Real-time brain activation detection by FPGA implemented adaptive algorithm

Muhammad Shahid Nazir; Abubakar Akram; Bhagesh Choudhry Maheshwari; Muhammad Usman Hadi; Muhammad Aqil; Haroon Khan

doi:10.1109/ICIEECT.2017.7916522

Real-time brain activation detection by FPGA implemented adaptive algorithm

Muhammad Shahid Nazir, Abubakar Akram, Bhagesh Choudhry Maheshwari, Muhammad Usman Hadi, Muhammad Aqil^*, Haroon Khan

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Publikation: Bidrag til bog/antologi/rapport/konference proceeding › Konferenceartikel i proceeding › Forskning › peer review

Abstract

This paper proposes a computationally efficient embedded system, implemented on field programmable gate arrays (FPGA), for real-time brain imaging. An RS-232 core is employed to obtain the brain data from a functional near-infrared spectroscopy (fNIRS) imaging modality on sample basis. A 32-bit floating point core (IEEE754) is developed on FPGA to manipulate floating point data with precision. Recursive least-squares estimation (RLSE) core is implemented on FPGA to facilitate computationally-efficient parallel adaptive processing (filtering) of multiple channels for real-time brain-activity estimation, for the first time as per our knowledge. The brain activation model and the methodology for its parameters' estimation by RLSE is depicted from Aqil et al., 2012 [2] and implemented on FPGA. The proposed embedded real-time methodology is demonstrated by instantiating eight RLSE cores on an FPGA board (Spartan-6 LX150T Development Kit) followed by its validation with an open source fNIRS dataset. The real-time results obtained with the proposed embedded system matches with the previously reported online results. Multiple RLSE cores can be instantiated, depending on the available resources of the FPGA, to process multiple channels concurrently.

Originalsprog	Engelsk
Titel	ICIEECT 2017 - International Conference on Innovations in Electrical Engineering and Computational Technologies 2017, Proceedings
Forlag	IEEE Signal Processing Society
Publikationsdato	1 maj 2017
Artikelnummer	7916522
ISBN (Trykt)	978-1-5090-3311-9
ISBN (Elektronisk)	978-1-5090-3310-2
DOI	https://doi.org/10.1109/ICIEECT.2017.7916522
Status	Udgivet - 1 maj 2017
Udgivet eksternt	Ja
Begivenhed	2017 International Conference on Innovations in Electrical Engineering and Computational Technologies, ICIEECT 2017 - Karachi, Pakistan Varighed: 5 apr. 2017 → 7 apr. 2017

Konference

Konference	2017 International Conference on Innovations in Electrical Engineering and Computational Technologies, ICIEECT 2017
Land/Område	Pakistan
By	Karachi
Periode	05/04/2017 → 07/04/2017
Sponsor	et al., H.E.J Research Institute of Chemistry (ICCBS), Higher Education Commission Islamabad (HEC), Indus University Karachi, K-Electric, Pakistan Science Foundation (PSF)

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10.1109/ICIEECT.2017.7916522

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Citationsformater

Nazir, M. S., Akram, A., Maheshwari, B. C., Hadi, M. U., Aqil, M., & Khan, H. (2017). Real-time brain activation detection by FPGA implemented adaptive algorithm. I ICIEECT 2017 - International Conference on Innovations in Electrical Engineering and Computational Technologies 2017, Proceedings Artikel 7916522 IEEE Signal Processing Society. https://doi.org/10.1109/ICIEECT.2017.7916522

@inproceedings{debaa00a6ef04176a9c2e46e1b97176f,

title = "Real-time brain activation detection by FPGA implemented adaptive algorithm",

abstract = "This paper proposes a computationally efficient embedded system, implemented on field programmable gate arrays (FPGA), for real-time brain imaging. An RS-232 core is employed to obtain the brain data from a functional near-infrared spectroscopy (fNIRS) imaging modality on sample basis. A 32-bit floating point core (IEEE754) is developed on FPGA to manipulate floating point data with precision. Recursive least-squares estimation (RLSE) core is implemented on FPGA to facilitate computationally-efficient parallel adaptive processing (filtering) of multiple channels for real-time brain-activity estimation, for the first time as per our knowledge. The brain activation model and the methodology for its parameters' estimation by RLSE is depicted from Aqil et al., 2012 [2] and implemented on FPGA. The proposed embedded real-time methodology is demonstrated by instantiating eight RLSE cores on an FPGA board (Spartan-6 LX150T Development Kit) followed by its validation with an open source fNIRS dataset. The real-time results obtained with the proposed embedded system matches with the previously reported online results. Multiple RLSE cores can be instantiated, depending on the available resources of the FPGA, to process multiple channels concurrently.",

keywords = "Brain-computer interfacing, brain-imaging, field programmable gate arrays (FPGAs), near-infrared spectroscopy, real-time parameter estimation",

author = "Nazir, {Muhammad Shahid} and Abubakar Akram and Maheshwari, {Bhagesh Choudhry} and Hadi, {Muhammad Usman} and Muhammad Aqil and Haroon Khan",

year = "2017",

month = may,

day = "1",

doi = "10.1109/ICIEECT.2017.7916522",

language = "English",

isbn = "978-1-5090-3311-9",

booktitle = "ICIEECT 2017 - International Conference on Innovations in Electrical Engineering and Computational Technologies 2017, Proceedings",

publisher = "IEEE Signal Processing Society",

address = "United States",

note = "2017 International Conference on Innovations in Electrical Engineering and Computational Technologies, ICIEECT 2017 ; Conference date: 05-04-2017 Through 07-04-2017",

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Nazir, MS, Akram, A, Maheshwari, BC, Hadi, MU, Aqil, M & Khan, H 2017, Real-time brain activation detection by FPGA implemented adaptive algorithm. i ICIEECT 2017 - International Conference on Innovations in Electrical Engineering and Computational Technologies 2017, Proceedings., 7916522, IEEE Signal Processing Society, 2017 International Conference on Innovations in Electrical Engineering and Computational Technologies, ICIEECT 2017, Karachi, Pakistan, 05/04/2017. https://doi.org/10.1109/ICIEECT.2017.7916522

Real-time brain activation detection by FPGA implemented adaptive algorithm. / Nazir, Muhammad Shahid; Akram, Abubakar; Maheshwari, Bhagesh Choudhry et al.
ICIEECT 2017 - International Conference on Innovations in Electrical Engineering and Computational Technologies 2017, Proceedings. IEEE Signal Processing Society, 2017. 7916522.

Publikation: Bidrag til bog/antologi/rapport/konference proceeding › Konferenceartikel i proceeding › Forskning › peer review

TY - GEN

T1 - Real-time brain activation detection by FPGA implemented adaptive algorithm

AU - Nazir, Muhammad Shahid

AU - Akram, Abubakar

AU - Maheshwari, Bhagesh Choudhry

AU - Hadi, Muhammad Usman

AU - Aqil, Muhammad

AU - Khan, Haroon

PY - 2017/5/1

Y1 - 2017/5/1

N2 - This paper proposes a computationally efficient embedded system, implemented on field programmable gate arrays (FPGA), for real-time brain imaging. An RS-232 core is employed to obtain the brain data from a functional near-infrared spectroscopy (fNIRS) imaging modality on sample basis. A 32-bit floating point core (IEEE754) is developed on FPGA to manipulate floating point data with precision. Recursive least-squares estimation (RLSE) core is implemented on FPGA to facilitate computationally-efficient parallel adaptive processing (filtering) of multiple channels for real-time brain-activity estimation, for the first time as per our knowledge. The brain activation model and the methodology for its parameters' estimation by RLSE is depicted from Aqil et al., 2012 [2] and implemented on FPGA. The proposed embedded real-time methodology is demonstrated by instantiating eight RLSE cores on an FPGA board (Spartan-6 LX150T Development Kit) followed by its validation with an open source fNIRS dataset. The real-time results obtained with the proposed embedded system matches with the previously reported online results. Multiple RLSE cores can be instantiated, depending on the available resources of the FPGA, to process multiple channels concurrently.

AB - This paper proposes a computationally efficient embedded system, implemented on field programmable gate arrays (FPGA), for real-time brain imaging. An RS-232 core is employed to obtain the brain data from a functional near-infrared spectroscopy (fNIRS) imaging modality on sample basis. A 32-bit floating point core (IEEE754) is developed on FPGA to manipulate floating point data with precision. Recursive least-squares estimation (RLSE) core is implemented on FPGA to facilitate computationally-efficient parallel adaptive processing (filtering) of multiple channels for real-time brain-activity estimation, for the first time as per our knowledge. The brain activation model and the methodology for its parameters' estimation by RLSE is depicted from Aqil et al., 2012 [2] and implemented on FPGA. The proposed embedded real-time methodology is demonstrated by instantiating eight RLSE cores on an FPGA board (Spartan-6 LX150T Development Kit) followed by its validation with an open source fNIRS dataset. The real-time results obtained with the proposed embedded system matches with the previously reported online results. Multiple RLSE cores can be instantiated, depending on the available resources of the FPGA, to process multiple channels concurrently.

KW - Brain-computer interfacing

KW - brain-imaging

KW - field programmable gate arrays (FPGAs)

KW - near-infrared spectroscopy

KW - real-time parameter estimation

UR - http://www.scopus.com/inward/record.url?scp=85019980971&partnerID=8YFLogxK

U2 - 10.1109/ICIEECT.2017.7916522

DO - 10.1109/ICIEECT.2017.7916522

M3 - Article in proceeding

AN - SCOPUS:85019980971

SN - 978-1-5090-3311-9

BT - ICIEECT 2017 - International Conference on Innovations in Electrical Engineering and Computational Technologies 2017, Proceedings

PB - IEEE Signal Processing Society

T2 - 2017 International Conference on Innovations in Electrical Engineering and Computational Technologies, ICIEECT 2017

Y2 - 5 April 2017 through 7 April 2017

ER -

Real-time brain activation detection by FPGA implemented adaptive algorithm

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