基于稀疏自编码器的污水流量双向LSTM预测模型。

IF 2.5 3区 计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
Jianying Huang, Seunghyeok Yang, Jinhui Li, Jeill Oh, Hoon Kang
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引用次数: 4

摘要

过量降雨引发的入渗和流入导致的生活污水溢流是目前市政管理面临的主要挑战,因此,提前正确预测生活污水系统的废水状态的能力尤为重要。本文提出了基于稀疏自编码器的双向长短期记忆(SAE-BLSTM)网络模型的设计,该模型建立在稀疏自编码器(SAE)和双向长短期记忆(BLSTM)网络的基础上,用于预测下水道系统的污水流量。该网络模型由数据预处理网段、SAE网段和BLSTM网段组成。SAE能够对高维原始输入特征数据进行数据降维,从而从上述高维原始输入特征数据中提取稀疏的潜在特征。SAE隐藏层提取的潜在特征与平滑的历史废水流量特征相连接,以创建一个增强的先前特征向量,更准确地预测废水流量。这些增强的先前特征应用于BLSTM网络来预测未来的废水流量。因此,该网络模型结合了两种能力,即SAE对原始输入特征数据的低维非线性表示和BLSTM对废水流量的时间序列预测。然后,我们利用真实水文时间序列数据集,采用先进的SVM、FCN、GRU、LSTM和BLSTM模型作为比较算法,对SAE-BLSTM网络模型进行了广泛的实验。实验结果表明,我们提出的SAE-BLSTM模型始终优于先进的比较模型。具体来说,我们在我们的数据集中选择了一个3个月周期的训练数据集来训练和测试SAE-BLSTM网络模型。SAE-BLSTM网络模型的RMSE最低,MAE最高,r2最高,分别为242.55、179.05和0.99626。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Prediction model of sparse autoencoder-based bidirectional LSTM for wastewater flow rate.

Prediction model of sparse autoencoder-based bidirectional LSTM for wastewater flow rate.

Prediction model of sparse autoencoder-based bidirectional LSTM for wastewater flow rate.

Prediction model of sparse autoencoder-based bidirectional LSTM for wastewater flow rate.

Sanitary sewer overflows caused by excessive rainfall derived infiltration and inflow is the major challenge currently faced by municipal administrations, and therefore, the ability to correctly predict the wastewater state of the sanitary sewage system in advance is especially significant. In this paper, we present the design of the Sparse Autoencoder-based Bidirectional long short-term memory (SAE-BLSTM) network model, a model built on Sparse Autoencoder (SAE) and Bidirectional long short-term memory (BLSTM) networks to predict the wastewater flow rate in a sanitary sewer system. This network model consists of a data preprocessing segment, the SAE network segment, and the BLSTM network segment. The SAE is capable of performing data dimensionality reduction on high-dimensional original input feature data from which it can extract sparse potential features from the aforementioned high-dimensional original input feature data. The potential features extracted by the SAE hidden layer are concatenated with the smooth historical wastewater flow rate features to create an augmented previous feature vector that more accurately predicts the wastewater flow rate. These augmented previous features are applied to the BLSTM network to predict the future wastewater flow rate. Thus, this network model combines two kinds of abilities, SAE's low-dimensional nonlinear representation for original input feature data and BLSTM's time series prediction for wastewater flow rate. Then, we conducted extensive experiments on the SAE-BLSTM network model utilizing the real-world hydrological time series datasets and employing advanced SVM, FCN, GRU, LSTM, and BLSTM models as comparison algorithms. The experimental results show that our proposed SAE-BLSTM model consistently outperforms the advanced comparison models. Specifically, we selected a 3 months period training dataset in our dataset to train and test the SAE-BLSTM network model. The SAE-BLSTM network model yielded the lowest RMSE, MAE, and highest R 2, which are 242.55, 179.05, and 0.99626, respectively.

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来源期刊
Journal of Supercomputing
Journal of Supercomputing 工程技术-工程:电子与电气
CiteScore
6.30
自引率
12.10%
发文量
734
审稿时长
13 months
期刊介绍: The Journal of Supercomputing publishes papers on the technology, architecture and systems, algorithms, languages and programs, performance measures and methods, and applications of all aspects of Supercomputing. Tutorial and survey papers are intended for workers and students in the fields associated with and employing advanced computer systems. The journal also publishes letters to the editor, especially in areas relating to policy, succinct statements of paradoxes, intuitively puzzling results, partial results and real needs. Published theoretical and practical papers are advanced, in-depth treatments describing new developments and new ideas. Each includes an introduction summarizing prior, directly pertinent work that is useful for the reader to understand, in order to appreciate the advances being described.
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