t-SNE and variational auto-encoder with a bi-LSTM neural network-based model for prediction of gas concentration in a sealed-off area of underground coal mines

Dey, Prasanjit; Saurabh, Kunal; Kumar, Chandan; Pandit, Dewangshu; Chaulya, S.K.; Ray, S. K.; Prasad, G.M.; Mandal, Sujit

doi:10.1007/s00500-021-06261-8

Cited by 13 publications

(6 citation statements)

References 54 publications

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“…Other unsupervised models were also tried for feature extraction such as autoencoder and a deep belief network [34,[57][58][59]. Autoencoder is a feed-forward network structure aimed at recovering input at its output by minimizing mean square error; a stacked autoencoder refers to an autoencoder with more than one hidden layer.…”

Section: Feature Extraction Through Learningmentioning

confidence: 99%

“…Compared to other dimensionality reduction methods including PCA and Kernel-PCA, feature representations from the GRU-AE were more distinguishable and effectively improved classification performance. Other unsupervised models were also tried for feature extraction such as autoe coder and a deep belief network [34,[57][58][59]. Autoencoder is a feed-forward network stru ture aimed at recovering input at its output by minimizing mean square error; a stacke autoencoder refers to an autoencoder with more than one hidden layer.…”

Section: Feature Extraction Through Learningmentioning

confidence: 99%

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Recent Progress in Smart Electronic Nose Technologies Enabled with Machine Learning Methods

Liu

2021

Sensors

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Machine learning methods enable the electronic nose (E-Nose) for precise odor identification with both qualitative and quantitative analysis. Advanced machine learning methods are crucial for the E-Nose to gain high performance and strengthen its capability in many applications, including robotics, food engineering, environment monitoring, and medical diagnosis. Recently, many machine learning techniques have been studied, developed, and integrated into feature extraction, modeling, and gas sensor drift compensation. The purpose of feature extraction is to keep robust pattern information in raw signals while removing redundancy and noise. With the extracted feature, a proper modeling method can effectively use the information for prediction. In addition, drift compensation is adopted to relieve the model accuracy degradation due to the gas sensor drifting. These recent advances have significantly promoted the prediction accuracy and stability of the E-Nose. This review is engaged to provide a summary of recent progress in advanced machine learning methods in E-Nose technologies and give an insight into new research directions in feature extraction, modeling, and sensor drift compensation.

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Section: Feature Extraction Through Learningmentioning

confidence: 99%

Section: Feature Extraction Through Learningmentioning

confidence: 99%

Recent Progress in Smart Electronic Nose Technologies Enabled with Machine Learning Methods

Liu

2021

Sensors

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“…Meng et al [ 24 ] proposed a novel prediction method that combines classical time series analysis with these deep learning models. Dey et al [ 25 ] proposed the t-SNE_VAE_bi-LSTM prediction model that combines the t-SNE, VAE, and bi-LSTM networks. Xu et al [ 26 ] constructed a new IWOA-LSTM-CEEMDAN prediction model based on the improved whale optimization algorithm (IWOA).…”

Section: Introductionmentioning

confidence: 99%

Combined Prediction Model of Gas Concentration Based on Indicators Dynamic Optimization and Bi-LSTMs

Peng

Song

Qiu

et al. 2023

Sensors

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In order to accurately predict the gas concentration, find out the gas abnormal emission in advance, and take effective measures to reduce the gas concentration in time, this paper analyzes multivariate monitoring data and proposes a new dynamic combined prediction method of gas concentration. Spearman’s rank correlation coefficient is applied for the dynamic optimization of prediction indicators. The time series and spatial topology features of the optimized indicators are extracted and input into the combined prediction model of gas concentration based on indicators dynamic optimization and Bi-LSTMs (Bi-directional Long Short-term Memory), which can predict the gas concentration for the next 30 min. The results show that the other gas concentration, temperature, and humidity indicators are strongly correlated with the gas concentration to be predicted, and Spearman’s rank correlation coefficient is up to 0.92 at most. The average R2 of predicted value and real value is 0.965, and the average prediction efficiency R for gas abnormal or normal emission is 79.9%. Compared with the other models, the proposed dynamic optimized indicators combined model is more accurate, and the missing alarm of gas abnormal emission is significantly alleviated, which greatly improves the early alarming accuracy. It can assist the safety monitoring personnel in decision making and has certain significance to improve the safety production efficiency of coal mines.

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“…Since gas concentration data have strong time series characteristics [20,21], the algorithms in the above studies are able to predict gas concentration well, but most of the above studies focus on the accuracy of data prediction, and the prediction efficiency is mostly dependent on the operation efficiency of the model itself, which actually has certain limitations for improving the prediction efficiency. In this paper, we propose a gas concentration prediction model incorporating the particle swarm optimisation algorithm (PSO) and a gated recurrent unit (GRU) model under the Spark Streaming framework (SSF), which can further improve the model's operational efficiency due to the advantages of fast data processing and fault tolerance of the SSF.…”

Section: Introductionmentioning

confidence: 99%

A Spark Streaming-Based Early Warning Model for Gas Concentration Prediction

Huang

Fan

et al. 2023

Processes

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The prediction and early warning efficiency of mine gas concentrations are important for intelligent monitoring of daily gas concentrations in coal mines. It is used as an important means for ensuring the safe and stable operation of coal mines. This study proposes an early warning model for gas concentration prediction involving the Spark Streaming framework (SSF). The model incorporates a particle swarm optimisation algorithm (PSO) and a gated recurrent unit (GRU) model in the SSF, and further experimental analysis is carried out on the basis of optimising the model parameters. The operational efficiency of the model is validated using a control variable approach, and the prediction and warning errors is verified using MAE, RMSE and R2. The results show that the model is able to predict and warn of the gas concentration with high efficiency and high accuracy. It also features fast data processing and fault tolerance, which provides a new idea to continue improving the gas concentration prediction and warning efficiency and some theoretical and technical support for intelligent gas monitoring in coal mines.

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t-SNE and variational auto-encoder with a bi-LSTM neural network-based model for prediction of gas concentration in a sealed-off area of underground coal mines

Cited by 13 publications

References 54 publications

Recent Progress in Smart Electronic Nose Technologies Enabled with Machine Learning Methods

Recent Progress in Smart Electronic Nose Technologies Enabled with Machine Learning Methods

Combined Prediction Model of Gas Concentration Based on Indicators Dynamic Optimization and Bi-LSTMs

A Spark Streaming-Based Early Warning Model for Gas Concentration Prediction

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