Abstract
Considering the advances in building monitoring and control through networks of interconnected devices, effective handling of the associated rich data streams is becoming an important challenge. In many situations, the application of conventional system identification or approximate grey-box models, partly theoretic and partly data driven, is either unfeasible or unsuitable. The paper discusses and illustrates an application of black-box modelling achieved using data mining techniques with the purpose of smart building ventilation subsystem control. We present the implementation and evaluation of a data mining methodology on collected data from over one year of operation. The case study is carried out on four air handling units of a modern campus building for preliminary decision support for facility managers. The data processing and learning framework is based on two steps: raw data streams are compressed using the Symbolic Aggregate Approximation method, followed by the resulting segments being input into a Support Vector Machine algorithm. The results are useful for deriving the behaviour of each equipment in various modi of operation and can be built upon for fault detection or energy efficiency applications. Challenges related to online operation within a commercial Building Management System are also discussed as the approach shows promise for deployment.
Highlights
We focus on the application of such advanced data processing techniques in the field of building automation Journal of Sensors systems (BAS)
The preprocessed time series are represented into an aggregate form, initially through numeric Piecewise Aggregate Approximation (PAA) segments followed by symbolic SAX
One of the key tuning parameters is the number of segments for the daily representation of each time series and the alphabet size into which these segments are codified by SAX
Summary
We view and define smartness by having the building comply to the dual objectives of occupant awareness and energy efficiency, achieved by modelling, simulation, and control over the network of field devices and controllers. This leads to increased requirements on the control strategies to balance in an online manner the needs of the building users for comfort with the needs of the building operator for reduced costs. Dynamic energy pricing and electrical grid balancing constraints impose real-time requirements which are often addressed by means of demand response (DR) schemes
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