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Efficient approximation of action potentials with high-order shape preservation in unsupervised spike sorting

Efficient approximation of action potentials with high-order shape preservation in unsupervised spike sorting
Efficient approximation of action potentials with high-order shape preservation in unsupervised spike sorting
This paper presents a novel approximation unit added to the conventional spike processing chain which provides an appreciable reduction of complexity of the high-hardware cost feature extractors. The use of the Taylor polynomial is proposed and modelled employing its cascaded derivatives to non-uniformly capture the essential samples in each spike for reliable feature extraction and sorting. Inclusion of the approximation unit can provide 3X compression (i.e. from 66 to 22 samples) to the spike waveforms while preserving their shapes. Detailed spike waveform sequences based on in-vivo measurements have been generated using a customized neural simulator for performance assessment of the approximation unit tested on six published feature extractors. For noise levels σN between 0.05 and 0.3 and groups of 3 spikes in each channel, all the feature extractors provide almost same sorting performance before and after approximation. The overall implementation cost when including the approximation unit and feature extraction shows a large reduction (i.e. up to 8.7X) in the hardware costly and more accurate feature extractors, offering a substantial improvement in feature extraction design.
4884-4887
IEEE
Zamani, Majid
9934f763-9fa9-4be3-889d-69e6b447ec87
Okreghe, Christian
91754d88-d49c-4bef-85a4-07ec9869b902
Demosthenous, Andreas
bed19531-d770-4f48-8464-59d225ddea8d
Zamani, Majid
9934f763-9fa9-4be3-889d-69e6b447ec87
Okreghe, Christian
91754d88-d49c-4bef-85a4-07ec9869b902
Demosthenous, Andreas
bed19531-d770-4f48-8464-59d225ddea8d

Zamani, Majid, Okreghe, Christian and Demosthenous, Andreas (2022) Efficient approximation of action potentials with high-order shape preservation in unsupervised spike sorting. In 2022 44th Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC). IEEE. pp. 4884-4887 . (doi:10.1109/EMBC48229.2022.9871487).

Record type: Conference or Workshop Item (Paper)

Abstract

This paper presents a novel approximation unit added to the conventional spike processing chain which provides an appreciable reduction of complexity of the high-hardware cost feature extractors. The use of the Taylor polynomial is proposed and modelled employing its cascaded derivatives to non-uniformly capture the essential samples in each spike for reliable feature extraction and sorting. Inclusion of the approximation unit can provide 3X compression (i.e. from 66 to 22 samples) to the spike waveforms while preserving their shapes. Detailed spike waveform sequences based on in-vivo measurements have been generated using a customized neural simulator for performance assessment of the approximation unit tested on six published feature extractors. For noise levels σN between 0.05 and 0.3 and groups of 3 spikes in each channel, all the feature extractors provide almost same sorting performance before and after approximation. The overall implementation cost when including the approximation unit and feature extraction shows a large reduction (i.e. up to 8.7X) in the hardware costly and more accurate feature extractors, offering a substantial improvement in feature extraction design.

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More information

e-pub ahead of print date: 8 September 2022
Published date: 2022
Venue - Dates: 44th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, EMBC 2022, , Glasgow, United Kingdom, 2022-07-11 - 2022-07-15

Identifiers

Local EPrints ID: 489231
URI: http://eprints.soton.ac.uk/id/eprint/489231
PURE UUID: d12daca6-9a33-4d91-bb15-9c1f348b7be9

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Date deposited: 18 Apr 2024 16:36
Last modified: 29 Apr 2024 16:35

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Contributors

Author: Majid Zamani
Author: Christian Okreghe
Author: Andreas Demosthenous

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