Rule-base wearable embedded platform for seizure detection from real EEG data in ambulatory state

2014 IEEE REGION 10 SYMPOSIUM Pub Date : 2014-04-14 DOI:10.1109/TENCONSPRING.2014.6862995

M. Shakir, A. Malik, N. Kamel, U. Qidwai

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引用次数: 1

Abstract

This paper describes a classification method is presented using an empirical Rule-base System to detect the occurrences of Partial Seizures from Epilepsy data, which can be implemented in any embedded system as a wearable detection system. The system distinguishes between `Normal' and `Seizure' state using on-the-fly calculated features representing the statistical measures for specifically filtered signals from the raw data. It was noticed that for a large number of cases, the seizure waveforms manifest higher energy components during the seizure episodes as compared to the normal brain activity in specific bands of frequencies. Same is also true in the reverse fashion for a separate band of frequency that changes the energy levels from higher to lower when a patient goes from Normal to a Seizure state. This fact has been exploited in this paper and filter has been developed to isolate the seizure band. The rule base has been developed on the calculated measures for the filtered signal from this band-filter and classification is performed on the basis of certain empirical thresholds. Since the complexity of calculations have been deliberately kept quite low, the algorithm is highly suitable for implementation in a small micro-controller environment with near-real-time operation. This gives an enhanced advantage over the existing EEG based seizure detection systems due to their complex pattern classification methodologies. Based on the presented technique, a wearable ubiquitous system can be easily developed with applications in personal healthcare and clinical usage. In this case, the users are not necessarily restricted to the clinical environment in which many devices are connected to the patient externally. The wearable devices allow the user to continue daily activities while being monitored for seizure activities. Once seizure is detected, a number of possible usages can be employed such as alerting the user while driving/holding a baby etc.

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基于规则的可穿戴嵌入式平台，用于从动态状态的真实脑电图数据中检测癫痫发作

本文描述了一种基于经验规则的系统的分类方法，用于从癫痫数据中检测部分癫痫发作的发生，该方法可以作为可穿戴检测系统在任何嵌入式系统中实现。该系统使用实时计算的特征来区分“正常”和“癫痫”状态，这些特征代表了从原始数据中特定过滤信号的统计度量。我们注意到，在许多情况下，与正常大脑活动在特定频段的频率相比，癫痫发作时的波形表现出更高的能量成分。当病人从正常状态转到癫痫状态时，另一种频率的能量水平由高到低的变化也是如此。本文利用了这一事实，并开发了滤波器来隔离扣押带。该规则库是根据该带滤波器滤波后信号的计算测度建立的，并根据一定的经验阈值进行分类。由于计算的复杂性被刻意地保持在相当低的水平，因此该算法非常适合在小型微控制器环境中实现，具有接近实时的操作。由于其复杂的模式分类方法，与现有的基于脑电图的癫痫检测系统相比，这具有增强的优势。基于该技术，可轻松开发出可穿戴的无所不在系统，并可用于个人医疗保健和临床应用。在这种情况下，用户不一定局限于临床环境，其中许多设备从外部连接到患者。可穿戴设备允许用户在监测癫痫发作活动的同时继续进行日常活动。一旦检测到癫痫发作，可以采用许多可能的用途，例如在驾驶/抱着婴儿等时提醒用户。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2014 IEEE REGION 10 SYMPOSIUM

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