Low Q Cavity BPM Study for the Beam Position Measurement of Nanosecond Spaced Electron Bunches

Yang, Liu; Cao, Shanshan; He, Xiaozhong; Leng, Yongbin; Yu, Luyang; Yuan, Renxian; Zhang, Linwen

doi:10.18429/JACoW-IPAC2018-WEPAF027

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RIS citation export for WEPAF027: Low Q Cavity BPM Study for the Beam Position Measurement of Nanosecond Spaced Electron Bunches

TY - CONF
AU - Yang, L.
AU - Cao, S.S.
AU - He, X.
AU - Leng, Y.B.
AU - Yu, L.Y.
AU - Yuan, R.X.
AU - Zhang, L.W.
ED - Koscielniak, Shane
ED - Satogata, Todd
ED - Schaa, Volker RW
ED - Thomson, Jana
TI - Low Q Cavity BPM Study for the Beam Position Measurement of Nanosecond Spaced Electron Bunches
J2 - Proc. of IPAC2018, Vancouver, BC, Canada, April 29-May 4, 2018
C1 - Vancouver, BC, Canada
T2 - International Particle Accelerator Conference
T3 - 9
LA - english
AB - Low Q cavity BPM is a key to distinguish closely spaced electron bunches allowing precise beam handling for XFEL facilities operating in a multi-bunch mode at high repetition rate up to hundreds MHz. The inter-bunch signal pollution issue becomes significant when bunch separation is down to nanosecond and causes the position detection to be increasingly overestimated. Solely relying on extreme low Q to achieve sufficient decay within bunch interval leads to appreciable interference from non-signal modes due to strong overcoupling of antenna design is required. The error imposed on measured position raises a challenge to meet the goal of high resolution. Alternatively, a concept is proposed to remove the dominant part of signal pollution at the moment of sampling by intentionally shifting the phase of the last bunch signal 90degree respect to that of current bunch signal, where signal sampling is normally taken for nanosecond spaced bunches. This quadrature phase shift is defined by properly choosing the operational frequency of dipole mode regarding to the bunch frequency. A low Q cavity BPM prototype to identify technical challenges and verify this concept is under development in the R&D plan for future XFEL with high repetition rate
PB - JACoW Publishing
CP - Geneva, Switzerland
SP - 1881
EP - 1883
KW - cavity
KW - FEL
KW - dipole
KW - electron
KW - coupling
DA - 2018/06
PY - 2018
SN - 978-3-95450-184-7
DO - 10.18429/JACoW-IPAC2018-WEPAF027
UR - http://jacow.org/ipac2018/papers/wepaf027.pdf
ER -