Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III.

Published byAnnabelle Douglas Modified over 8 years ago

Similar presentations

Presentation on theme: "1 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III."— Presentation transcript:

1 1 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III. Study plan IV. Study results Gradient study for near quench limit operation Klystron output linearization RF operation near klystron saturation V. Summary and future plan

2 R&D results (upto Feb. 2012) High beam power and long bunch-trains (Sept 2009) MetricILC Goal Achieved Macro-pulse current9mA (5.8mA)9mA Bunches per pulse2400 x 3nC (3MHz)1800 x 3nC 2400 x 2nC Cavities operating at high gradients, close to quench 31.5MV/m +/-20%4 cavities > 30MV/m Gradient operating margins (updated following Feb 2012 studies) MetricILC Goal Achieved Cavity gradient flatness (all cavities in vector sum) 2%  V/V (800  s, 5.8mA) (800  s, 9mA) <0.3%  V/V (800  s, 4.5mA) First tests of automation for Pk/Ql control Gradient operating marginAll cavities operating within 3% of quench limits Some cavities within ~5% of quench (800us, 4.5mA) First tests of operations strategies for gradients close to quench Energy Stability0.1% rms at 250GeV<0.15% p-p (0.4ms) <0.02% rms (5Hz) LCWS12(Sep.24) Shin MICHIZONO 2

3 3 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III. Study plan IV. Study results Gradient study for near quench limit operation Klystron output linearization RF operation near klystron saturation V. Summary and future plan

4 Study items for ILC  High beam current  From 4.5 mA (Feb. 2012) to 6 mA  Gradient study for near quench limit operation  PkQl control was carried out on Feb. 2012.  In February, we had some cavities within 10% of quench, ILC design parameters assume all cavities operate within 5% of quench  Klystron output linearization  To operate the klystron near saturation, linearization would be essential for high gain feedback operation.  RF operation near klystron saturation  In February, we got to within 7% of the saturation power by reducing the klystron anode voltage  The ILC design assumes 5% power overhead  Combination of these results  High beam (6 mA), rf operation near saturation, cavity gradient near quench limit 4 LCWS12(Sep.24) Shin MICHIZONO

5 5 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III. Study plan IV. Study results Gradient study for near quench limit operation Klystron output linearization RF operation near klystron saturation V. Summary and future plan

6 Intended studies program Sep. 17 Mon Sep.18 Tues Sep.19 Wed Sep.20 Thurs Sep.21 Fri Sep.22 Sat MSwitch to 3MHz/5Hz Set up long fill time, flat rf pulse Gradient studies Integrate main studies tracks, with goal of high current operation close to quench with klystron saturation ASet up machine with high charge long pulses Set up long fill time, flat rf pulse Klystron saturation studies NTuning towards 6mA, 2400 bunches Saturation studies, machine tuning 6 LCWS12(Sep.24) Shin MICHIZONO

7 Actual studies Sep. 17 Mon Sep.18 Tues Sep.19 Wed Sep.20 Thurs Sep.21 Fri Sep.22 Sat MSwitch to 3MHz/5Hz Set up long fill time, flat rf pulse Gradient studies Integrate main studies tracks, with goal of high current operation close to quench with klystron saturation ASet up machine with high charge long pulses Set up long fill time, flat rf pulse Klystron saturation studies NTuning towards 6mA, 2400 bunches Saturation studies, machine tuning 7 Klystron studies Gradient studies (partial) Gradient studies (partial) Klystron studies (partial) RF studies (waiting for beam) LCWS12(Sep.24) Shin MICHIZONO About 6 shifts were available and these were not sufficient to complete the studies.

8 FLASH layout 315 m Bunch Compressor Bypass Undulators sFLASH Bunch Compressor 5 MeV160 MeV500 MeV1200 MeV Accelerating StructuresDiagnostics FEL Experiments ACC6&7 (total 16 cav.) LCWS12(Sep.24) Shin MICHIZONO 8

9 9 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III. Study plan IV. Study results Gradient study for near quench limit operation Klystron output linearization RF operation near klystron saturation V. Summary and future plan

10 Cavity gradient tilts from beam loading 10 A ‘feature’of running cavities with a spread of gradients when the are all fed from same RF source Solution: adjust individual Pks and Qls so each cavity is ‘matched’ for the same beam current Steady-state cavity voltage (Note: Vector Sum is constant) Ratios of power required by each cavity are different between beam off and beam on Klystron power increases linearly with beam current Higher gradient cavities get too much extra power Lower gradient cavities get not enough extra power Must be solved uniquely for a given beam current and set of gradients LCWS12(Sep.24) Shin MICHIZONO

11 Time [usec] ABC ILC: 9mA @ FLASH: Gradient Study Results from FLASH 9mA study (Feb. 2012): I beam = 4.5 mA Results from FLASH 9mA study (Sep. 2012): QL optimization algorithm now includes exception handling (Piezo, Ql,…) Still not fully understood about optimization procedure (next study): AB C short bunch train default Q L = 3x10 6 short bunch train optimized Q L long bunch train optimized Q L 400 usec 800 usec LCWS12(Sep.24) Shin MICHIZONO 11

12 12 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III. Study plan IV. Study results Gradient study for near quench limit operation Klystron output linearization RF operation near klystron saturation V. Summary and future plan

13 One of the key assumption for ILC design is to operate the RF station near to klystron saturation region (about 5% below hard saturation). In order to determine such inconvenient range of operation (where gain rapidly decreases to 0) the set of measurement has been performed to characterize system behavior (gain change) in function of controller (input) signal change. Measured input-output characteristics of klystron Transfer characteristics achieved for high power chain for modules ACC67 @ FLASH (for reduced cathode voltage value =~86kV) revealed saturation points for given controller output level. As the nonlinearity and saturation issue is only signal amplitude level dependent – figures shows measured dependence between controller signal amplitude and klystron output (for amplitude and phase). It has to be emphasize that transfer characteristics includes not only klystron behavior but also gain and phase modification caused by preamplifiers. LCWS12(Sep.24) Shin MICHIZONO 13

14 Linearization tool concept and implementation The nonlinearities identified during the system characterization has been used to find inverse function that is described in look-up tables in LLRF controller (FPGA side). The LUT table is indexed by calculated controller signal amplitude. Complex multiplication of the control signal with correction signal from LUT's result in corrected signal generation. This signal is amplified by nonlinear klystron and is distributed. linearization LCWS12(Sep.24) Shin MICHIZONO 14 Correction inside digital system

15 The results of linearization achieved during last high beam current studies at FLASH (RF station for accelerating modules ACC67 – 10 MW klystron) (red characteristics). Linearization results Proposed and implemented method allowed for klystron behavior linearization. Although some system weak points can be recognize (eq. poor phase detection for low signal levels) amplitude and phase characteristic correction can be considered as satisfactory. The main benefit of constant gain maintenance can be clearly noticed especially for operation with wide working point range (eq. high feedback gain control). LCWS12(Sep.24) Shin MICHIZONO 15

16 16 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III. Study plan IV. Study results Gradient study for near quench limit operation Klystron output linearization RF operation near klystron saturation V. Summary and future plan

17 LCWS12(Sep.24) Shin MICHIZONO 17

18 18 Preparation for saturation study LCWS12(Sep.24) Shin MICHIZONO -0.3dB beam We adjust filling time (550 us or 590 us) to have a flat rf output at 5.2 mA (800 us). We decrease HV of the klystron to operate near saturation. ILC specification requires to operate -0.22dB (-5%) from saturation. Artificial step is introduced to confirm the saturation point during rf pulse Beam profile RF output Filling beam Beam current is ~20% different during pulse. Further study will be necessary with flat beam

19 19 Measured stability LCWS12(Sep.24) Shin MICHIZONO -0.3dB -0.2dB beam RF output with artificial step nominal -0.3dB operation -0.2dB operation Vector sum amplitude [arb.] Vector sum phase [deg.] Stability just after the beam is insufficient probably due to the limited FB gain. Further study will be necessary. with longer time (> hours), higher gain

20 20 Amp., phase, beam energy, current are compared. (initial 200us of pulse) VS amplitudes at the beginning of -0.3dB and -0.2dB show some slope due to the limited beam loading suppression. -> Further study will be necessary. 150 pulse envelope LCWS12(Sep.24) Shin MICHIZONO Nominal -0.3dB operation -0.2dB operation with gap without gap - VS amplitude VS phase Beam Energy Beam current 0.4% 0.5deg. 2MeV 5.5mA 5mA 4.5mA “nominal” and “-0.3dB” have a gap between filling and beam. “-0.2dB” has no gap between filling and beam. -> response is opposite.

21 Summary and future plan Several studies have been carried out at FLASH for technical demonstration of ILC specification. PkQl control (Ql adjustment) for near quench limit operation Klystron linearization and rf operation near saturation High current beam loading with long bunch train. For the engineering phase (post TDR), we need to accumulate more experience for stable operation. XFEL and ILC have many common study items because of the similar beam parameters. Further studies will be necessary. LCWS12(Sep.24) Shin MICHIZONO 21 FLASH (10% of XFEL) FLASH (10% of XFEL) EU-XFEL (10% of ILC) EU-XFEL (10% of ILC) ILC Operate FLASH as if it were XFEL Operate EU- XFEL as if it were ILC EU-XFELILC (250GeV) Gradient23.6 MV/m31.5 MV/m +-20% Bunch charge1 nC3.2 nC Beam current5 mA5.8 mA Energy stability2.5MeVrms/20GeV (0.013%) 0.1% rms -> strategy for automation (reach near quench limit without exceeding etc.) -> Beam energy stability, long term stability with flat beam current -> High beam, high gradient, near klystron saturation study

Download ppt "1 9 mA study at FLASH on Sep., 2012 Shin MICHIZONO (KEK) LCWS12(Sep.24) Shin MICHIZONO Outline I.Achievement before Sep.2012 II.Study items for ILC III."

Similar presentations

Tom Powers Practical Aspects of SRF Cavity Testing and Operations SRF Workshop 2011 Tutorial Session.

Tom Powers Practical Aspects of SRF Cavity Testing and Operations SRF Workshop 2011 Tutorial Session.
11/27/2007ILC Power and Cooling VM Workshop Mike Neubauer 1 RF Power and Cooling Requirements Overview from “Main Linac Power and Cooling Information”

11/27/2007ILC Power and Cooling VM Workshop Mike Neubauer 1 RF Power and Cooling Requirements Overview from “Main Linac Power and Cooling Information”
J. Branlard ALCPG11 – 19-23 March 2011 – Eugene OR, USA Results from 9mA studies on achieving flat gradients with beam loading P K |Q L studies at FLASH.

J. Branlard ALCPG11 – March 2011 – Eugene OR, USA Results from 9mA studies on achieving flat gradients with beam loading P K |Q L studies at FLASH.
1 STF-LLRF system and its study plan Shin MICHIZONO (KEK) LCWS12 STF-LLRF Outline I.STF system configuration S1-Global (~2011 Feb.) Quantum Beam (QB) (2012.

1 STF-LLRF system and its study plan Shin MICHIZONO (KEK) LCWS12 STF-LLRF Outline I.STF system configuration S1-Global (~2011 Feb.) Quantum Beam (QB) (2012.
Areal RF Station A. Vardanyan19.09.2012. RF System The AREAL RF system will consist of 3 RF stations: Each RF station has a 1 klystron, and HV modulator,

Areal RF Station A. Vardanyan RF System The AREAL RF system will consist of 3 RF stations: Each RF station has a 1 klystron, and HV modulator,
Areal RF Station A. Vardanyan22.06.2012. RF System The AREAL RF system will consist of 3 RF stations: Each RF station has a 1 klystron, and HV modulator,

Areal RF Station A. Vardanyan RF System The AREAL RF system will consist of 3 RF stations: Each RF station has a 1 klystron, and HV modulator,
R. Corsini LCWS12 – Arlington 26 Oct. 2012 Summary of system tests R. Corsini, H. Hayano.

R. Corsini LCWS12 – Arlington 26 Oct Summary of system tests R. Corsini, H. Hayano.
April 25 2008 SCRF Meeting FNAL08 S.Fukuda 1 HLRF Summary and Work Assignment S. FUKUDA KEK.

April SCRF Meeting FNAL08 S.Fukuda 1 HLRF Summary and Work Assignment S. FUKUDA KEK.
ILC RF phase stability requirements and how can we demonstrate them Sergei Nagaitsev Oct 24, 2007.

ILC RF phase stability requirements and how can we demonstrate them Sergei Nagaitsev Oct 24, 2007.
RF Systems and Stability Linac Coherent Light Source Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator Center.

RF Systems and Stability Linac Coherent Light Source Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator Center.
Beam loading compensation 300Hz positron generation (Hardware Upgrade ??? Due to present Budget problem) LCWS2013 at Tokyo Uni., 11-15 Nov. 2013 KEK, Junji.

Beam loading compensation 300Hz positron generation (Hardware Upgrade ??? Due to present Budget problem) LCWS2013 at Tokyo Uni., Nov KEK, Junji.
Demonstration of the Beam loading compensation (Preparation status for ILC beam loading compensation experiments at ATF injector in this September) (PoP.

Demonstration of the Beam loading compensation (Preparation status for ILC beam loading compensation experiments at ATF injector in this September) (PoP.
Conventional Source for ILC (300Hz Linac scheme and the cost) Junji Urakawa, KEK LCWS2012 Contents : 0. Short review of 300Hz conventional positron source.

Conventional Source for ILC (300Hz Linac scheme and the cost) Junji Urakawa, KEK LCWS2012 Contents : 0. Short review of 300Hz conventional positron source.
1 Results from the 'S1-Global' cryomodule tests at KEK (8-cav. and DRFS operation) Shin MICHIZONO (KEK) LOLB-2 (June, 2011) Outline I. 8-cavity installation.

1 Results from the 'S1-Global' cryomodule tests at KEK (8-cav. and DRFS operation) Shin MICHIZONO (KEK) LOLB-2 (June, 2011) Outline I. 8-cavity installation.
DMCS W.Cichalewski Aug 17 th 1 FLASH - klystron 2 and klystron 5 nonlinearities and linearisation MSc Wojciech CICHALEWSKI.

DMCS W.Cichalewski Aug 17 th 1 FLASH - klystron 2 and klystron 5 nonlinearities and linearisation MSc Wojciech CICHALEWSKI.
Proposed machine parameters Andrei Seryi July 23, 2010.

Proposed machine parameters Andrei Seryi July 23, 2010.
TTF-II Status & Prospectives Nick Walker DESY 5 th ITRP Meeting – 28.06.04 CALTECH.

TTF-II Status & Prospectives Nick Walker DESY 5 th ITRP Meeting – CALTECH.
Grzegorz Jablonski, Technical University of Lodz, Department of Microelectronics and Computer Science XFEL-LLRF-ATCA Meeting, 3-4 December 2007 XFEL The.

Grzegorz Jablonski, Technical University of Lodz, Department of Microelectronics and Computer Science XFEL-LLRF-ATCA Meeting, 3-4 December 2007 XFEL The.
Proposed TDR baseline LLRF design J. Carwardine, 22 May 2012.

Proposed TDR baseline LLRF design J. Carwardine, 22 May 2012.
1 LLRF Pre-readiness review (26th May, 2009) 27/10/2015 LLRF performance and its limitation based on KEK's experiments Shin Michizono (KEK) KEK’s LLRF.

1 LLRF Pre-readiness review (26th May, 2009) 27/10/2015 LLRF performance and its limitation based on KEK's experiments Shin Michizono (KEK) KEK’s LLRF.

Similar presentations

Ads by Google