Developing a computationally efficient but accurate building energy simulation (BES) model is important in order to accelerate building design optimizations, retrofit analysis, and development and evaluation of advanced control algorithms where a number of iterations over a long simulation period are required. For this purpose, identification approaches that develop simplified models from building simulation datasets could replace detailed energy simulation software. However, those approaches require extensive computational time at the front to generate necessary data sets and train models for sufficient reliability. An alternative approach that utilizes model order reduction (MOR) methods to directly extract a lower dimensional model from a detailed physics-based model consisting of a number of differential equations is attractive to avoid the pre-simulation requirement. Among many MOR approaches, the balanced truncation method has been most reliably and popularly applied to the building science field. However, it can not be practically applied to a large-scale building with many zones due to computational and data storage requirements. To overcome the problem, this paper introduces the Krylov subspace method to the building science field. Technical issues of applying the Krylov subspace method to building applications are addressed and a suitable algorithm that overcomes those challenges is presented. To demonstrate reliability of the algorithm, comparisons between the resulting reduced-order model (ROM) and a high fidelity model developed from a commercially available BES software for a 60-zone case study building are provided. The ROM was a factor of 100 faster than the high fidelity model but with high accuracy.
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