Your search keyword '"combined normalization"' showing total 3 results

1. Prediction Model of Wastewater Pollutant Indicators Based on Combined Normalized Codec.

Author

Xu, Chun-Ming, Zhang, Jia-Shuai, Kong, Ling-Qiang, Jin, Xue-Bo, Kong, Jian-Lei, Bai, Yu-Ting, Su, Ting-Li, Ma, Hui-Jun, and Chakrabarti, Prasun

Subjects

*PREDICTION models, *WASTEWATER treatment, *POLLUTANTS, *INDUSTRIAL wastes, *CHEMICAL oxygen demand

Abstract

Effective prediction of wastewater treatment is beneficial for precise control of wastewater treatment processes. The nonlinearity of pollutant indicators such as chemical oxygen demand (COD) and total phosphorus (TP) makes the model difficult to fit and has low prediction accuracy. The classical deep learning methods have been shown to perform nonlinear modeling. However, there are enormous numerical differences between multi-dimensional data in the prediction problem of wastewater treatment, such as COD above 3000 mg/L and TP around 30 mg/L. It will make current normalization methods challenging to handle effectively, leading to the training failing to converge and the gradient disappearing or exploding. This paper proposes a multi-factor prediction model based on deep learning. The model consists of a combined normalization layer and a codec. The combined normalization layer combines the advantages of three normalization calculation methods: z-score, Interval, and Max, which can realize the adaptive processing of multi-factor data, fully retain the characteristics of the data, and finally cooperate with the codec to learn the data characteristics and output the prediction results. Experiments show that the proposed model can overcome data differences and complex nonlinearity in predicting industrial wastewater pollutant indicators and achieve better prediction accuracy than classical models. [ABSTRACT FROM AUTHOR]

Published

2022

2. Prediction Model of Wastewater Pollutant Indicators Based on Combined Normalized Codec

Author

Chun-Ming Xu, Jia-Shuai Zhang, Ling-Qiang Kong, Xue-Bo Jin, Jian-Lei Kong, Yu-Ting Bai, Ting-Li Su, Hui-Jun Ma, and Prasun Chakrabarti

Subjects

wastewater treatment, combined normalization, codec, pollutant indicators, predict, Mathematics, QA1-939

Abstract

Effective prediction of wastewater treatment is beneficial for precise control of wastewater treatment processes. The nonlinearity of pollutant indicators such as chemical oxygen demand (COD) and total phosphorus (TP) makes the model difficult to fit and has low prediction accuracy. The classical deep learning methods have been shown to perform nonlinear modeling. However, there are enormous numerical differences between multi-dimensional data in the prediction problem of wastewater treatment, such as COD above 3000 mg/L and TP around 30 mg/L. It will make current normalization methods challenging to handle effectively, leading to the training failing to converge and the gradient disappearing or exploding. This paper proposes a multi-factor prediction model based on deep learning. The model consists of a combined normalization layer and a codec. The combined normalization layer combines the advantages of three normalization calculation methods: z-score, Interval, and Max, which can realize the adaptive processing of multi-factor data, fully retain the characteristics of the data, and finally cooperate with the codec to learn the data characteristics and output the prediction results. Experiments show that the proposed model can overcome data differences and complex nonlinearity in predicting industrial wastewater pollutant indicators and achieve better prediction accuracy than classical models.

Published

2022

3. Required Threshold Settings and Signal-to-Noise Ratios for Combined Normalization and Or-ing

Author

NAVAL UNDERWATER SYSTEMS CENTER NEW LONDON CT, Nuttall, Albert H., NAVAL UNDERWATER SYSTEMS CENTER NEW LONDON CT, and Nuttall, Albert H.

Abstract

The system of interest here includes the combined nonlinear transformations of normalization and or-ing in the data processing chain. The required threshold settings for specified false alarm probabilities are determined, as well as the required input signal-to-noise ratios for specified detection probabilities. Specializations to normalization or or-ing alone are available by particular choices of parameter values built into the models. When the sizes of the transformations are changed, that is, the amount of normalization and/or or-ing, the thresholds will also have to be changed if the earlier probabilities are to be maintained; these options are included in the first program listed.

Published

1991