The eleven main accelerating cavities of the Proton Synchrotron (PS) at CERN consist of two ferrite-loaded coaxial lambda/4 resonators each. Both resonators oscillate in phase, as their gaps are electrically connected by short bars. They are in addition magnetically coupled via the bias loop used for cavity tuning. The cavities are equipped with a wide-band feedback system, limiting the beam loading, and a further reduction of the beam induced voltage is achieved by relays
which short-circuit each half-resonator gap when the cavity is not in use. Asymmetries of the beam induced voltage observed in the two half-cavities indicate that the coupling between the two resonators is not as tight as expected. The total cavity impedance coupling to the beam may be affected differently by the contributions of both resonators. A dedicated measurement campaign with high-intensity proton beam and numerical simulation have been performed to investigate the beam-cavity interaction. This paper reports the result of the study and the work aiming at the development of a model of the system, including the wide-band feedback, which reproduces this interaction

Damerau, H.

FAVIA, GIORGIA

MIGLIORATI, Mauro

Morvillo, M.

Rossi, C.

English

The eleven main accelerating cavities of the Proton Synchrotron (PS) at CERN consist of two ferrite-loaded coaxial λ/4 resonators each. Both resonators oscillate in phase, as their gaps are electrically connected by short bars. They are in addition magnetically coupled via the bias loop used for cavity tuning. The cavities are equipped with a wide-band feedback system, limiting the beam loading, and a further reduction of the beam induced voltage is achieved by relays which short-circuit each half-resonator gap when the cavity is not in use. Asymmetries of the beam induced voltage observed in the two half-cavities indicate that the coupling between the two resonators is not as tight as expected. The total cavity impedance coupling to the beam may be affected differently by the contributions of both resonators. A dedicated measurement campaign with high-intensity proton beam and numerical simulation have been performed to investigate the beam-cavity interaction. This paper reports the result of the study and the work aiming at the development of a model of the system, including the wide-band feedback, which reproduces this interaction

Favia, Giorgia

Damerau, Heiko

Migliorati, Mauro

Morvillo, Michele

Rossi, Carlo

CERN Document Server

Study of the Beam-Cavity Interaction in the PS 10 MHz RF System

Archivio della ricerca- Università di Roma La Sapienza

STUDY OF THE BEAM-CAVITY INTERACTION IN THE PS 10 MHz RFSYSTEMG. Favia∗1,2, H. Damerau1, M. Migliorati2, M. Morvillo1, C. Rossi11CERN, Geneva, Switzerland2Sapienza Universita’ di Roma and INFN-Roma1, Rome, ItalyAbstractThe eleven main accelerating cavities of the Proton Syn-chrotron (PS) at CERN consist of two ferrite-loaded coaxiallambda/4 resonators each. Both resonators oscillate in phase,as their gaps are electrically connected by short bars. Theyare in addition magnetically coupled via the bias loop usedfor cavity tuning. The cavities are equippedwith a wide-bandfeedback system, limiting the beam loading, and a furtherreduction of the beam induced voltage is achieved by relayswhich short-circuit each half-resonator gap when the cavityis not in use. Asymmetries of the beam induced voltageobserved in the two half-cavities indicate that the couplingbetween the two resonators is not as tight as expected. Thetotal cavity impedance coupling to the beam may be affecteddifferently by the contributions of both resonators. A ded-icated measurement campaign with high-intensity protonbeam and numerical simulation have been performed to in-vestigate the beam-cavity interaction. This paper reports theresult of the study and the work aiming at the developmentof a model of the system, including the wide-band feedback,which reproduces this interaction.INTRODUCTIONThe PS is equipped with different cavities covering ona wide frequency range (2.8-10, 20, 40, 80 and 200MHz)for acceleration, RF gymnastics and longitudinal emittanceblow-up. Among them the 10MHzRF system plays a crucialrole for the beam dynamics, since it is the one responsible forbeam acceleration and also performs beam manipulations,such as bunch splitting and rotation. It has been shown that itrepresents the main source of longitudinal beam instabilitiesin the PS, namely coupled bunch instabilities [1].The parameter relevant to the beam-cavity interactioncan be modeled as an impedance excited by the beam cur-rent crossing the cavity. The reduction of this impedanceis already achieved by a wide-band feedback system [2].However, with the increasing intensity expected in the PSin the framework of the Injectors Upgrade (LIU), a furtherreduction of the equivalent impedance is wished to improvelongitudinal beam stability.BEAM LOADING AND LONGITUDINALIMPEDANCEA beam travelling in a synchrotron loses part of its energyat each turn, generating an electromagnetic (EM) wake fieldthat acts back on the beam itself. Depending on the intensity∗ giorgia.favia@cern.chthis may cause significant modification in the dynamics ofthe particles motion [3].A cavity can be modeled as a complex impedance Z .When a bunch of current Ib travels across the cavity, a beaminduced voltage Vb develops at the cavity gap [4]:Vb = −Z · Ib, (1)where the minus sign indicates that the induced voltage leadsto an energy loss.10MHz RF SystemEach 10MHz cavity is driven by a tetrode based amplifier,which provides the necessary current to reach up to 10 kVpper gap. In addition the system is equipped with a directwide-band feedback, which reduces the cavity impedance [5].The evaluation of the cavity impedance has to take into ac-count the effect of the electronics of the amplifier driving thecavity as well as the reduction due to the wide-band feedback.Figure 1 presents a simplified model of the 10MHz system.A detailed description of the RF amplifier and its upgradeZG RF+-IDRCCCRCVGAP2VGAP1IFGrid resonatorPredriver +Driver Final stage IBIBFigure 1: Simplified model of the 10MHz RF system, in-cluding two cavity shorted coaxial line resonators and thedriving amplifier.can be found in [6]. The two half cavities are modeled as twoR − L − C circuits: the shorted coaxial lines represent theequivalent inductances of the two cavity halves, establishedby the ferrite magnetic properties and variable with the mag-netic bias field; C is the equivalent ceramic gap capacityand Rc is mainly given by ferrite losses. There are threeshort coaxial lines connecting the two cavity halves: oneof them represents a copper bar which electrically couplestheir gaps; the other two are the two bars, through which theamplifier feeds the two gaps in parallel. The two half cavitiesare magnetically coupled through the circuit carrying theMOPOR012 Proceedings of IPAC2016, Busan, KoreaISBN 978-3-95450-147-2618Copyright©2016CC-BY-3.0andbytherespectiveauthors05 Beam Dynamics and Electromagnetic FieldsD04 Beam Coupling Impedance - Theory, Simulations, Measurements, Code Developmentscurrent biasing the ferrites, which makes a figure-of-8 looparound the two resonators.Since the beam crosses both gaps in series, it is modeledas two current sources. The total impedance seen by thebeam is thenZ = 2 ·RF+Rc/2RF ·Rc/21 + βZGgDgF RF+Rc/2RF ·Rc/2, (2)with ZG being the impedance of the grid resonator loadingthe driver stage, gD and gF the effective trans-conductancesof driver and final amplifier, RF the anode resistance ofthe final stage, β the feedback loop transfer function. Inorder to better understand how the beam interacts with thewhole system, a Pspice [7] model of the cavity, includingthe feedback amplifier, has been developed. To benchmarkthe model a measurement campaign of the voltage inducedby the beam has been performed.BEAM INDUCED VOLTAGEMEASUREMENTS AND SIMULATIONSMeasurements of the voltage induced by a single bunch,with high-intensity of about 8 · 1012 protons, at fixed har-monic, have been performed.The RF frequency for acceleration of protons with the10MHz cavities can vary from 3MHz (h=7) to 10MHz(h=21), slightly lower frequencies are required for ion accel-eration. Several cavities have been measured, at h=8, 16 and21 and the induced voltage has been evaluated at three stagesof the beam cycle: injection, transition and ejection (Fig. 2).Since the bunch length visibly changes during the cycle, aswell as its spectrum, the measurements allow to evaluatethe contribution of the beam harmonic content to the totalcavity impedance. The highest attention in this paper is-200 -100 0 100 200Time [ns]010203040Beam current [A] ejectiontransitioninjection0 0.5 1 1.5 2 2.5Time [7s]-3-2-10123V peak [kV]ejectiontransitioninjectionFigure 2: Measurements of the bunch current and the in-duced voltage across a gap, at h=8, at injection, transitionand close to ejection.posed on the effects observed during transition, since thebunch presents the shortest length, thus the highest harmoniccontent, during the acceleration cycle.Simulations andmeasurements were carried out in parallelin order to figure out which are the main contributors to thetotal cavity impedance. The Pspice model, that is alreadyable to reproduce the system behavior, has been optimizedfor this study. It includes dedicated libraries describingthe electron tube characteristics by means of 3 to 7 orderpolynoms, allowing to take into account the non-linearity ofthe system. The cavity is modeled as sketched in Fig. 1.The beam is simulated by means of two current sourcesdelayed in time by 4 ns, which corresponds to the time offlight between the two gaps. The model almost perfectlymatches the measurements, in each stage of the cycle, andat each harmonic.Figure 3 shows the voltage induced by the beam acrossthe cavity in straight section 11, when tuned to h=8 duringtransition, as from measurements and simulations.0 0.4 0.8 1.2 1.6 2Time [7s]-4-2024Induced voltage [kV]measurementsimulationFigure 3: Comparison of measurements and Pspice simu-lation of the induced voltage by a bunch of ∼60 ns lengthpassing through the cavity.The knowledge of the beam induced voltage and the bunchcurrent can lead to an evaluation of the 10MHz cavitiesimpedance as seen by beam. The real part of the impedancecan be computed according to the formula [3]:< (Z (ω)) = −<(V (ω)I (ω))= −< *.,FFT(Vgap (t))FFT (Ibunch (t))+/- (3)Figure 4 shows the results of the calculation of theimpedance of several cavities as observed from beam in-duced voltage. It also contains a trace obtained from simu-lations, using a model whose parameters have been set tomatch cavity 11 properties.1 2 3 4 5 6 7Frequency [MHz]0100200300400500Re (Z)  [+]cav 86cav 51cav 11cav 66simulationsFigure 4: Computation of the beam impedance of cavitiesin straight sections 11, 51, 86, 66 at h=8 during transition.Gap RelaysWhen the cavities are not in use two gap relays, one foreach half cavity, short-circuit the gaps to strongly reducetheir impedance and, as a consequence, the voltage inducedby the beam.Considering that the two half cavities are strongly cou-pled, one would expect to observe a similar beam inducedvoltage at both gaps. However an asymmetric behavior wasobserved [1].Proceedings of IPAC2016, Busan, Korea MOPOR01205 Beam Dynamics and Electromagnetic FieldsD04 Beam Coupling Impedance - Theory, Simulations, Measurements, Code DevelopmentsISBN 978-3-95450-147-2619 Copyright©2016CC-BY-3.0andbytherespectiveauthorsThe distribution of the beam induced voltage in both res-onators has therefore been analyzed into more detail: mea-surements and simulations have been carried out in parallelto investigate the main causes of the asymmetry observed.The beam induced voltage along the beam cycle, measuredacross the left and right gaps at different times during thecycle, is shown in Fig. 5. The induced voltage increases0 0.5 1Time [s]00.511.522.53V peak [KV] RIGHT GAPBoth gaps closedLeft openRight open0 0.5 1Time [s]00.511.522.53V peak [KV] LEFT GAPBoth gaps closedLeft openRight openFigure 5: Beam induced voltage on left and right acceleratinggaps during the acceleration of a single high intensity bunch.The first peak is the transition crossing and the second comesfrom bunch rotation before extraction.when whichever gap is open: a reduction of the voltage bymore than a factor of two, due to the second gap relay isobserved. Moreover the voltage measured at the shortedgap is about one half of the voltage at the open gap. Thesame asymmetry of the beam induced voltage distributionis present in all cavities and at different harmonics. The gaprelay effect on the gap voltage and the voltage distributionhave been analyzed through numerical simulations.A gap relay can be modeled as a series R − L − C, whereL represents the leakage inductance due to the connectionof the device to the gap, C is the capacitor decoupling theDC voltage, provided to generate the current biasing theferrite discs, and R is a small resistor which reduces thecavity impedance over the whole operating frequency range.In order to simulate the gap relay effect on the cavity, aseries R− L −C (R=2Ω, L=150 nH, C=67.2 nF) circuit hasbeen included in the model, in parallel to each gap. Thedevice increases the cavity resonance of the cavity, due tothe inductance L added in parallel to the cavity, and reducesthe real part of the cavity impedance because of R.Figure 6 shows a comparison between measurements andsimulations when the left gap is shorted, at h=8. An oscil-lation at 15MHz is visible, as well as a modulation of thevoltage due to a beat between two frequencies. Accordingto measurements and CST [8] simulations, the cavity trans-fer function is characterized by its main resonant frequencyand additional parallel or series resonances due to the cav-ity geometry and ferrite properties. If the series resonantfrequency of the gap relay is close to one of the cavity reso-nances, there could be an additional reduction of the inducedvoltage and thus of the impedance seen by the beam. This isthe case shown in Fig. 6 and in Fig. 7 at h=8.0 0.5 1Time [7s]-1.5-1-0.500.511.52Induced voltage [kV]RIGHT GAPmeasurementsimulation0 0.5 1Time [7s]-1.5-1-0.500.511.52Induced voltage [kV]LEFT GAPmeasurementsimulationFigure 6: Beam induced voltage induced across the twocavities gaps, when the left gap is shorted.The valid Pspice model allows to predict phenomena, asthe one described, and to take them into account in the designof an improved gap relay circuit.5 10 15 20 25Frequency [MHz]050100150200250300Re (Z) [+]RIGHT GAPh=21h=16h=85 10 15 20 25Frequency [MHz]050100150200250300Re(Z) [+]LEFT GAPh=21h=16h=8Re(Z) [+]Figure 7: Measured cavity impedance at h=8, 16, 21 whenthe left gap is shorted.Through numerical simulations and an analysis of thecircuit, it has been found that the main contribution to theasymmetry comes from the not perfect coupling made bythe bars connecting the 2 gaps. The magnetic coupling,instead, does not seem to give any contribution to the voltagedistribution. In addition the grid resonator tuning positionplays an important role on the total cavity impedance, sinceit is related to the phase stability of the wide-band feedbackand power amplifier driving the cavities [5].CONCLUSIONSMeasurements of the beam induced voltage in the PS10MHz cavities have been performed in order to charac-terize the beam-cavity interaction. Numerical simulationscarried out in parallel, by means of a complete Pspice model,have allowed to fully understand how the amplifier with itsfeedback contributes to this interaction.The Pspice simulations have proved to be a powerfulmeans for the synthesis of a complex system, as well asfor the characterization of single circuit elements and oftheir contribution to the whole system behaviour. We havebeen able to reproduce the measurement results and we coulduse the validated model for the design of new components,in the perspective of the system upgrade. A development ofa CST model of the full system is presently ongoing, whichcould possibly lead to a further EM characterization of thesystem.MOPOR012 Proceedings of IPAC2016, Busan, KoreaISBN 978-3-95450-147-2620Copyright©2016CC-BY-3.0andbytherespectiveauthors05 Beam Dynamics and Electromagnetic FieldsD04 Beam Coupling Impedance - Theory, Simulations, Measurements, Code DevelopmentsREFERENCES[1] H. Damerau et al. "Longitudinal Coupled-bunch Instabilitiesin the CERN PS." Particle Accelerator Conference, 2007. PAC.IEEE. IEEE, 2007.[2] R. Garoby, J. Jamsek, P. Konrad, G. Lobeau and G. Nassibian,"RF system for high beam intensity acceleration in the CERNPS", Particle Accelerator Conference, 1989. Accelerator Sci-ence and Technology, Proceedings of the 1989 IEEE, Chicago,IL, 1989, pp. 135-137 vol.1.[3] L. Palumbo, V. G. Vaccaro, and M. Zobov. "Wake fields andimpedance", CAS - CERN Accelerator School, AdvancedSchool on Accelerator Physic, Rhodes 1994. LNF-94/041,1994[4] K. Schindl, "Instabilities", CAS - CERN Accelerator School:Intermediate Course on Accelerator Physics, Zeuthen, Ger-many, 15-26 Sep 2003, pp.321-342[5] G. Favia et al. "The PS 10MHz high level RF system upgrade",IPAC 2016, Busan, Korea, paper MOPOR013, this conference.[6] D. Grier, "The PS 10MHz Cavity and Power Amplifier",PS/RF Note 2002-073, CERN, Geneva, Switzerland, 2002[7] OrCAD Pspice Designer, https://www.orcad.com/[8] https://www.cst.com/Proceedings of IPAC2016, Busan, Korea MOPOR01205 Beam Dynamics and Electromagnetic FieldsD04 Beam Coupling Impedance - Theory, Simulations, Measurements, Code DevelopmentsISBN 978-3-95450-147-2621 Copyright©2016CC-BY-3.0andbytherespectiveauthors

Study of the beam-cavity interaction in the PS 10 MHz RF system

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Study of the beam-cavity interaction in the PS 10 MHz RF system

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