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GCN- and GRU-Based Intelligent Model for Temperature Prediction of Local Heating Surfaces

Wanghu Chen, Chenhan Zhai, Xin Wang, Jing Li, Pengbo Lv, Chen Liu

2022IEEE Transactions on Industrial Informatics33 citationsDOIOpen Access PDF

Abstract

A boiler heating surface is composed of hundreds of tubes, whose temperatures may be different because of their positions, the influences of attempering water, and flue gas. Using a criteria based on the Davies–Bouldin index, in this article, we propose to partition a heating surface into local ones, whose interactions in temperature are represented as a weighted heating surface graph (HSG) at each point of time, and whose current features are embedded in the HSG's nodes. Then, a local heating surface temperature prediction model based on weighted graph convolutional networks and gated recurrent units (WGCN-GRU), is proposed. Graph convolutional networks (GCNs) receive a series of HSGs, and extract the features of local heating surfaces and their spatial dependences in a time window. Features output by GCNs are finally directed to GRUs for temperature predictions. Experiments show that WGCN-GRU can averagely maintain the prediction error below 0.5 °C. Compared with other models, it can reduce the errors by a rate from 5.6% to 46.8%, and shows advantages in root-mean-squared error and <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"><tex-math notation="LaTeX">$R^{2}$</tex-math></inline-formula> . It also shows that the node-to-node weights for the GCN can reduce the prediction error by 11.4%.

Topics & Concepts

Mean squared prediction errorAlgorithmMean squared errorGraphTemperature measurementNotationMathematicsComputer scienceStatisticsDiscrete mathematicsThermodynamicsPhysicsArithmeticEnergy Load and Power ForecastingTraffic Prediction and Management TechniquesStock Market Forecasting Methods