An Unsupervised Classification Method for Flame Image of Pulverized Coal Combustion Based on Convolutional Auto-Encoder and Hidden Markov Model

Qiu, Tian; Liu, Minjian; Zhou, Guiping; Wang, Li; Gao, Kai

doi:10.3390/en12132585

Cited by 36 publications

(21 citation statements)

References 19 publications

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“…One of the applications in which these networks perform particularly well is the detection of anomalies in the time series of different signals. 32–36 In the study, we utilised three types of DRNNs. They are as follows: LSTM recurrent neural network, one-dimensional (1D) convolutional neural network LSTM (CNN-LSTM) and 1D convolutional LSTM (ConvLSTM).…”

Section: Methodsmentioning

confidence: 99%

“…Gangopadhyay et al 14 leveraged images from hi-speed flame videos as well as the sound pressure data for detecting instability in an experimental combustion system. Qiu et al 15 used uniformly spaced flame images in recognition of the pulverised coal (PC) combustion status (stable, semi-stable and unstable) in the thermal power plant. Liu et al 16 used a deep belief network to predict the oxygen content at the combustion system outlet.…”

Section: Introductionmentioning

confidence: 99%

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Combustion process monitoring based on flame intensity time series

Omiotek

Smolarz

2020

Proceedings of the Institution of Mechanical Engineers, Part I:

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The pulverised coal and its mixture with biomass are one of the most popular fuels in industrial energy. To ensure, on one hand, minimal greenhouse gas emission and, on the other hand, maximum energy production efficiency, it is necessary to monitor the combustion process of these fuels. One way to do this is to monitor the flame intensity. This is an optical, non-invasive solution, and information on the status of the process is obtained with minimal delay. The article proposes a method for identifying undesired combustion states for which the excess air coefficient is greater or smaller than the value ensuring total combustion. Three deep recurrent neural network architectures for classifying the flame intensity time series were explored. The best results were obtained using the convolutional long short-term memory model, which offered the accuracy of 86.5%–99.8%, depending on the current thermal power. The prediction time of a single data sequence was about 0.6 ms. High accuracy and low time consumption of the proposed method create an opportunity for its use in industrial combustion systems of pulverised coal and its mixture with biomass.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Combustion process monitoring based on flame intensity time series

Omiotek

Smolarz

2020

Proceedings of the Institution of Mechanical Engineers, Part I:

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“…A large number of existing studies have shown that deep learning-based classification method has good classification performance, and has achieved great success in computer vision, image processing and other fields. Some representative deep learning techniques include convolutional neural network (CNN) [9,10], recurrent neural network (RNN) [11,12], generative adversarial network [13,14] and convolutional auto-encoder [15,16]. Recently, a series of deep learning-based classification frameworks have been widely used in the field of remote sensing [17][18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Hyperspectral Image Classification Based on Superpixel Pooling Convolutional Neural Network with Transfer Learning

et al. 2021

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Deep learning-based hyperspectral image (HSI) classification has attracted more and more attention because of its excellent classification ability. Generally, the outstanding performance of these methods mainly depends on a large number of labeled samples. Therefore, it still remains an ongoing challenge how to integrate spatial structure information into these frameworks to classify the HSI with limited training samples. In this study, an effective spectral-spatial HSI classification scheme is proposed based on superpixel pooling convolutional neural network with transfer learning (SP-CNN). The suggested method includes three stages. The first part consists of convolution and pooling operation, which is a down-sampling process to extract the main spectral features of an HSI. The second part is composed of up-sampling and superpixel (homogeneous regions with adaptive shape and size) pooling to explore the spatial structure information of an HSI. Finally, the hyperspectral data with each superpixel as a basic input rather than a pixel are fed to fully connected neural network. In this method, the spectral and spatial information is effectively fused by using superpixel pooling technique. The use of popular transfer learning technology in the proposed classification framework significantly improves the training efficiency of SP-CNN. To evaluate the effectiveness of the SP-CNN, extensive experiments were conducted on three common real HSI datasets acquired from different sensors. With 30 labeled pixels per class, the overall classification accuracy provided by this method on three benchmarks all exceeded 93%, which was at least 4.55% higher than that of several state-of-the-art approaches. Experimental and comparative results prove that the proposed algorithm can effectively classify the HSI with limited training labels.

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“…Various architectures of such networks have been developed, and many of them achieve excellent performance in image recognition tasks, including flame images. Examples include deep convolutional neural networks [ 2 , 3 , 4 , 5 , 6 ], deep belief networks [ 7 , 8 ], deep convolutional auto-encoder [ 9 ], deep convolutional auto-encoder connected with the principal component analysis and the hidden Markov model [ 10 ], deep, fully connected neural networks [ 11 ], deep convolutional selective autoencoder [ 12 ] and various architectures followed by a symbolic time series analysis [ 13 , 14 ]. Each of the architectures mentioned above plays a vital role in a specific application area.…”

Section: Introductionmentioning

confidence: 99%

Flame Image Processing and Classification Using a Pre-Trained VGG16 Model in Combustion Diagnosis

Omiotek

Kotyra

2021

Sensors

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Nowadays, despite a negative impact on the natural environment, coal combustion is still a significant energy source. One way to minimize the adverse side effects is sophisticated combustion technologies, such as, e.g., staged combustion, co-combustion with biomass, and oxy-combustion. Maintaining the combustion process at its optimal state, considering the emission of harmful substances, safe operation, and costs requires immediate information about the process. Flame image is a primary source of data which proper processing make keeping the combustion at desired conditions, possible. The paper presents a method combining flame image processing with a deep convolutional neural network (DCNN) that ensures high accuracy of identifying undesired combustion states. The method is based on the adaptive selection of the gamma correction coefficient (G) in the flame segmentation process. It uses the empirically determined relationship between the G coefficient and the average intensity of the R image component. The pre-trained VGG16 model for classification was used. It provided accuracy in detecting particular combustion states on the ranging from 82 to 98%. High accuracy and fast processing time make the proposed method possible to apply in the real systems.

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An Unsupervised Classification Method for Flame Image of Pulverized Coal Combustion Based on Convolutional Auto-Encoder and Hidden Markov Model

Cited by 36 publications

References 19 publications

Combustion process monitoring based on flame intensity time series

Combustion process monitoring based on flame intensity time series

Hyperspectral Image Classification Based on Superpixel Pooling Convolutional Neural Network with Transfer Learning

Flame Image Processing and Classification Using a Pre-Trained VGG16 Model in Combustion Diagnosis

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