Cavity parameters identification for TESLA control system development

Czarski, T.; Romaniuk, Ryszard S.; Pozniak, K. T.; Simrock, S.

Report

PUBDB-2022-07373

Cavity parameters identification for TESLA control system development

Czarski, T.DESY* ; Pozniak, K. T. ; Romaniuk, R. S. ; Simrock, S.

2005

15 pp. (2005) [10.3204/PUBDB-2022-07373]

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Please use a persistent id in citations: doi:10.3204/PUBDB-2022-07373

Report No.: DESY-TESLA-FEL-2005-08

Abstract: Aim of the control system development for TESLA cavity is a more efficient stabilization of the pulsed, accelerating EM field inside resonator. Cavity parameters identification is an essential task for the comprehensive control algorithm. TESLA cavity simulator has been successfully implemented using high-speed FPGA technology. Electromechanical model of the cavity resonator includes Lorentz force detuning and beam loading. The parameters identification is based on the electrical model of the cavity. The model is represented by state space equation for envelope of the cavity voltage driven by current generator and beam loading. For a given model structure, the over-determined matrix equation is created covering long enough measurement range with the solution according to the least-squares method. A low-degree polynomial approximation is applied to estimate the time-varying cavity detuning during the pulse. The measurement channel distortion is considered, leading to the external cavity model seen by the controller. The comprehensive algorithm of the cavity parameters identification was implemented in the Matlab system with different modes of operation. Some experimental results were presented for different cavity operational conditions. The following considerations have lead to the synthesis of the efficient algorithm for the cavity control system predicted for the potential FPGA technology implementation.

Keyword(s): electron positron: linear collider ; linear collider: proposed ; cavity: superconductivity ; niobium ; cavity: control system ; expansion: wavelet ; DESY TESLA Linac ; 07.05.Dz ; 29.50.+v ; 07.50.-e ; 29.17.+w ; Superconducting cavity control ; Model identification ; System modeling and simulation