CogWatch: An open-source platform to monitor physiological indicators for cognitive workload and stress

IF 2.1 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC HardwareX Pub Date : 2024-09-01 Epub Date: 2024-05-23 DOI:10.1016/j.ohx.2024.e00538

Louis J. Dankovich IV , Janell S. Joyner , William He , Ahmad Sesay , Monifa Vaughn-Cooke

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Abstract

Cognitive workload is a measure of the mental resources a user is dedicating to a given task. Low cognitive workload produces boredom and decreased vigilance, which can lead to an increase in response time. Under high cognitive workload the information processing burden of the user increases significantly, thereby compromising the ability to effectively monitor their environment for unexpected stimuli or respond to emergencies.

In cognitive workload and stress monitoring research, sensors are used to measure applicable physiological indicators to infer the state of user. For example, electrocardiography or photoplethysmography are often used to track both the rate at which the heart beats and variability between the individual heart beats. Photoplethysmography and chest straps are also used in studies to track fluctuations in breathing rate. The Galvanic Skin Response is a change in sweat rate (especially on the palms and wrists) and is typically measured by tracking how the resistance of two probes at a fixed distance on the subject's skin changes over time. Finally, fluctuations in Skin Temperature are typically tracked with thermocouples or infrared light (IR) measuring systems in these experiments. While consumer options such a smartwatches for health tracking often have the integrated ability to perform photoplethysmography, they typically perform significant processing on the data which is not transparent to the user and often have a granularity of data that is far too low to be useful for research purposes. It is possible to purchase sensor boards that can be added to Arduino systems, however, these systems generally are very large and obtrusive. Additionally, at the high end of the spectrum there are medical tools used to track these physiological signals, but they are often very expensive and require specific software to be licensed for communication. In this paper, an open-source solution to create a physiological tracker with a wristwatch form factor is presented and validated, using conventional off-the-shelf components. The proposed tool is intended to be applied as a cost-effective solution for research and educational settings.

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CogWatch：监测认知工作量和压力生理指标的开源平台

认知工作量是衡量用户在特定任务中投入的精神资源的一个指标。认知工作量低时，用户会感到无聊，警惕性降低，从而导致响应时间增加。在认知工作量大的情况下，用户的信息处理负担会大大增加，从而影响其有效监控环境中的意外刺激或应对紧急情况的能力。例如，心电图或光敏血压计通常用于跟踪心脏跳动的频率和单个心脏跳动之间的变化。在研究中还会用到光敏血压计和胸带来追踪呼吸频率的波动。皮肤电化反应（Galvanic Skin Response）是指出汗率的变化（尤其是手掌和手腕），通常是通过跟踪受试者皮肤上固定距离的两个探头的电阻随时间的变化来测量的。最后，在这些实验中，通常使用热电偶或红外光（IR）测量系统跟踪皮肤温度的波动。虽然用于健康追踪的智能手表等消费类产品通常都具有执行光敏血压计的集成能力，但它们通常会对数据进行大量处理，而这些处理对用户来说并不透明，而且数据粒度通常太低，无法用于研究目的。可以购买可添加到 Arduino 系统中的传感器板，但这些系统一般都非常庞大和碍眼。此外，还有一些高端的医疗工具可用于跟踪这些生理信号，但它们通常非常昂贵，而且需要获得特定软件的通信许可。本文介绍并验证了一种开源解决方案，即使用传统的现成组件，创建一个具有手表外形尺寸的生理跟踪器。所建议的工具将作为一种经济有效的解决方案应用于研究和教育环境。

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来源期刊

HardwareX Engineering-Industrial and Manufacturing Engineering

CiteScore

4.10

自引率

18.20%

发文量

124

审稿时长

24 weeks

期刊介绍： HardwareX is an open access journal established to promote free and open source designing, building and customizing of scientific infrastructure (hardware). HardwareX aims to recognize researchers for the time and effort in developing scientific infrastructure while providing end-users with sufficient information to replicate and validate the advances presented. HardwareX is open to input from all scientific, technological and medical disciplines. Scientific infrastructure will be interpreted in the broadest sense. Including hardware modifications to existing infrastructure, sensors and tools that perform measurements and other functions outside of the traditional lab setting (such as wearables, air/water quality sensors, and low cost alternatives to existing tools), and the creation of wholly new tools for either standard or novel laboratory tasks. Authors are encouraged to submit hardware developments that address all aspects of science, not only the final measurement, for example, enhancements in sample preparation and handling, user safety, and quality control. The use of distributed digital manufacturing strategies (e.g. 3-D printing) is encouraged. All designs must be submitted under an open hardware license.