Calibrating building energy models using supercomputer trained machine learning agents

SUMMARYBuilding energy modeling (BEM) is an approach to model the energy usage in buildings for design and retrofit purposes. EnergyPlus is the flagship Department of Energy software that performs BEM for different types of buildings. The input to EnergyPlus can often extend in the order of a few th...

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Veröffentlicht in:	Concurrency and computation 2014-09, Vol.26 (13), p.2122-2133
Hauptverfasser:	Sanyal, Jibonananda, New, Joshua, Edwards, Richard E., Parker, Lynne
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Sprache:	eng
Schlagworte:	big data Boundary element method building energy modeling Buildings Calibration Construction Construction equipment machine learning Mathematical analysis Mathematical models parametric ensemble supercomputer Supercomputers
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container_title	Concurrency and computation
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creator	Sanyal, Jibonananda New, Joshua Edwards, Richard E. Parker, Lynne
description	SUMMARYBuilding energy modeling (BEM) is an approach to model the energy usage in buildings for design and retrofit purposes. EnergyPlus is the flagship Department of Energy software that performs BEM for different types of buildings. The input to EnergyPlus can often extend in the order of a few thousand parameters that have to be calibrated manually by an expert for realistic energy modeling. This makes it challenging and expensive thereby making BEM unfeasible for smaller projects. In this paper, we describe the ‘Autotune’ research that employs machine learning algorithms to generate agents for the different kinds of standard reference buildings in the US building stock. The parametric space and the variety of building locations and types make this a challenging computational problem necessitating the use of supercomputers. Millions of EnergyPlus simulations are run on supercomputers that are subsequently used to train machine learning algorithms to generate agents. These agents, once created, can then run in a fraction of the time thereby allowing cost‐effective calibration of building models. Published 2014. This article is a US Government work and is in the public domain in the USA.
doi_str_mv	10.1002/cpe.3267
format	Article
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subjects	big data Boundary element method building energy modeling Buildings Calibration Construction Construction equipment machine learning Mathematical analysis Mathematical models parametric ensemble supercomputer Supercomputers
title	Calibrating building energy models using supercomputer trained machine learning agents
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