Salvato in:
Dettagli Bibliografici
Autori principali: Arnaud, Kevin, Back, Antoine, Charlet, Daniel, Degret, Gabriel, Del Buono, Luigi, Durante, Paolo, Hervo, Amaury, Hachon, Frédéric, Lafay, Xavier, Langouët, Julien, Gac, Renaud Le, Meunier, Jea-Luc, Nappa, Jean-Marc, Mattar, Costy Nassif, Renard, Christophe, Vouters, Guillaume
Natura: Preprint
Pubblicazione: 2026
Soggetti:
Accesso online:https://arxiv.org/abs/2602.01422
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866914471973224448
author Arnaud, Kevin
Back, Antoine
Charlet, Daniel
Degret, Gabriel
Del Buono, Luigi
Durante, Paolo
Hervo, Amaury
Hachon, Frédéric
Lafay, Xavier
Langouët, Julien
Gac, Renaud Le
Meunier, Jea-Luc
Nappa, Jean-Marc
Mattar, Costy Nassif
Renard, Christophe
Vouters, Guillaume
author_facet Arnaud, Kevin
Back, Antoine
Charlet, Daniel
Degret, Gabriel
Del Buono, Luigi
Durante, Paolo
Hervo, Amaury
Hachon, Frédéric
Lafay, Xavier
Langouët, Julien
Gac, Renaud Le
Meunier, Jea-Luc
Nappa, Jean-Marc
Mattar, Costy Nassif
Renard, Christophe
Vouters, Guillaume
contents The PCIe400 is a generic readout board designed for high-throughput data acquisition in future high-energy physics experiments. It interfaces up to 48 bidirectional links supporting custom protocols from 1 to 26 Gbps to modern back-end systems providing up to 400 Gbps bandwidth.The board is developed as a technological demonstrator for the LHCb Upgrade II, which foresees an aggregated throughput of approximately 200 Tbps. In addition to increased bandwidth, the PCIe400 targets deterministic clock distribution to front-end electronics. At a maximum instantaneous luminosity of $1.5~\times~10^{34}~cm^{-2}s^{-1}$, up to 40 proton-proton interactions per bunch crossing are expected in LHCb Upgrade II. The adoption of 4D tracking detectors with time resolutions down to 20 ps motivates clock distribution with phase determinism below 10 ps peak-to-peak across large-scale systems exceeding 2000 nodes. This paper presents the qualification of the PCIe400 prototype board, focusing on high-bandwidth interfaces, including next-generation QSFP112 links, and phase-deterministic clock distribution.
format Preprint
id arxiv_https___arxiv_org_abs_2602_01422
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle PCIe400 generic readout board qualification test
Arnaud, Kevin
Back, Antoine
Charlet, Daniel
Degret, Gabriel
Del Buono, Luigi
Durante, Paolo
Hervo, Amaury
Hachon, Frédéric
Lafay, Xavier
Langouët, Julien
Gac, Renaud Le
Meunier, Jea-Luc
Nappa, Jean-Marc
Mattar, Costy Nassif
Renard, Christophe
Vouters, Guillaume
Instrumentation and Detectors
The PCIe400 is a generic readout board designed for high-throughput data acquisition in future high-energy physics experiments. It interfaces up to 48 bidirectional links supporting custom protocols from 1 to 26 Gbps to modern back-end systems providing up to 400 Gbps bandwidth.The board is developed as a technological demonstrator for the LHCb Upgrade II, which foresees an aggregated throughput of approximately 200 Tbps. In addition to increased bandwidth, the PCIe400 targets deterministic clock distribution to front-end electronics. At a maximum instantaneous luminosity of $1.5~\times~10^{34}~cm^{-2}s^{-1}$, up to 40 proton-proton interactions per bunch crossing are expected in LHCb Upgrade II. The adoption of 4D tracking detectors with time resolutions down to 20 ps motivates clock distribution with phase determinism below 10 ps peak-to-peak across large-scale systems exceeding 2000 nodes. This paper presents the qualification of the PCIe400 prototype board, focusing on high-bandwidth interfaces, including next-generation QSFP112 links, and phase-deterministic clock distribution.
title PCIe400 generic readout board qualification test
topic Instrumentation and Detectors
url https://arxiv.org/abs/2602.01422