Evaluation of methods for estimating autonomic nervous activity using a web camera

IF 0.8 Q4 ROBOTICS
Miku Shimizu, Yu Matsumoto, Naoaki Itakura, Kuzuyuki Mito, Tota Mizuno
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引用次数: 0

Abstract

There is an increasing need for methods to estimate autonomic nerve activity, such as using autonomic nerve activity as an indicator of stress and to improve the activity environment, such that people can live more comfortably. In a previous study, a method for estimating autonomic nervous activity using facial thermal images was established. Such activity was evaluated by obtaining the differential temperature of the nasal region, which is a sympathetic index of autonomic nervous activity, and the less-affected forehead region. However, this method requires the use of an expensive far-infrared camera, which is difficult to obtain and is cited as a problem. Another study suggested acquiring pulse waves and heartbeats by obtaining changes in blood flow from the heart using real facial images. This was obtained using independent component analysis for each Red–Green–Blue (RGB [color model]) component value of the real image. However, the problem with this method is that it cannot evaluate autonomic nerve activity, such as thermal images, because it cannot examine changes in the blood flow in peripheral blood vessels. Therefore, in this study, a method for estimating autonomic nerve activity is proposed, with the same accuracy as thermal images, by obtaining changes in peripheral blood flow from real images taken with an easily usable web camera. To obtain the changes in peripheral blood flow from real images, we used the property that the incident depth of light entering the skin differs depending on the color component. By considering the difference between the R component (which enters the skin at the deepest depth) and the B component (which is almost reflected by the epidermis), we assumed that we could capture the blood flow in the widest range and measure the change in blood flow in the peripheral vasculature. To cause unpleasant irritation, an experiment was conducted in which participants performed a randomly assigned memorization task for 10 min. A rest period of 1 min was provided before and after the mental calculation task, and a subjective evaluation questionnaire was administered during the rest period and before the mental calculation task. The results showed that some subjects exhibited a significant decrease in the R-B component values when they noticed calculation errors, whereas others exhibited an increase in the R-B component values after completing the memorization task. Also, some subjects showed a correspondence between the variation of R-B component values and the results of the questionnaire. Additionally, compared to the conventional method, it was clear that we could obtain real-time and even fine variations in response to event switching. These results suggest that it is possible to evaluate autonomic nervous system activity from real image data to the same extent as from thermal images.

Abstract Image

使用网络摄像机评估自主神经活动的方法
人们越来越需要估计自主神经活动的方法,例如使用自主神经活动作为压力的指标,并改善活动环境,使人们能够生活得更舒适。在之前的一项研究中,建立了一种使用面部热图像估计自主神经活动的方法。通过获得鼻腔区域和受影响较小的前额区域的温差来评估这种活动,鼻腔区域是自主神经活动的交感指数。然而,这种方法需要使用昂贵的远红外相机,这很难获得,并且被认为是一个问题。另一项研究建议,通过使用真实的面部图像获取心脏血流的变化来获取脉搏波和心跳。这是使用真实图像的每个红-绿-蓝(RGB[颜色模型])分量值的独立分量分析获得的。然而,这种方法的问题是,它无法评估自主神经活动,如热图像,因为它无法检查外周血管中血流的变化。因此,在这项研究中,提出了一种估计自主神经活动的方法,其精度与热图像相同,方法是从使用易于使用的网络相机拍摄的真实图像中获得外周血流量的变化。为了从真实图像中获得外周血流量的变化,我们使用了进入皮肤的光的入射深度根据颜色成分而不同的特性。通过考虑R成分(在最深的深度进入皮肤)和B成分(几乎被表皮反射)之间的差异,我们假设我们可以在最宽的范围内捕捉血流,并测量外周血管系统中血流的变化。为了引起不愉快的刺激,进行了一项实验,参与者执行随机分配的记忆任务10分钟。在心理计算任务前后提供1分钟的休息时间,并在休息时间和心理计算任务之前进行主观评估问卷。结果表明,当一些受试者注意到计算错误时,他们的R-B分量值显著降低,而另一些受试在完成记忆任务后,他们的R-B分量值增加。此外,一些受试者表现出R-B成分值的变化与问卷结果之间的对应关系。此外,与传统方法相比,很明显,我们可以获得响应事件切换的实时甚至精细变化。这些结果表明,从真实图像数据中评估自主神经系统活动的程度与从热图像中评估的程度相同是可能的。
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来源期刊
CiteScore
2.00
自引率
22.20%
发文量
101
期刊介绍: Artificial Life and Robotics is an international journal publishing original technical papers and authoritative state-of-the-art reviews on the development of new technologies concerning artificial life and robotics, especially computer-based simulation and hardware for the twenty-first century. This journal covers a broad multidisciplinary field, including areas such as artificial brain research, artificial intelligence, artificial life, artificial living, artificial mind research, brain science, chaos, cognitive science, complexity, computer graphics, evolutionary computations, fuzzy control, genetic algorithms, innovative computations, intelligent control and modelling, micromachines, micro-robot world cup soccer tournament, mobile vehicles, neural networks, neurocomputers, neurocomputing technologies and applications, robotics, robus virtual engineering, and virtual reality. Hardware-oriented submissions are particularly welcome. Publishing body: International Symposium on Artificial Life and RoboticsEditor-in-Chiei: Hiroshi Tanaka Hatanaka R Apartment 101, Hatanaka 8-7A, Ooaza-Hatanaka, Oita city, Oita, Japan 870-0856 ©International Symposium on Artificial Life and Robotics
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