Abstract
The foreseen incremental luminosity for near-future high-energy physics experiments demands evolution for the read-out electronics in terms of event data-rate. However, the filtering necessary to reject noise and meet the signal-to-noise-ratio requirements imposes a restriction on the operational speed of the conventional read-out electronics. The stringent trade-off between signal-to-noise-ratio and the event data-rate originates from the time-invariant behavior of the conventional systems. In this paper, the cases of time-variant systems are addressed, studying a benchmark with the RC-CR shaping function used in time-over-threshold methods. It was demonstrated that the time-variant systems enable a higher data-rate for the given noise performance. Moreover, taking advantage of time-variant systems, the proposed rising-edge method enables further data-rate enhancement with respect to the traditional time-over-threshold technique by reading the data from the rising edge of the analog output waveform. A comparison between the conventional time-invariant time-over-threshold technique, its time-variant equivalent and rising-edge method confirms the better performance of the latter one in terms of data-rate enhancement for a target noise performance. Moreover, design challenges for time-variant systems are briefly discussed, considering the ATLAS Monitored Drift Tube detector as a design case.
Highlights
The luminosity of the Large Hadron Collider (LHC) accelerator at CERN will be upgraded by a factor of about seven compared to its previous performance
While the upgraded LHC accelerator is expected to go into operation in the second half of this decade, a more powerful accelerator is already on the drawing board, which is envisaged to be constructed in the second half of the decade [1,2]
The results indicate the competitiveness of TV analog-channels in the optimization of the SNR versus baseline recovery (BLR) trade-off
Summary
The luminosity of the Large Hadron Collider (LHC) accelerator at CERN will be upgraded by a factor of about seven compared to its previous performance. The conventional ASD read-out chains suffer from a severe trade-off between data-rate and SNR originating from the time-invariant (TI) nature of the analog-channels’ operational behavior. Time-variant (TV) analog-channels were considered, which allow the transfer function optimization of both the event measurement (EM) phase and BLR tail. The comparison between TI and TV analog-channels is studied considering the known RC-CR transfer function as a benchmark with the ToT method for event amplitude measurement Both TI and TV methods are modeled and behaviorally simulated to be compared in terms of SNR, BLR, and experiment data-rate. It is demonstrated that for a target SNR required in a defined application/experiment, the time-variant risingedge (TV-RE) system presents a shorter BLR, enabling a higher data-rate, outperforming the TV/TI-ToT systems. The proposed solution is attractive for high-data-rate experiments
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