 Orbit control for machine operation and protection Orbit control requirements Feedback performance.

BROOKHAVEN SCIENCE ASSOCIATES Abstract Magnetic Specifications and Tolerances Weiming Guo, NSLS-II Project In this presentation I briefly introduced the.

The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme.

Expected Quench Levels of the Machine without Beam: Starting at 7 TeV ? P. Pugnat CERN, Geneva, Switzerland LHC Project Workshop Chamonix XV, Tuesday 24.

Trajectory Correction and Tuning James Jones Anthony Scarfe.

Gek 16/6/041 ITRP Comments on Question 19 GEK 9/06/04 19) For the X-band (warm) technology, detail the status of the tests of the full rf delivery system.

ATF2 optics … 1 3 rd Mini-Workshop on Nano Project at ATF ATF2 optics, tuning method and tolerances of initial alignment, magnets, power supplies etc.

March 7, 2007 LET Issues (Cai/Kubo/Zisman) Global Design Effort 1 Low-Emittance Tuning Issues and Plans Yunhai Cai, Kiyoshi Kubo and Michael S. Zisman.

Fk. Bordry AB/PO Ability of the converter s to follow the reference function (static, dynamics) I1 I2 I3 Static part is covered by the static definition.

Feed forward orbit corrections for the CLIC RTML R. Apsimon, A. Latina.

André Augustinus 17 June 2002 Technology Overview What is out there to fulfil our requirements? (with thanks to Tarek)

E. Todesco FIELD MODEL AT 7 TEV N. Aquilina, E. Todesco CERN, Geneva, Switzerland On behalf of the FiDeL team CERN, 17 th June.

Real time control Logical architecture Discussion of logical architecture of real time control systems M.Jonker.

Xiao-Yan Zhao Beam Instrumentation Group Accelerator Center, IHEP BEPCII Background Issues: Beam Loss Measurement.

RHIC Status: Startup Run 12 V. Schoefer RHIC Spin Collaboration Meeting 1/13/12.

LHC Collimation Project Integration into the control system Michel Jonker External Review of the LHC Collimation Project 1 July 2004.

ICALEPCS 2005 Advanced uses of the WorldFIP fieldbus for diverse communications applications within the LHC power converter* control system Quentin King.

Friday to Saturday 02:00: Machine closed. 09:00: Cryogenics all OK. Preparing pre-cycle. 10:00: Pre-cycle started. 11:30: Pre-cycle finished. 14:00: Beam.

NUCLOTRON CONTROL SYSTEM (NCS) V.Andreev, E.Frolov, A.Kirichenko, A.Kovalenko, B.Vasilishin, V.Volkov Laboratory of High Energies, JINR, Dubna.

Elias Métral, LHC Beam Commissioning Working Group meeting, 08/06/2010 /191 SINGLE-BUNCH INSTABILITY STUDIES IN THE LHC AT 3.5 TeV/c Elias Métral, N. Mounet.

R. Assmann - LHCCWG Two Beam Operation R.W. Aßmann LHCCWG Acknowledgements to W. Herr, V. Previtali, A. Butterworth, P. Baudrenghien, J. Uythoven,

Nominal intensity bunches ● First ramp with nominal intensity bunches suffered from an instability appearing around 1.8 TeV. ● Nominal intensity bunches.

Ramping & Snapback Andy Butterworth AB/RF Chamonix XIV 17 January 2005.

Fast feedback, studies and possible collaborations Alessandro Drago INFN-LNF ILCDR07 Damping Rings R&D Meeting 5-7 March 2007.

Analysis of Multipole and Position Tolerances for the ATF2 Final Focus Line James Jones ASTeC, Daresbury Laboratory.

Real time performance estimates of the LHC BPM and BLM system SL/BI.

1 Experience at CERN with luminosity monitoring and calibration, ISR, SPS proton antiproton collider, LEP, and comments for LHC… Werner Herr and Rüdiger.

Beam Dynamics WG K. Kubo, N. Solyak, D. Schulte. Presentations –N. Solyak Coupler kick simulations update –N. Solyak CLIC BPM –A. Latina: Update on the.

E. Todesco EXPERIENCE WITH FIELD MODELING IN THE LHC E. Todesco CERN, Geneva Switzerland Thanks to the FiDeL team CERN, Space charge th April 2013.

Proposal for a Global Network for Beam Instrumentation [BIGNET] BI Group Meeting – 08/06/2012 J-J Gras CERN-BE-BI.

Beam-beam compensation at RHIC LARP Proposal Tanaji Sen, Wolfram Fischer Thanks to Jean-Pierre Koutchouk, Frank Zimmermann.

Principals of fast injection and extraction R. Apsimon.

The Control System for the LHC tunnel cryogenics Controlling Cool Accelerators Controle da Criogenia de Aceleradores de Partículas Dr. Paulo Gomes CERN.

DRAFT: What have been done and what to do in ILC-LET beam dynamics Beam dynamics/Simulations Group Beijing.

TC 25th October1 Real-time A system -- e.g., application system, computer system, operating system -- operates in real time to the degree that those of.

AB-CO TC / J. Wenninger1 Real-time orbit the LHC Summary of the mini-workshop held Oct 6 th 2003 J. Wenninger AB-OP-SPS With emphasis.

Progress with Beam Report to LMC, Machine Coordination W10: Mike Lamont – Ralph Assmann Thanks to other machine coordinators, EIC’s, operators,

Tune: Decay at Injection and Snapback Michaela Schaumann In cooperation with: Mariusz Juchno, Matteo Solfaroli Camillocci, Jorg Wennigner.

Corrections for multi-pass eRHIC lattice with large chromaticity Chuyu Liu ERL workshop 2015 June 7, 2015.

4. Operations and Performance M. Lonza, D. Bulfone, V. Forchi’, G. Gaio, L. Pivetta, Sincrotrone Trieste, Trieste, Italy A Fast Orbit Feedback for the.

LHC machine protection close-out 1 Close-out. LHC machine protection close-out 2 Introduction The problem is obvious: –Magnetic field increase only a.

Measurement of LHC Superconducting Dipole and Quadrupole Magnets in Ramp Rate Conditions G.Deferne, CERN Aknowledgements: M. Di Castro, S. Sanfilippo,

LHC RT feedback(s) CO Viewpoint Kris Kostro, AB/CO/FC.

Collimation Aspects for Crab Cavities? R. Assmann, CERN Thanks to Daniel Wollmann for presenting this talk on my behalf (criticism and complaints please.

First evaluation of Dynamic Aperture at injection for FCC-hh

A monitoring system for the beam-based feedbacks in the LHC

High precision specification and test of power converters at CERN

J. Wenninger AB-OP-SPS for the non-dormant AB feedback team,

Sextupole calibrations via measurements of off-energy orbit response matrix and high order dispersion Nicola Carmignani.

LHC Commissioning with Beam

FiDeL: the model to predict the magnetic state of the LHC

New algorithms for tuning the CLIC beam delivery system

Results of the LHC Prototype Chromaticity Measurement

Status of Magnet Setup Cycling for LHC

Top-Up Injection for PEP-II and Applications to a Higgs Factory

Real-time orbit the LHC

Intensity Evolution Estimate for LHC

Limits on damping times

LHC OPERATION AND SUPPORT

450 GeV Initial Commissioning with Pilot Beam - Beam Instrumentation

Orbit Feedback / Chamonix 03 / J. Wenninger

Machine Tolerances in Cleaning Insertions

Aims for the week Recover from technical stop and precycle at 10A/s

Electron Rings Eduard Pozdeyev.

Collimators: Operations - Baseline Assumptions

Triplet corrector layout and strength specifications

Feedbacks & Stabilization Getting them going

Presentation transcript:

TC 25th October1 LHC Real-time requirements What is real-time? What is latency? The time between asking for something to be done and it being done The violation of one or more temporal constraints causes a loss of functionality. If it takes too long it don’t work. It ain’t necessarily speed.

TC 25th October2 Implications Front-ends Field bus Gateway Network Workstation Widely available industrial standards: ATM, WorldFIP, LynxOS, PowerPC which would satisfy LHC requirements (and in fact are already in use, planned to be used, or being used in prototypes.) E.g: Full ATM for LHC: 2M CHF Power converters Beam Instrumentation Reference magnets Real time To allow real time control/access of: But note: things are moving quickly out there

TC 25th October3 Why bother? 150 units of Q’ Large but reproducible, will clearly have to be measured Energy during injection plateau Orbit 1. Multipole errors

TC 25th October4 Control: assumptions Snap-back and low energy provide the challenge Nominal is the worse case... The “multipole factory” takes care of at least 80% of the effect i.e. –magnetic measurements –non-linear models –on-line reference magnets Characteristic frequency of snap-back slow & not changed by feed-forward from “multipole factory” Corrections to: horiz. orbit correctors (b1) & tuning quads. (b2) sextupole (b3) and decapole (b5) spool pieces Characteristic frequency is low 70 s

TC 25th October5 Beam parameter changes

TC 25th October6 Beam based feedback max rate db3/dt  units/second, units Q’/second  1 unit per second given the 80% from the magnet factory (NB out of tolerance in 1 second) Chromaticity is NOT an easy measurement and is not likely to be available for the physics beams (emittance growth). Available for pilots  reproducibility (again…) Tune & orbit we can do but b3: caveat...

TC 25th October7 So we have large multipole swings during the injection plateau and snapback... Beam stability will depend totally on –feed-forward from the reference magnets –feedback on the key beam parameters tune, orbit, energy, chromaticity Have to make a phase jump in our expected performance of a control system: –at present it is in the stone-age –have a look at synchrotron light sources to get an idea of what is possible... We will need similar to deal with multipoles, tight physics constraints & the low tolerance to beam loss.

TC 25th October8 LEP Orbit Maximum sampling frequency Hz LHC Orbit Proposed sampling frequency 10 Hz The stone age...

TC 25th October9 RT Requirements Reference magnets –feed-forward of corrections to machine Feedback-loops –Global Orbit –Local Orbit - e.g. orbit stability at collimators –Tune –Chromaticity Real-time knobs –typically tune, orbit bumps –extension of feedback, operator close loop, need... Display –Orbit –Beam loss (not for abort, but display & possible feedback) –Luminosity, Beam sizes, Lifetimes… Timing like actions (possibly) –e.g post-mortem trigger

TC 25th October10 RT requirements II Response limited by PC/magnet

TC 25th October11 Work in progress Power converters: –WordlFip 2.5 Mb/s + PowerPC/LynxOS gateway –already planning RT capabilities up to 100 Hz BPM/BLM –work in progress but use of RT functionality assume ATM prototyping –SPS Q-loop –LHC orbit correction simulation Requirements elucidated: –LHC report 221 “Requirements for real time correction…” –CO/OP forum –LHC-CP workshop –here...

TC 25th October12 SL-BI Two classes of instrumentation: global & local The global systems e.g. orbit and beam loss will provide the main control challenges:- Orbit: 10 Hz RT connection to PCR BLMs: 10 Hz RT connection to PCR (NOT to decide on beam abort) Local systems such as tune & chromaticity will be involved in RT feedback Proposed Architecture VME World FIP for RT Ethernet for off-line retrieval & Post-mortem Under discussion

TC 25th October13 Gateway MCCS Server ~80 Gateways ~1700 Digital Controllers Up to 30 Digital Controllers Per WorldFIP fieldbus RT LHC Network Major system - all magnets - set, ramp, trim etc. etc. Offering RT control at 100 Hz (whether you need it or not!) Digital controllers:- CERN design, manufactured by industry. Prototypes for String II. Gateways:- standard SL-CO - Power PC running LynxOS Fieldbus: WorldFIP from CEGELEC Timing: via an IRIG-B receiver card Power Converters

TC 25th October14 Reference magnets C MCCS Gateway Multipoles Factory DB I SM18 Magnet Test Benches WorldFIP fieldbus Real-time LHC controls network FB Power Converter Real-Time LHC Control System Instrumented Magnet 3-10Hz

TC 25th October15 SL-CO-FE - Real Time Investigating RT architectures –Front-ends, Networks –Prototype WorldFIP, FIP running LynxOS, ATM SPS as test-bed –Q-loop –LHC orbit correction simulation

TC 25th October16 Conclusions Demonstrable need for real-time control at the LHC Essential requirements established. Foresee dual system: –real-time for purposes outlined above –non-deterministic but high bandwidth for non-critical monitoring, command flow, post-mortem etc. etc. Accept RT is necessary, form WG under auspices of LHC- CP, ask them to investigate possible architectures… Much work already done in prototyping possible system, however technology choice can wait. Final architecture will clearly take into account such things as: –cost –reliability –maintenance

TC 25th October17 Acknowledgements Michel Jonker Pedro Ribeiro Thijs Wijnands Quentin King Alan Burns Oliver Bruning Luca Bottura Robin Lauckner