GLULA: Linear attention-based model for efficient human activity recognition from wearable sensors

IF 3.4 Q2 ENGINEERING, BIOMEDICAL
Aldiyar Bolatov, A. Yessenbayeva, Adnan Yazici
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引用次数: 0

Abstract

Body-worn sensor data is used in monitoring patient activity during rehabilitation and also can be extended to controlling rehabilitation devices based on the activity of the person. The primary focus of research has been on effectively capturing the spatiotemporal dependencies in the data collected by these sensors and efficiently classifying human activities. With the increasing complexity and size of models, there is a growing emphasis on optimizing their efficiency in terms of memory usage and inference time for real-time usage and mobile computers. While hybrid models combining convolutional and recurrent neural networks have shown strong performance compared to traditional approaches, self-attention-based networks have demonstrated even superior results. However, instead of relying on the same transformer architecture, there is an opportunity to develop a novel framework that incorporates recent advancements to enhance speed and memory efficiency, specifically tailored for human activity recognition (HAR) tasks. In line with this approach, we present GLULA, a unique architecture for HAR. GLULA combines gated convolutional networks, branched convolutions, and linear self-attention to achieve efficient and powerful solutions. To enhance the performance of our proposed architecture, we employed manifold mixup as an augmentation variant which proved beneficial in limited data settings. Extensive experiments were conducted on five benchmark datasets: PAMAP2, SKODA, OPPORTUNITY, DAPHNET, and USC-HAD. Our findings demonstrate that GLULA outperforms recent models in the literature on the latter four datasets but also exhibits the lowest parameter count and close to the fastest inference time among state-of-the-art models.
GLULA:从可穿戴传感器高效识别人类活动的线性注意力模型
体戴式传感器数据可用于监测康复过程中病人的活动,也可扩展到根据人的活动控制康复设备。研究的主要重点是有效捕捉这些传感器收集的数据中的时空相关性,并对人类活动进行有效分类。随着模型的复杂性和规模不断增加,人们越来越重视在内存使用和推理时间方面优化模型的效率,以满足实时使用和移动计算机的需求。与传统方法相比,结合了卷积和递归神经网络的混合模型表现出了强劲的性能,而基于自我注意的网络则表现出了更出色的效果。然而,与其依赖相同的变压器架构,我们有机会开发出一种新颖的框架,将最新的技术融入其中,提高速度和记忆效率,专门用于人类活动识别(HAR)任务。根据这种方法,我们提出了 GLULA,一种用于 HAR 的独特架构。GLULA 结合了门控卷积网络、分支卷积和线性自注意,以实现高效而强大的解决方案。为了提高我们提出的架构的性能,我们采用了流形混合作为增强变体,这在有限的数据设置中被证明是有益的。我们在五个基准数据集上进行了广泛的实验:PAMAP2、SKODA、OPPORTUNITY、DAPHNET 和 USC-HAD。我们的研究结果表明,在后四个数据集上,GLULA 的表现优于文献中的最新模型,而且在最先进的模型中,GLULA 的参数数量最少,推理时间接近最快。
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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来源期刊
CiteScore
5.80
自引率
0.00%
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0
审稿时长
11 weeks
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