Fermilab AAC May 11 th 1/12 Testing of Cap-Cav 2 LLRF Development with DESY Alexander Brandt, DESY, Hamburg 1.Current and Future LLRF Developments at DESY 2.DESY Low Latency Control Hardware 3.Collaboration with FNAL-A0, –SMTF and –HPTF (present and future)
Fermilab AAC May 11 th 2/12 DESY LLRF Contributors DESY, Hamburg, Valeri Ayvazyan, Alexander Brandt, Gerhard Grygiel, Thomas Fröhlich, Olaf Hensler, Matthias Hoffmann, Bastian Lorbeer, Frank Ludwig, Günther Möller, Kay Rehlich, Stefan Simrock, Henning Weddig,... WUT-ISE, Warsaw, Tomasz Czarski, Krzystof Czuba, Tomasz Filipek, Wojciech Giergusiewicz, Wojciech Jalmuzna, Pawel Kaleta, Waldemar Koprek, Karol Perkuszewski, Piotr Pucyk, Ryszard Romaniuk, Jaroslaw Szewinski,... TUL-DMCS, Lodz, Wojciech Cichalewski, Piotr Cieciura, Mariusz Grecki, Tomasz Jezynski, Boguslaw Koseda, Dariusz Markowski, Pawel Pawlik, Przemsylaw Sekalski, Bartlomiej Swiercz, Marcin Wojtowski,... IHEP, Protvino, Nikolay Ignashin, Sergej Sytov,... INFN, Milano, Angelo Bosotti, Rocco Paparella KEK, Japan, Shin Michizono, Toshi Matsumoto Yerewan Institute, Gevorg Petrosyan, Ludwig Petrosyan...
Fermilab AAC May 11 th 3/12 LLRF Developments at DESY: VUV-FEL Running since 2004 (as successor of TTF1, ) SC linear injector, 6 undulator sections (down to 6nm wavelength) Pulsed operation (2ms / 1-10Hz) 1 nc cathode, 48 sc cavities, 1 transverse deflecting cavity 5 rf stations (one klystron per 8-32 sc cavities) Field stability requirement: / 0.1° Designed as user facility and for accelerator development Ideal testbed for LLRF developments!
Fermilab AAC May 11 th 4/12 LLRF Developments at DESY: VUV-FEL
Fermilab AAC May 11 th 5/12 LLRF Developments at DESY: XFEL, ILC FEL lightsource for sub-nm wavelength, commissioning ~2012 at DESY ~1000 cavities, 35 klystrons High field stability: 10 -4, 0.01° User facility (high reliability) Demands for a low-maintenance, radiation resistive hardware Future project, not yet scheduled ( ?) ~20000 cavities Collider experiment, therefore relaxed field requirements Very high degree of automation needed (e.g. global phase control, recovery automation)
Fermilab AAC May 11 th 6/12 Vecor Sum Control Challenges 1.3 VM ADC... (32) DSPDAC Latency in control loop limits feedback gain (and therefore field stability) build faster feedback hardware (Current revision: SimCon 3.1 FPGA system, ~200ns) Mechanical / electrical detuning limits performance and increases power demand build fast resonance frequency control system (piezo or magnetostrictive tuning) Calibration of signals determines precision (nonlinear effects) build transient detection hardware Reference and Distribution determines field stability build long range temperature stable reference system
Fermilab AAC May 11 th 7/12 Further Projects 8-channel downconverter boards (already in operation) Bubble Neutron Dosimetry system w/ automatic readout s/w Piezoelectric tuner installed at one cavity Box equipped with several field detectors for the rf gun Transient detection hardware (test setup)
Fermilab AAC May 11 th 8/12 DESY's Low Latency Control Boards SimCon xADCs, 2xDACs Virtex II FPGA Successfully tested at DESY 9-cell teststand (single cavity) Successfully tested at A0 Optical Gigalink 2.0GB/s mezzanine card Measured latency: 200ns+160ns! SimCon xADCs, 4xDACs Virtex II FPGA Successfully tested at DESY 9-cell teststand Vectorsum Test at VUV-FEL scheduled for May/June Optical Gigalink on board (3.125GB/s) Measured latency: 200ns+160ns! SimCon xADCs, 4xDACs Virtex II Pro FPGA with 2 PPC405 2x Optical Gigalink Schematics finished Prototypes expected in July SimCon x.x 128xADCs, 64xDACs Allows complex control algorithm Account for additional signals SimCon3.1 Block Diagram: DSP C-67 Successor of C-40 ( ) TI C-67 CPU In Operation for VS control since Gigalink channels No ADCs/DACs on board ~3us C-67 DSP Board: SimCon3.0 Board: SimCon2.1 Board:
Fermilab AAC May 11 th 9/12 LLRF Plans for A0/SMTF (Present / Short Term) Refer to Brian Chase talk What we have done already –Commision SimCon 2.1 prototype (1 week in March 05) at A0 –Achieved high gain (~100) already –Cleaned up DOOCS control system at A0 What we plan (short term, May '05 until end '05) –Again set up SimCon 2.1 at A0 –Improve calibration of system –Test various algorithms –Establish remote connection DESY FNAL –Update DOOCS control system at FNAL DESY support by G. Grygiel, O. Hensler, K. Rehlich DOOCS has interface to other systems, e.g. EPICS
Fermilab AAC May 11 th 10/12 Tests in March '05 Matlab Control Panel: Feedback Gain in the order of 100 Readout Panel: Top: I and Q (blue) resp. Amplitude and Phase (red) of the Cavity Bottom: I and Q setpoint curves
Fermilab AAC May 11 th 11/12 LLRF Plans for A0/SMTF (Medium / Long Term) Refer to Brian Chase talk What we plan (medium term, starting from end '05) –Continue support on the DOOCS control system at FNAL –Provide further SimCon systems (SimCon 3.1 to arrive by the end of this year) –Provide signal detection hardware (downconverters) –Collaboration with FNAL-staff on algorithm development What we plan (long term) –Provide and support further SimCon systems –Continue support on the DOOCS control system at FNAL
Fermilab AAC May 11 th 12/12 Summary and Outlook Based on the successful experience of TTF1 (first machine with VS control) and VUV-FEL, DESY is currently in the process of developing the LLRF control for XFEL Development of LLRF control for XFEL already accounts for the requirements of ILC (automation, radiation hardness) Demonstrated single cavity control at A0 in March '05 Established collaboration with FNAL for FPGA software development Plan to equip SMTF with next revisions of SimCon As a universal digital control system SimCon is applicable to many accelerators (in principle it is not restricted to LLRF control only)
Fermilab AAC May 11 th 13/12