Abstract
In this paper, we introduce AutoQual, a mobile-based assessment scheme for infrastructure sensing task performance prediction under new deployment environments. With the growth of the Internet-of-Things (IoT), many non-intrusive sensing systems have been explored for various indoor applications, such as structural vibration sensing. This indirect sensing approach’s learning performance is prone to deployment variance when signals propagate through the environment. As a result, current systems heavily rely on expert knowledge and manual assessment to achieve effective deployments and high sensing task performance. In order to mitigate this expert effort, we propose to systematically study factors that reflect deployment environment characteristics and methods to measure them autonomously. We present AutoQual that measures a series of assessment factors (AFs) reflecting how the deployment environment impacts the system performance. AutoQual outputs a task-oriented sensing quality (TSQ) score by integrating measured AFs trained from known deployments as a prediction of untested system’s performance. In addition, AutoQual achieves this assessment without manual effort by leveraging co-located mobile sensing context to extract structural vibration signal for processing automatically. We evaluate AutoQual by using it to predict untested systems’ performance over multiple sensing tasks. We conduct real-world experiments and investigate 48 deployments in 11 environments. AutoQual achieves less than 0.10 average absolute error when auto-assessing multiple tasks at untested deployments, which shows a le 0.018 absolute error difference compared to the manual assessment approach.
Highlights
IoT systems are becoming more and more pervasive in people’s daily life
– We present AutoQual, a framework of autonomous taskoriented sensing quality assessment that predicts the IoT system performance utilizing the mobility of ambient occupants
We consider the impact of AF1 is saturated, which we model with a saturation function—sigmoid
Summary
IoT systems are becoming more and more pervasive in people’s daily life. Due to their increasing applications and advantages in deployment (e.g., sparse, privacy preserving), many non-intrusive indirect sensing techniques are developed for indoor human information acquisition, including RF-, vibration-, light-based methods. The indirect sensing mechanisms of these systems induce large variances of the acquired data quality over deployment environment conditions and configurations, which reduces the system performance. The system’s information inference performance (e.g., detection rate, learning accuracy) is impacted by the deployment environment. To systematically understand these deployment environment impacts, we define sensing quality as a series of measurable factors/ models reflecting how they impact a given information inference task.
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