1. Power Plant Data Filtering Based on Gaussian Naive Bayesian Classification and Prediction Error Method
- Author
-
Jiong Shen, Qianchao Wang, Nianci Lu, and Lei Pan
- Subjects
Imagination ,A priori probability ,Computer science ,business.industry ,Gaussian ,Mean squared prediction error ,media_common.quotation_subject ,010401 analytical chemistry ,System identification ,Pattern recognition ,02 engineering and technology ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,symbols.namesake ,Naive Bayes classifier ,symbols ,Artificial intelligence ,0210 nano-technology ,business ,Classifier (UML) ,media_common - Abstract
The sufficient utilization of the mega data acquired from operative power units is a promising way leading to high efficient, clean and safe operation of power plant. Hereinto, data filtering is a critical link to the data-driven dynamic model identification aiming at optimizing the process control. The machine learning is an advantageous approach for filtering usable data from mega databases for identification due to its effective statistical learning strategy to the field data with noises, disturbances and coupling quantities. Therefore, a data filtering method of combining Gaussian Naive Bayesian classifier and prediction error method (Gaussian NB-PEM) is proposed in this paper. Firstly, variables associated with identification model are selected by analyzing the characteristics of the process. Secondly, the GaussianNB classifier is used for coarse data filtering by calculating the priori probability of each attribute from training sample set and the probability with all possible values of the known categories for testing sample set. Thirdly, the prediction error method is used for further data filtering based on model fitting. By using the filtered closed-loop data, the dynamic characteristics of the superheated steam temperature is modeled and verified by closed-loop control simulation, showing the validity of the Gaussian NB-PEM data filtering method.
- Published
- 2019