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Hauptverfasser: Taufique, Zain, Altaf, Muhammad Awais Bin, Miele, Antonio, Liljeberg, Pasi, Kanduri, Anil
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2402.09867
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author Taufique, Zain
Altaf, Muhammad Awais Bin
Miele, Antonio
Liljeberg, Pasi
Kanduri, Anil
author_facet Taufique, Zain
Altaf, Muhammad Awais Bin
Miele, Antonio
Liljeberg, Pasi
Kanduri, Anil
contents Electroencephalography (EEG) recordings are analyzed using battery-powered wearable devices to monitor brain activities and neurological disorders. These applications require long and continuous processing to generate feasible results. However, wearable devices are constrained with limited energy and computation resources, owing to their small sizes for practical use cases. Embedded heterogeneous multi-core platforms (HMPs) can provide better performance within limited energy budgets for EEG applications. Error resilience of the EEG application pipeline can be exploited further to maximize the performance and energy gains with HMPs. However, disciplined tuning of approximation on embedded HMPs requires a thorough exploration of the accuracy-performance-power trade-off space. In this work, we characterize the error resilience of three EEG applications, including Epileptic Seizure Detection, Sleep Stage Classification, and Stress Detection on the real-world embedded HMP test-bed of the Odroid XU3 platform. We present a combinatorial evaluation of power-performance-accuracy trade-offs of EEG applications at different approximation, power, and performance levels to provide insights into the disciplined tuning of approximation in EEG applications on embedded platforms.
format Preprint
id arxiv_https___arxiv_org_abs_2402_09867
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Characterizing Accuracy Trade-offs of EEG Applications on Embedded HMPs
Taufique, Zain
Altaf, Muhammad Awais Bin
Miele, Antonio
Liljeberg, Pasi
Kanduri, Anil
Signal Processing
Artificial Intelligence
Computer Vision and Pattern Recognition
Machine Learning
Performance
Electroencephalography (EEG) recordings are analyzed using battery-powered wearable devices to monitor brain activities and neurological disorders. These applications require long and continuous processing to generate feasible results. However, wearable devices are constrained with limited energy and computation resources, owing to their small sizes for practical use cases. Embedded heterogeneous multi-core platforms (HMPs) can provide better performance within limited energy budgets for EEG applications. Error resilience of the EEG application pipeline can be exploited further to maximize the performance and energy gains with HMPs. However, disciplined tuning of approximation on embedded HMPs requires a thorough exploration of the accuracy-performance-power trade-off space. In this work, we characterize the error resilience of three EEG applications, including Epileptic Seizure Detection, Sleep Stage Classification, and Stress Detection on the real-world embedded HMP test-bed of the Odroid XU3 platform. We present a combinatorial evaluation of power-performance-accuracy trade-offs of EEG applications at different approximation, power, and performance levels to provide insights into the disciplined tuning of approximation in EEG applications on embedded platforms.
title Characterizing Accuracy Trade-offs of EEG Applications on Embedded HMPs
topic Signal Processing
Artificial Intelligence
Computer Vision and Pattern Recognition
Machine Learning
Performance
url https://arxiv.org/abs/2402.09867