Epilepsy is a chronic neurological disorder with a significant prevalence. However, there is still no adequate technological support to enable epilepsy detection and continuous outpatient monitoring in everyday life. Hyperdimensional (HD) computing is an interesting alternative for wearable devices, characterized by a much simpler learning process and also lower memory requirements. In this work, we demonstrate a few additional aspects in which HD computing, and the way its models are built and stored, can be used for further understanding, comparing, and creating more advanced machine learning models for epilepsy detection. These possibilities are not feasible with other state-of-the-art models, such as random forests or neural networks. We compare inter-subject similarity of models per different classes (seizure and non-seizure), then study the process of creation of generalized models from personalized ones, and in the end, how to combine personalized and generalized models to create hybrid models. This results in improved epilepsy detection performance. We also tested knowledge transfer between models created on two different datasets. Finally, all those examples could be highly interesting not only from an engineering perspective to create better models for wearables, but also from a neurological perspective to better understand individual epilepsy patterns.
翻译:癫痫是一种具有显著患病率的慢性神经系统疾病。然而,目前还没有足够的技术支持,能够在日常生活中实现癫痫检测和连续门诊监测。超维计算是可穿戴设备的一种有趣的替代方案,具有更简单的学习过程和更低的内存需求。在这项工作中,我们展示了超维计算的一些额外方面,以及超维计算及其构建和存储模型的方法如何用于进一步理解、比较和创建更先进的机器学习模型以进行癫痫检测。这些机会是其他最先进模型如随机森林或神经网络所无法实现的。我们比较了不同类别(癫痫发作和非癫痫发作)模型间的个体间相似性,然后研究了如何从个性化模型中创建广义模型的过程,在最后,研究了如何结合个性化和广义模型创建混合模型。这导致了改进的癫痫检测性能。我们还测试了两个不同数据集上创建的模型之间的知识转移。最后,所有这些例子不仅从工程角度创建更好的可穿戴设备模型是高度有趣的,而且从神经学角度更好地了解个体癫痫模式是非常有意义的。