Pattern recognition for measuring the flame stability of gas-fired combustion based on the image processing technology

This study proposes a diagnostic method for gas-fired combustion based on the image processing technology, for identifying an abnormal combustion situation in a gaseous flame. The proposed algorithm is divided into four aspects: (1) a logarithmic entropy multi-threshold segmentation method for segme...

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Vydáno v:Fuel (Guildford) Ročník 270; s. 117486
Hlavní autoři: Wang, Yu, Yu, Yuefeng, Zhu, Xiaolei, Zhang, Zhongxiao
Médium: Journal Article
Jazyk:angličtina
Vydáno: Kidlington Elsevier Ltd 15.06.2020
Elsevier BV
Témata:
Algorithms
Combustion
Combustion diagnosis
Decision making
Diagnostic systems
Entropy
Feature extraction
Flame stability
Fuzzy pattern recognition
Gas-fired flame
Image processing
Image segmentation
Logarithmic entropy multi-threshold segmentation
Neural networks
Parameter identification
Pattern recognition
Q and T2
Self organizing maps
Support vector machines
Fuzzy pattern recognition
Logarithmic entropy multi-threshold segmentation
Combustion diagnosis
Q and T2
Gas-fired flame
ISSN:0016-2361, 1873-7153
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Shrnutí:This study proposes a diagnostic method for gas-fired combustion based on the image processing technology, for identifying an abnormal combustion situation in a gaseous flame. The proposed algorithm is divided into four aspects: (1) a logarithmic entropy multi-threshold segmentation method for segmenting the flame region utilized to extract image features; (2) 12 typical characteristic parameters representing gas-fired flame images, with five of them extracted for identification; (3) a fuzzy pattern recognition algorithm using an S-type membership function and a maximum-minimum distance function to distinguish between variable flame states; and (4) two statistics, Q and T2, used to evaluate the decision-making results of the fuzzy pattern recognition. The results are also compared to those from several other algorithms, including the self-organizing map, neural network, and support vector machine methods. The experimental results indicate that the proposed method has better performance in identifying different combustion situations in a gaseous flame and is superior to the other algorithms. Through a two-parameter adjustment, normal gas-fired combustion state can be accurately identified; for abnormal combustion, the prediction accuracy can become more than 90%. There can be a slight misjudgment; this may be owing to the relatively less training data for abnormal flame states.
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content type line 14
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2020.117486