a preliminary approach to the needs of open loop control of the lorentz force detuning is to...
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A preliminary approach to the needs of open loop control of the Lorentz Force Detuning is to generate a custom piezo control signal
with proper and tunable shape and timing (referred to a master sync input signal).
A simple and low chip-area consuming FPGA algorithm that handle such issue has been implemented.
AbstractA coaxial (blade) tuner solution has been developed for the compensation of the Lorentz force detuning of the superconducting cavities under the high gradient
pulsed operation foreseen for ILC operation. The device is based on prototypes successfully tested at DESY in 2002 both on CHECHIA and on the superstructures inserted in the TTF string. An improvement of the tuner characteristics has now been designed by the integration of fast tuning capabilities by means of piezo-ceramic element. Two prototypes of the new INFN coaxial piezo blade tuner have been manufactured and will be tested in the near future at
DESY and BESSY after integration with the cavities. Meanwhile also the control electronics is under developing based on a FPGA electronic platform, a SIMCON 3.1 board from DESY LLRF group led by S. Simrock. Once completed it will allow to implement a first prototype of a complete blade tuner control
system. Here the blade tuner design and its main characteristics are presented, together with the latest results from the activity on electronics.
CAS course "Introduction to Accelerator Physics" – Zakopane, Poland, 1 – 13 October 2006
Piezo system:Recently, a fast, piezo-based, tuning action has been added to the blade tuner concept. In the picture it’s possible to see
the piezoelectric elements acting between the ring-blade assembly and the outer ring.
The piezo actuators provide fast tuning capabilities needed
for Lorentz Force Detuning (LFD) compensation and
microphonics stabilization.
Two complete prototypes, including He tanks and piezo actuators, have been manufactured. Tests were initially foreseen on summer 2006 at
DESY and BESSY after the final tuner integration with two existing TTF cavities, but higher priorities for the Module 6 assembly operation at
DESY lead to a delay in the testing program.
The movement leverage:
Two existing blade tuner assemblies have been equipped with a
revised leverage system. With respect to
the original system used for the TTF
superstructures, the leverage system has been rotated to one
side, in order to avoid the mechanical
interferences with the Invar rod providing the
cavity longitudinal alignment in the TTF
CRY3 design.
The threaded bars:The four threaded bars, parallel to the piezo elements
accomplish two different tasks: first of all they are needed during transportation, handling and assembly phases to avoid inelastic deformations of the bellow. In this case
they are tightly bolted at both ends to provide stiffness to the system. Furthermore, in the operating condition, the
inner bolts are loosened by few hundredths of mm and the bars act as safety devices in case of piezo mechanical
failure or overpressure conditions inside the Helium tank
Modified Helium tank:
Because the tuner is fixed to the helium tank, a
bellow is needed between the two fixed rings. The position of pad supports
has been reviewed in order to minimize the bending
forces on the helium tank bellow and, of course, on
piezo elements.
The bending rings:The ring-blade assembly, consists of three different rings: one of the external rings is rigidly connected
to the helium tank, while the central one is symmetrically
divided in two halves.
The central arm is connected to the bending system to produce
the right rotation and the correct axial movement for the tuning. The rings are connected by thin titanium plates (blades) that can
change the cavity length (compression and tension) as a
results of an azimuthally rotation in opposite direction of the two
halves of the central ring.
The Closed Loop stage could instead be forced to implement, for the sake of stability and performance of the loop, a digital filter with
detailed transfer function, both in amplitude and phase.
Then an algorithm has been developed for state-space computations FPGA implementation, in this particular case the
design has been chosen in order to keep as low as possible the logic resources requested.
SIMCON 3.1 board main features:
• single low latency PCB board, VME standard based• 10 analog input channels, AD6645 ADC’s up to 105 MSPS, 14 bit• 4 analog output channels, AD9772A DAC’s up to 160 MSPS, 14 bit• XILINX Virtex II-Pro FPGA chip - main processing unit• ALTERA ACEX FPGA chip - VME and Internal Interface interpreter
State Space Order
Maximum achievablesampling frequency
[kHz]
64 20
32 100
16 300
• tunable delay from master sync
• custom shape and length of the pulse
• 10 s time resolution to build up the pulse pattern
• only 1% of chip logic resources needed
• up to 10 ms pulse length
Courtesy of DESY LLRF group
• discrete state-space implementation
• 32 bit fixed-point computations
• 7% of chip logic resources needed
Analog equipment:
• Phase detector
• Filter amplifier
• Piezoelectric actuator driver
• RF line (probe, delay etc.)
Digital equipment:
• Fast ADC & DAC
• Signal processing stage (DSP or FPGA)
RF Probe
PiezoDriver
MotorDriver
ClosedLoop
Controller
OpenLoop
Controller
StepMotor
Controller
+-
++
PhaseDetector
RFreference FPGA
DigitalController
Plant
Simulink schematic of State-Space algorithm
Tuner control system schematic view:
C. Pagani, A. Bosotti, P. Michelato, N. Panzeri, R. Paparella, P. PieriniINFN Milano - LASA, Italy
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