从数据分析到个人传感器数据的见解

A. Smeaton
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引用次数: 0

摘要

个人传感器现在无处不在,它们可以穿戴,可以携带,也可以在家里或工作场所固定。影响个人传感增长的主要因素包括它们更小,更智能,更便宜,需要更少的能源,并且与消费设备集成。个人传感的主要好处是在医疗保健部门,其次用于体育和表演以及对老年人等弱势群体的长期监测。那么我们通常如何处理个人感知产生的数据呢?我们计算步数,测量步行距离,计算能量消耗,评估睡眠质量,仅此而已。我们也可以纵向跟踪我们的行为并发现变化,但我们往往只在减肥或戒烟计划或改善食物摄入量等情况下才这样做。然后,在这样的激励场景之外,我们会感到无聊,并停止使用它们。有时,个人传感器通过让我们与他人竞争或为自己设定目标来利用人类行为的某些方面。Strava是一款用于跑步和骑行的传感器,它鼓励用户组成(虚拟)社区的一部分,并通过社交媒体与他人互动。除此之外,我们不会将我们的个人传感数据用于任何实际价值,例如监测我们的健康状况或构成我们年度医疗检查的一部分。事实上,人类的生活方式具有内在的各种频率的周期性。每日,每周,每月,季节性和年度。24小时的周期性是最重要的,对我们的24小时周期性的支配和破坏确实会对我们造成伤害。例如,时差干扰包括疲劳、不适和注意力不集中,所有这些都是由我们的昼夜节律偏离引起的。使用可穿戴传感器收集数据,我们可以检测到这些周期性。我们不仅可以检测,还可以测量在一段时间内,24小时周期的强度。利用从受试者身上收集的3个月的腕带加速度计数据,我们测量了他们24小时的周期性强度,并发现周期性强度的变化与一些心脏代谢生物标志物之间的相关性,这些生物标志物是与健康相关的生活质量指数,包括LDL胆固醇、甘油三酯、hc-CRP (c反应蛋白,炎症指标)。这是一个令人惊讶的结果,显示了基于加速度计数据驱动分析的心脏代谢健康反馈。这个例子突出表明,要真正最大化个人传感数据的价值,我们还有很多工作要做。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Insights from Data Analytics Into Our Personal Sensor Data
Personal sensors are now ubiquitous and they can be wearable, they can be carried or they can be in situ and fixed into our homes or workplaces. The major factors influencing the growth in personal sensing include that they are smaller, smarter, cheaper, require less energy and they integrate with consumer devices. The major benefits of personal sensing are in the healthcare sector with secondary uses in sports and performance and in long-term monitoring of vulnerable populations, like the aged. So what do we usually do with the data generated from personal sensing? We count steps taken, measure distance walked, add up energy expenditure, assess sleep quality and that's about it. We can also longitudinally track our behaviour and detect changes, but we tend to do this only for cases like following a weight loss or a smoking cessation program or improving our food intake. Then, outside such motivational scenarios, we get bored and stop using them. Sometimes personal sensors use aspects of human behaviour by engaging us in competitions with others, or setting goals for ourselves. Strava is an example sensor for running and cycling that encourages its users to form part of a (virtual) community and to engage with others through social media. Beyond that we do not use our personal sensing data for any real value, for example to monitor our health or to form part of our annual medical check-up, for example. It is a fact that human lifestyles have in-built periodicities of various frequencies... daily, weekly, monthly, seasonal, and annual. The 24h periodicity is the most important, and dominant and disruptions to our 24h periodicity do cause us harm. For example, jet lag disruption includes us fatigue, malaise and poor concentration, all caused by deviation from our circadian rhythm. Using wearable sensors to collect data we can detect these periodicities. Not only can we detect but we can also measure the strength or intensity of the 24h periodicity over a time period. Using wrist-worn accelerometer data gathered from subjects over a 3-month period we measured the strength of their 24h periodicity and found correlation between shifts in periodicity intensity and some cardio-metabolic biomarkers which are health-related quality of life indices including LDL cholesterol, triglycerides, hc-CRP (C-Reactive Proteins, indicators of inflammation). This is a surprising result showing cardio-metabolic health feedback based on data-driven analytics of accelerometer data. This example highlights that we have much more to do to really maximise value from personal sensing data.
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