Parallelized Kalman-Filter-Based Reconstruction of Particle Tracks on Many-Core Processors and GPUs

Giuseppe Cerati; Peter Elmer; Slava Krutelyov; Steven Lantz; Matthieu Lefebvre; Mario Masciovecchio; Kevin McDermott; Daniel Riley; Matevž Tadel; Peter Wittich; Frank Würthwein; Avi Yagil

doi:10.1051/epjconf/201715000006

All issues

Volume 150 (2017)

EPJ Web Conf., 150 (2017) 00006

Abstract

Open Access

Issue		EPJ Web Conf. Volume 150, 2017 Connecting The Dots/Intelligent Trackers 2017 (CTD/WIT 2017)


Article Number		00006
Number of page(s)		12
DOI		https://doi.org/10.1051/epjconf/201715000006
Published online		08 August 2017

EPJ Web of Conferences 150, 00006 (2017)
https://doi.org/10.1051/epjconf/201715000006

Parallelized Kalman-Filter-Based Reconstruction of Particle Tracks on Many-Core Processors and GPUs

Giuseppe Cerati⁴^a, Peter Elmer²^b, Slava Krutelyov¹^c, Steven Lantz³^d, Matthieu Lefebvre²^e, Mario Masciovecchio¹^f, Kevin McDermott³^g, Daniel Riley³^h, Matevž Tadel¹ⁱ, Peter Wittich³^j, Frank Würthwein¹^k and Avi Yagil¹^l

¹ UC San Diego, La Jolla, CA, United States of America 92093
² Princeton University, Princeton, NJ, United States of America 08544
³ Cornell University, Ithaca, NY, United States of America 14853
⁴ Fermilab, Batavia, IL, United States of America 60510-5011

^a e-mail: giuseppe.cerati@cern.ch
^b e-mail: peter.elmer@cern.ch
^c e-mail: vyacheslav.krutelyov@cern.ch
^d e-mail: steve.lantz@cornell.edu
^e e-mail: ml15@princeton.edu
^f e-mail: mario.masciovecchio@cern.ch
^g e-mail: kevin.mcdermott@cern.ch
^h e-mail: daniel.riley@cornell.edu
ⁱ e-mail: matevz.tadel@cern.ch
^j e-mail: wittich@cornell.edu
^k e-mail: fkw@ucsd.edu
^l e-mail: ayagil@physics.ucsd.edu

Published online: 8 August 2017

Abstract

For over a decade now, physical and energy constraints have limited clock speed improvements in commodity microprocessors. Instead, chipmakers have been pushed into producing lower-power, multi-core processors such as Graphical Processing Units (GPU), ARM CPUs, and Intel MICs. Broad-based efforts from manufacturers and developers have been devoted to making these processors user-friendly enough to perform general computations. However, extracting performance from a larger number of cores, as well as specialized vector or SIMD units, requires special care in algorithm design and code optimization. One of the most computationally challenging problems in high-energy particle experiments is finding and fitting the charged-particle tracks during event reconstruction. This is expected to become by far the dominant problem at the High-Luminosity Large Hadron Collider (HL-LHC), for example. Today the most common track finding methods are those based on the Kalman filter. Experience with Kalman techniques on real tracking detector systems has shown that they are robust and provide high physics performance. This is why they are currently in use at the LHC, both in the trigger and offine. Previously we reported on the significant parallel speedups that resulted from our investigations to adapt Kalman filters to track fitting and track building on Intel Xeon and Xeon Phi. Here, we discuss our progresses toward the understanding of these processors and the new developments to port the Kalman filter to NVIDIA GPUs.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License 4.0, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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