The CMS Fast Beam Condition Monitor for HL-LHC

The CMS Fast Beam Condition Monitor for HL-LHC

The high-luminosity upgrade of the LHC brings unprecedented requirements for real-time and precision bunch-by-bunch online luminosity measurement and beam-induced background monitoring. A key component of the CMS Beam Radiation, Instrumentation and Luminosity system is a stand-alone luminometer, the...

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Hauptverfasser: Auzinger, G, Bakhshiansohi, H, Dabrowski, A, Delannoy, A. G, Dierlamm, A, Dragicevic, M, Gholami, A, Gomez, G, Guthoff, M, Haranko, M, Homna, A, Jenihhin, M, Kaplon, J, Karacheban, O, Korcsmáros, B, Liu, W. H, Lokhovitskiy, A, Loos, R, Mallows, S, Michel, J, Myronenko, V, Pásztor, G, Pari, M, Schwandt, J, Sedghi, M, Shevelev, A, Shibin, K, Steinbrueck, G, Stickland, D, Ujvari, B, Wegrzyn, G. J
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creator Auzinger, G
Bakhshiansohi, H
Dabrowski, A
Delannoy, A. G
Dierlamm, A
Dragicevic, M
Gholami, A
Gomez, G
Guthoff, M
Haranko, M
Homna, A
Jenihhin, M
Kaplon, J
Karacheban, O
Korcsmáros, B
Liu, W. H
Lokhovitskiy, A
Loos, R
Mallows, S
Michel, J
Myronenko, V
Pásztor, G
Pari, M
Schwandt, J
Sedghi, M
Shevelev, A
Shibin, K
Steinbrueck, G
Stickland, D
Ujvari, B
Wegrzyn, G. J
description The high-luminosity upgrade of the LHC brings unprecedented requirements for real-time and precision bunch-by-bunch online luminosity measurement and beam-induced background monitoring. A key component of the CMS Beam Radiation, Instrumentation and Luminosity system is a stand-alone luminometer, the Fast Beam Condition Monitor (FBCM), which is fully independent from the CMS central trigger and data acquisition services and able to operate at all times with a triggerless readout. FBCM utilizes a dedicated front-end application-specific integrated circuit (ASIC) to amplify the signals from CO$_2$-cooled silicon-pad sensors with a timing resolution of a few nanoseconds, which enables the measurement of the beam-induced background. FBCM uses a modular design with two half-disks of twelve modules at each end of CMS, with four service modules placed close to the outer edge to reduce radiation-induced aging. The electronics system design adapts several components from the CMS Tracker for power, control and read-out functionalities. The dedicated FBCM23 ASIC contains six channels and adjustable shaping time to optimize the noise with regards to sensor leakage current. Each ASIC channel outputs a single binary high-speed asynchronous signal carrying time-of-arrival and time-over-threshold information. The chip output signal is digitized, encoded and sent via a radiation-hard gigabit transceiver and an optical link to the back-end electronics for analysis. This paper reports on the updated design of the FBCM detector and the ongoing testing program.
doi_str_mv 10.48550/arxiv.2402.03971
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title The CMS Fast Beam Condition Monitor for HL-LHC
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