Abstract
Proactive monitoring and control of our natural and built environments is important in various application scenarios. Semantic Sensor Web technologies have been well researched and used for environmental monitoring applications to expose sensor data for analysis in order to provide responsive actions in situations of interest. While these applications provide quick response to situations, to minimize their unwanted effects, research efforts are still necessary to provide techniques that can anticipate the future to support proactive control, such that unwanted situations can be averted altogether. This study integrates a statistical machine learning based predictive model in a Semantic Sensor Web using stream reasoning. The approach is evaluated in an indoor air quality monitoring case study. A sliding window approach that employs the Multilayer Perceptron model to predict short term PM pollution situations is integrated into the proactive monitoring and control framework. Results show that the proposed approach can effectively predict short term PM pollution situations: precision of up to 0.86 and sensitivity of up to 0.85 is achieved over half hour prediction horizons, making it possible for the system to warn occupants or even to autonomously avert the predicted pollution situations within the context of Semantic Sensor Web.
Highlights
Proactive monitoring of the natural and built environments is important in many day to day application scenarios in order to take control of environmental situations
When a “Poor” state is correctly classified as “Poor”, it is regarded as true positive (TP), and when a “Good” state is correctly classified as “Good”, it is regarded as true negative (TN)
We have presented an approach to achieve proactive monitoring and control in the Semantic
Summary
Proactive monitoring of the natural and built environments is important in many day to day application scenarios in order to take control of environmental situations. Such application areas include preventing natural disasters, avoiding life threatening situations, enhancing productivity and improving health and well-being. Sensors 2017, 17, 807 the gap between the virtual and the physical world by making sensor equipped computing devices understand the environment, anticipate the user’s goal and act on his or her behalf [2,3]. To provide more expressive descriptions and enhanced access to sensor data on the web, the Semantic Sensor Web (SSW) initiative aims to extend SWE with Semantic Web technologies [5]
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