Abstract
Smart buildings with connected lighting and sensors are likely to become one of the first large-scale applications of the Internet of Things (IoT). However, as the number of interconnected IoT devices is expected to rise exponentially, the amount of collected data will be enormous but highly redundant. Devices will be required to pre-process data locally or at least in their vicinity. Thus, local data fusion, subject to constraint communications will become necessary. In that sense, distributed architectures will become increasingly unavoidable. Anticipating this trend, this paper addresses the problem of presence detection in a building as a distributed sensing of a hidden Markov model (DS-HMM) with limitations on the communication. The key idea in our work is the use of a posteriori probabilities or likelihood ratios (LR) as an appropriate “interface” between heterogeneous sensors with different error profiles. We propose an efficient transmission policy, jointly with a fusion algorithm, to merge data from various HMMs running separately on all sensor nodes but with all the models observing the same Markovian process. To test the feasibility of our DS-HMM concept, a simple proof-of-concept prototype was used in a typical office environment. The experimental results show full functionality and validate the benefits. Our proposed scheme achieved high accuracy while reducing the communication requirements. The concept of DS-HMM and a posteriori probabilities as an interface is suitable for many other applications for distributed information fusion in wireless sensor networks.
Highlights
Smart buildings are becoming a reality thanks to the availability of low-cost, easy to install Internet of Things (IoT) devices, such as sensors and actuators
The experiment is limited to only two USR sensors, the goal of our work is to expect that system detection performance can be significantly improved by using heterogeneous provide a common platform that allows the combination of multiple sensing modalities
It is attractive to complement this with a USR sensor that detects distance (and infrared (PIR) motion sensor that offers high reliability in detecting motion but fails to detect actual we expect that system detection performance can be significantly improved by using heterogeneous sensing modalities, each with different error and reliability profiles capabilities, for example a passive infrared (PIR) motion sensor that offers high reliability in detecting motion but fails to detect actual occupancy
Summary
Smart buildings are becoming a reality thanks to the availability of low-cost, easy to install Internet of Things (IoT) devices, such as sensors and actuators. An extensive amount of research has been dedicated to developing occupancy-based control systems that exploit information on user presence to dynamically adjust energy-related appliances and building systems (HVAC, lighting, or other appliances) Those systems are based on a network of IoT-enabled sensor devices that continuously monitor the space with the aim to provide real-time information on user occupation. SCOPES, a distributed smart cameras object position estimation system [1], uses real-time occupancy data to create predictive occupancy models [2] Those models can be integrated into a building conditioning system for usage-based demand control conditioning strategies, most notably HVAC and lighting. Wireless, binary sensors are preferred, which are easy to retrofit in existing buildings and comply with the existing privacy regulations
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
