LHC Technical Committee, 28/03/2007

LHC Commissioning Phases

450GeV Initial Commissioning

presented by Rhodri Jones (AB/BI)

on behalf of the LHCCWG

Particular thanks to the A. Butterworth, B. Goddard,

W. Hofle, V. Kain, R. Steinhagen & J. Wenninger

LHC Technical Committee, 28/03/2007

LHC Commissioning Phases: Phase 3 – 450GeV Initial Commissioning

• Phase A.3: 450GeV Initial Commissioning– Objectives– Entry conditions– Preconditions and tools– Commissioning procedure– Exit conditions

• Summary

LHC Technical Committee, 28/03/2007

LHC Stage A: Commissioning phases

Phase Description

A.1 Injection and first turn:  injection commissioning; threading, commissioning beam instrumentation.

A.2 Circulating pilot: establish circulating beam, closed orbit, tunes, RF capture

A.3 450 GeV initial commissioning:  initial commissioning of beam instrumentation, beam dump

A.4 450 GeV optics: beta beating, dispersion, coupling, non-linear field quality, aperture

A.5 Increasing intensity: prepare the LHC for unsafe beam

A.6 Two beam operation - colliding beams at 450 GeV

A.7 Snap-back and ramp: single beam

A.8 Bringing beams into collision: adjustment and luminosity measurement

A.9 7 TeV optics: beta beating, dispersion, coupling, non-linear field quality, aperture

A.10 Squeeze: commissioning the betatron squeeze in all IP's

A.11 Physics runs: physics with partially squeezed beams, no crossing in IP1 and IP5

Phases for full commissioning Stage A (pilot physics run)

Basic Objectives:

• Continued RF commissioning• Initial commissioning of beam dump• Commissioning of beam instrumentation• To reach a lifetime > 1hr at 450GeV

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Overview of Steps Involved

• Steps 1 to 3 carried out with a single pilot bunch of 5×109

• Remaining steps carried out with a single intermediate bunch of ~ 3×1010

– higher precision on measurements & easier for BI commissioning

• All steps carried out first on one beam then on the other– same “experts” will be required for both systems

Step Activity

A.3.1 Final RF commissioning with Pilot Intensity

A.3.2 BPM Checks with Pilot Intensity

A.3.3 First Commissioning of the Beam Dumping System (pilot)

A.3.4 Commission beam instrumentation with higher intensity

A.3.5 Lifetime optimisation – to get to at least 1 hour

A.3.6 Further commission beam instrumentation with lifetime > 1hr

A.3.7 Further commission beam dumping system

A.3.8 Commission BI Feedback Systems

A.3.9 Start Commissioning of TCP Collimators

A.3.10 Rough Setting-up of Injection Protection Devices

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – entry conditionsBeam Entry conditions: • RF Captured• Beam circulating for hundreds of turns (orbit, tune & chromaticity coarsely adjusted)

Additional Hardware/Software Entry conditions:• Point 6, extraction channel

– Dry runs and 450 GeV reliability run completed• Collimator control system

– TCPs, TCDQ, TCSG and TDI moveable – Collimator movements for TCP, TCDQ, IR6 TCS, TDI hardware calibrated

• Inject & dump / circulate & dump modes available – both scenarios hardware commissioned – timing tables available – RF synchronisation hardware tested and available

• Additional RF Systems– Transverse damper available

• Additional Beam Instrumentation– BCTDC hardware available– Interlock BPMs in LSS6 available– Tune meter & tune hardware PLL available– Tune kicker & tune tickler hardware available– Head-Tail monitor available– Wire Scanner available– Abort Gap Monitor (BSRA) available

• Applications & controls– XPOC GUI and analysis package available in the control room – GUIs for all RF & BI instrumentation

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.1 – RF (Pilot)

Step Activity Priority

A.3.1 Final RF commissioning with Pilot Intensity.01 Check bunch 1 timing with revolution frequency and abort gap RF 1.02 Commission the transverse feedback for injection oscillations RF 1.03 Commission the wall current monitor for beam diagnostics RF 1

• Further RF commissioning– Details still to be presented at LHCCWG

• will be put on the agenda for a future meeting

• Transverse damper (some preliminary comments from W. Hofle)– As an exciter the damper system will be available from day 1– The damper pick-up electronics can be commissioned as soon as there

is circulating beam– Injection damping should only be attempted once

• a stable tune has been established• the phase advance between the damper pick-ups is reasonably well known

– These 2 conditions push this towards the end of this Stage

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.2 – BPM (Pilot)

Step Activity Priority

A.3.2 BPM Checks with Pilot Intensity.01 Time in the BPM system with respect to RF BI 1.02 Commission the real-time channel for continuous orbit measurement BI/OP 1.03 Rough calibration of BPM & corrector system ST/OP 1.04 Flatten orbit in injection regions and dumping region ST 1

• Time-in the BPM system with respect to RF– Adjust BST for all crates to get same turn on all systems– Put bunch 1 in bucket 1 for all channels (automatic but requires checks)– Adjust the 40MHz phase for each channel (automatic but requires checks)

• Commission the real-time channel for continuous orbit measurement– Orbit data concentration initially at 1Hz– First step in setting up orbit feedback

• Scan a few orbit correctors & acquire all monitors– Allows check on BPM quality and calibrations.– Measurements require only 4-20 correctors/plane/ring– Use response data for first rough linear optics check

• phase advance measurements are ‘lighter’ and faster to fit

• Flatten orbit in injection regions and dumping region

SPS example : before fitSPS example : before fit

(*) + line : modelHistogram : raw data

MDHD.118 MDV.121

Since the SPS lattice is very simple, the model tune is set far away (0.2) from the actual tune in the example to make life a bit more difficult for the fit.

Response for a horizontal and a vertical corrector (1% of the matrix).

J. Wenninger – LHCCWG June 2006

SPS example : a few fit iterations later…SPS example : a few fit iterations later…

MDHD.118 MDV.121

Histogram : gain corrected dataEmpty bin BPM rejected

(*) + line : fit model (17 MAD parameters) with calibrated kick

BPM and correctors are calibrated. Fitted model tunes exactly as expected ! Excellent agreement model-data.

Details on SPSresults can be found in

CERN-AB-2004-009

J. Wenninger – LHCCWG June 2006

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.3 – Beam Dump (Pilot)

Step Activity Priority

A.3.3 First Commissioning of the Beam Dumping System (pilot).01 Set mode circulate & dump (1 s delay - depends on lifetime?) ST 1.02 Set TCDQ and TCS in IR6 to ~10 using nominal optics & orbit info ST/OP/ATB 1.03 Check analogue signal from kicker trigger BPMs is correctly transmitted BI/BT 1.04 Adjust kicker timing with single pilot as bunch #1 BT 1.05 Aperture measurements with circulating beam OP 1.06 Commission dump line Beam Instrumentation BI 1.07 Check bunch dumped on TDE block BT 1

• Set TCDQ & TCS– Adjust to best guess 10 based on current optics model & measured orbit– Requires collimator controls & application

30 May 2006 B.Goddard ICFA-HB2006 11/26

Risk from particles in the abort gap

• Asynchronous beam dump or over-populated abort gap quench or damage– Several failures possible (synchronisation, MKD erratic, abort gap repopulation)

• Precautionary measures include:– Abort gap watchdog during the injection process, to inhibit injection with wrong phase– Abort gap monitor and possibility of abort gap cleaning– TCDS (fixed) – 6 m long diluter protects extraction septum– TCDQ/TCS (mobile) – 7 m long diluter kept at about 7-8 from the beam, at all times

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.3 – Beam Dump (Pilot)

Step Activity Priority

A.3.3 First Commissioning of the Beam Dumping System (pilot).01 Set mode circulate & dump (1 s delay - depends on lifetime?) ST 1.02 Set TCDQ and TCS in IR6 to ~10 using nominal optics & orbit info ST/OP/ATB 1.03 Check analogue signal from kicker trigger BPMs is correctly transmitted BI/BT 1.04 Adjust kicker timing with single pilot as bunch #1 BT 1.05 Aperture measurements with circulating beam OP 1.06 Commission dump line Beam Instrumentation BI 1.07 Check bunch dumped on TDE block BT 1

• Set TCDQ & TCS– Adjust to best guess 10 based on current optics model & measured orbit– Requires collimator controls & application

• Aperture Measurements – Horizontal aperture at TCDS entrance & MSD exit – Horizontal and Vertical aperture at MSD

• Commission dump line Beam Instrumentation– BLMs, BPMs, BTVs & FBCTs – check all beam-dependent transient signals are acquired correctly for XPOC

• Check position of bunch dumped– adjust energy tracking if needed local intervention to change EPROMS – adjust IPOC/XPOC references if needed

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.4 – BI (Pilot ++)

Step Activity Priority

A.3.4 Commission beam instrumentation with higher intensity ~ 3 x 1010

3.4.10 Full BCT Commissioning.11 Commission the BCTDC with beam to give acquisitions updates at 1Hz BI 1.12 Commission the Safe Beam Flag using the BCTDC measurement BI/OP/CO 1.13 Commission the BCTFR in bunch to bunch mode BI 1.14 Commission the Beam Presence Flag using BCTFR BI/OP/CO 1.15 Commission the BCTFR lifetime measurement BI 1.16 Cross calibrate the BCTDC and BCTFR BI 2

• Commission Safe Beam Flag using 1Hz BCTDC intensity measurement– Verify the generation & distribution– Verify the logic at the LHC master BIC concerning the LHC safe beam flag

• Commission the BCTFR in bunch to bunch mode– Set slot 1 to correspond to bunch 1– Adjust the phase of the acquisition

• Commission the Beam Presence Flag using BCTFR– Verify the generation & distribution

• Commission the lifetime measurement– Will use turn by turn data from the BCTFR to calculate the lifetime– Lifetime initially updated at 1Hz

Third LHC Project Workshop, January 2005 - Rhodri Jones (CERN - AB/BI)

Measurement Mode

Beam typeAccuracy/

Resolution

Fast BCT

(BCTFR)

DC BCT

(BCTDC)

Injection

Pilot bunch ±20% / ±20%±109

(OK)N/A

Nominal bunch

±3% / ±1%±3·109 / ±109

(OK)N/A

Circulating

Beam

(>200 turns)

Pilot bunch ±10% / ±10%±0.5·109

(OK)

1A (on 10A)

(resolution ~2-10A)

Nominal bunch

±1% / ±1%±109

(OK)

2A (on 180A)

(limit for short int time)

43 pilot bunches

±1% / ±1%±109

(OK)

2A (on 390A)

(limit for short int time)

Lifetime

Pilot bunch10%

(10hrs/1min)(OK) N/A

Nominal bunch

10%

(30hrs/10sec)(OK) N/A

Early LHC BCT System Performance

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.4 – BI (Pilot ++)

Step Activity Priority

A.3.4 Commission beam instrumentation with higher intensity ~ 3 x 1010

3.4.20 Tune Meter Commissioning.21 Commission single kick tune measurement using MKQ & BBQ BI/BT 1.22 Commission chirped tune measurement using BQK & BBQ BI 1.23 Commission chirped tune measurement using transverse damper BI/RF 2.24 Commission head-tail chromaticity measurement BI 1.25 Commission the BCTFR lifetime measurement BI 1

3.4.30 Initial BLM system commissioning.31 Adjust thresholds on "quench & learn basis" BI/ST 1.32 Lose / quench on purpose BI/ST 2

• Commission the Tune Meter– Time-in the MKQ tune kicker– FFT analysis after applied excitation

• MKQ – dedicated Q kicker• Chirp – either via BQK (BI tickler) or transverse damper

• Commission Head-Tail Monitor– In parallel to Tune Meter with MKQ excitation– Allows more precise chromaticity measurement

• Initial BLM System Commissioning– At this stage perform threshold adjustment on an “accidental quench & learn” basis– If quenches are very frequent then a more detailed study may be necessary

• determine quench level for type of magnet which is quenching by steering beam into magnet?

LHCCWG, April 2005 - Rhodri Jones (CERN - AB/BI)

BLM System at 450GeV

• Already Commissioned Hardware functionality & detector availability

• First Adjustment of Thresholds Initially set as factor 3 below estimated quench level at 450GeV

• Based on– simulations

– lab heating test measurements (SM18)

– possible sector test data

• Thresholds adjusted either on a– Quench & learn basis if too high

– Dump & learn basis if too low

• Threshold change procedure under discussion in MPWG

At 450GeV fast loss damage level is factor 1000 above quench level• No risk of damaging components

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.5 – Lifetime (Pilot ++)

Step Activity Priority

A.3.5 Lifetime optimisation – to get to at least 1 hour ~ 3 x 1010

.01 Adjust orbit, tune, chromaticity & coupling ST 1

• Lifetime Optimisation– Use commissioned beam instrumentation to achieve reasonable lifetime

• required for commissioning of remaining instrumentation• required for detailed optics measurements in next commissioning step

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.6 – BI (lifetime >1hr)Step Activity Priority

A.3.6 Further commission beam instrumentation with lifetime > 1hr ~ 3 x 1010

3.6.10 Systematic BPM & Corrector Calibration.11 Scan all orbit correctors and acquire all monitors - polarity and calibration BI 1

3.6.20 Commission PLL Tune & Coupling Measurement BI 1

3.6.30 Commission Wire Scanners BI 1

3.6.40 Commission Synchrotron Light monitors BI 1

.41 Commission the undulators ST 1

.42 Commission the abort gap monitor BI 1

.43 Commission the synchrotron light beam size monitor BI 23.6.50 Commission Rest Gas Ionisation Monitor BI 2

.51 Commission the gas injection system BI/VAC 2

• Systematic calibration of the BPMs & Correctors– Scan all orbit correctors and acquire all monitors

• ~30 s per COD (530 CODs per beam) ~1 shift per beam– Check response data for BPM & COD polarities and calibrations – Use response data for a more detailed linear optics check

• PLL– Requires BQK tune tickler or transverse damper in excitation mode

• Wire Scanners– May need to slow them down to get desired resolution on a single bunch

• 2m per second 180m per point

• Abort Gap– Commission the optics – will require tunnel intervention for fine adjustment– Define and check timing and injection bucket– Calibrate photon production versus proton number using a single bunch– Set threshold based on quench level in terms of protons/meter

LHC Machine Advisory Committee December 2006 - Rhodri Jones (CERN - AB/BI)

Abort Gap Monitor (BSRA)• System based on gated photomultiplier

• Tested in the SPS with synchrotron light source on fixed target beam Observation of injection kicker gap while beam is debunched before extraction.

• Worked extremely well

• Gain of photomultiplier is not as high as advertised Requires 15x more light

• For LHC a longer integration time is possible (every ms for SPS)

• BUT BSRA will require more light than anticipated at expense of BSRT

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.7 – Detailed DumpStep Activity Priority

A.3.7 Further commission beam dumping system ~ 3 x 1010

.01 Commission beam dependent interlocks ST/BI/CO 1

.02 Perform detailed aperture measurements around extraction region OP/BT 1

.03 Perform detailed aperture measurements in the dump line OP/BT 1

.04 Adjust fine kicker timing BT 1

• Commission Beam Dependent Interlocks– Verify beam position interlock in IR6 (set to dump at > 3.2mm)– Verify count rates on BLM monitors at TCDQ (hardware link to dump)

• Aperture Checks in IR6– H: TCDS entrance, MSD exit, TCDQ, TCS – H&V: MKD, MSD, TCDQM (retract TCDQ)

• Aperture Checks in the Dump Lines– Explicit check to ensure aperture is adequate for 14/15 MKD– Requires orbit bump in IR6 (cannot unplug 1 MKD)

• Adjustment of Fine Kicker Timing– 2 bunches (bunch 1 & 2808) to define abort gap

• Needs ‘new’ injection sequence and timing tables

– UA access will be required for each trim

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.8 – FeedbacksStep Activity Priority

A.3.8 Commission BI Feedback Systems ~ 3 x 1010

.01 Commission RF radial modulation RF 1

.02 Commission continuous chromaticity measurement BI 1

.03 Commission Orbit Feedback OP/BI 1

.04 Commission Tune & Coupling Feedbacks OP/BI 1

• Commission Continuous Chromaticity Measurements– Requires RF radial modulation to be operational (~1Hz modulation)

– Optimise PLL to track tune modulation of 1×10-4

• Commission Orbit Feedback– Use measured BPM & corrector calibrations

– Use “best guess” optics model• Convergence time (i.e. correction rate) will depend on accuracy of the model

• Commission Tune & Coupling Feedback– Verify trim quadrupole calibration (16 circuits per beam)

– Verify trim skew quadrupole calibration (12 circuits B1 & 10 circuits B2)

– Robust tune feedback requires coupling to be corrected!• Using commissioning tunes should help: 64.285/59.385

Third LHC Project Workshop, January 2005 - Rhodri Jones (CERN - AB/BI)

Measurement of Coupling using a PLL Tune Tracker (RHIC Example)

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Eigenmode 2

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Fully coupled Tunes entirely definedby coupling

LHCCWG, April 2005 - Rhodri Jones (CERN - AB/BI)

Coupling Feedback at RHIC (2006)

LHC Technical Committee, 28/03/2007

450GeV Initial Commissioning – Stage A.3.8 – FeedbacksStep Activity Priority

A.3.9 Start Commissioning of TCP Collimators ATB/OP 2

A.3.10 Rough Setting-up of Injection Protection Devices BT/OP 1

• Start the commissioning of some collimators (TCPs)– Find the orbit position at the primary collimators and assign the aperture

based on the best available optics estimates• Initial setting roughly 10 sigma

• Rough setting up of injection protection devices– Find the orbit position at the protection devices and assign the aperture

based on the best available optics estimates.

– Lock the orbit with orbit feedback

– Verify the centring of the TDI with circulating beam• requires masking of BLM thresholds at TDI

– Set TDI to 10 sigma with the measured optics information

– Set TCLI to 10 sigma with the measured optics information

LHC Technical Committee, 28/03/2007

Summary

• Phase A.3 :– from a few hundred turns of circulating beam to a lifetime > 1 hr.

• Main focus is on:– Continued RF commissioning– Initial beam dumping system commissioning– Full beam instrumentation commissioning

• Consensus is to include time for commissioning of feedbacks at this stage

• Ramp development is much easier if these feedbacks are operational

– Basic optics measurements

• At the end of this stage the machine should:– be ready for detailed optics measurements at 450GeV (next step)– have beam instrumentation and RF ready for ramping