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RF Synchronization Activity at SPARC

This review discusses the RF synchronization activities at SPARC, including bench qualification, phase monitoring, and control of phase noise from RF power stations. It also covers the goals and techniques for phase stability in the SPARC RF distribution. Bench measurements and conclusions are provided.

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RF Synchronization Activity at SPARC

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  1. 6th SPARC Injector ReviewCommittee - Frascati, 14 June 2005 RF Synchronization Activity at SPARC • Gallo • and • D. Alesini, M. Bellaveglia, R. Boni, G. Di Pirro, A. Drago, A.Ghigo • P. Baldini, L. Cacciotti, M. Scampati, A. Sprecacenere, S. Quaglia

  2. SUMMARY • General Layout; • Demodulation of “square” pulsed RF signals: bench qualification; • Phase monitoring of short pulses: bench qualification; • Control of the phase noise from RF power stations: bench test of a fast intra-pulse phase lock system; • To do list and Conclusions

  3. SPARC RF DISTRIBUTION: SCHEMATIC LAYOUT

  4. SPARC RF PHASE STABILITY GOALS: • SPARC phase I: • ± 3° between the Laser pulse and the Linac RF • (RF gun mainly) • SPARC phase II: • ± 0.5° between the Laser pulse and the Linac RF • (RF gun and RF compressor mainly)

  5. Phase Lock to the RF Reference Line • All the Linac RF signals will be phase-monitored respect to the RF ref. Line. The resolution of the phase measurements must be << 1 ps ( << 1° RF @ 2856 MHz) • The slow phase phase variations will be sampled at 10 Hz (the Linac rep. rate) and corrected acting on the phase shifters (included those placed in the high power waveguide branches). • The fast phase variations (i.e. the jitter with spectral components beyond 10 Hz) are much more difficult to correct. The possibility of implementing intra-pulse, fast phase lock to reduce the fast phase jitter introduced by the RF stations (klystrons + drivers) is well advanced.

  6. 1 I&Q Demodulator 0.5 k€ ½ PCI Sampling Board 0.4 k€ 1 RF Isolator 0.2 k€ RF Attenuators 0.1 k€ 1.2 k€ 1/4 PCI Samp. Board 0.2 k€ 1 Peak Detector 0.2 k€ 1 Directional Coup. 0.2 k€ RF Attenuators 0.1 k€ 0.7 k€ RF Demodulation Channel based on I&Q Detector passive, low cost, 4 quadrants, amplitude independent CW RF Total cost: 1.9 k€/channel (High Quality) 1.2 k€/channel (Standard) Pulsed RF RF Isolator

  7. PULSAR I&Q DEMODULATOR MODEL ID I4-0428 (custom)

  8. PULSAR I&Q DEMODULATOR MODEL ID I4-0428 : CALIBRATION

  9. PULSAR ID I4-0428 Long Term Acquisition

  10. PULSAR ID I4-0428 + ADLINK 9810 20 MS/s PCI Sampling Board Phase Resolution

  11. LASER to RF Line Syncronization • The phase of the Laser pulse respect to the Linac RF reference line will be continuously monitored and the “slow drifts” (i.e. the phase noise in a frequency band limited to ½ of the Linac rep. rate) will be compensated (shifting the phase of the RF ref. Line seems the simplest way to do it). • The “fast phase jitter” (i .e. the noise in a band larger than ½ of the rep. rate) of the Laser pulse can’t be compensated and must be kept inside the acceptable limits by specifications (1°nrequested to the manufacturer).

  12. Monitoring the synchronization of the bunch from the Gun and of the laser pulse

  13. HOMDYN Time-of-Flight Simulations

  14. TM010 – 2856 MHz • R/Q = 28.5 W • Q0 = 15000 (Al) • Qext = 30000 • Vp (@ 1 nC) = 4 V • = 0.5 ms • ftun 10 kHz Bunch Monitor Cavity TE111 – 2985 MHz R/Q = 0.5 W Q0 = 17000 (Al)

  15. Bench measurements of short pulse synchronization

  16. Results of the bench measurements of short pulse synchronization

  17. BENCH MEASUREMENTS OF A FAST INTRA-PULSE PHASE-LOCK CONTROL • An intra-pulse phase-lock system is under study to actively correct the fast phase jitter coming from the RF stations. • Since the RF pulse is about 4.5 ms long, the rise time of the system should be of the order of 1 ms, corresponding to a bandwidth of about 1 MHz. • Afast phase modulator is needed, while the overall delay of the connections (including the group delay of the RF station) should be limited to  150 ns. • The speed of the OpAmps manipulating the signal has also to be adequate.

  18. PHASE STABILITY MEASUREMENTS DAFNE LINAC – STATION B August 2003 mixer sensitivity = 5.6 mV/Deg

  19. Long Term (90 min) phase variation: ± 2.5° Short Term (16 shots) phase variation: ± 1°

  20. KLYSTRON PHASE LOCK

  21. FAST PHASE LOCK FEEDBACK SYSTEM Sketch of the Experimental Set-up “Noisy” RF Station

  22. PULSAR ST-G9-411 Phase Shifter CALIBRATION FREQUENCY RESPONSE

  23. Lock Amp: Circuit sketch Fast Phase Lock Feedback System: Open Loop Gain (amplitude and phase)

  24. OPEN LOOP CLOSED LOOP

  25. OPEN LOOP + noise CLOSED LOOP + noise

  26. To do list and Conclusions

  27. DAFNE LINAC KLYSTRON MEASUREMENTS The phase jitter at the output of one of the DAFNE TH2128C Linac klystrons has been measured to figure out the amount of expected noise in the SPARC case and to gain some experience in this subject.

  28. Open/Closed Loop Phase Pulses 256 frames with  10°pp , 10 kHz phase noise  10°pp Single shot phase pulses

  29. KLYSTRON PHASE NOISE MEASUREMENTS CONCLUSIONS • The measured phase jitter at the output of the Linac station-B klystron is about ± 2.5° in long term and ± 1° in short term. • The main contribution seems to come from the driver amplifiers (planar triode technology). In the SPARC case the driver amplifiers will be of a different and better performing technology (pure class A, solid state) with tight phase jitter specification (1° rms). The expected phase jitter values of the SPARC RF stations are consequently lower.

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