Discovering multi‐dimensional motifs from multi‐dimensional time series for air pollution control

Liu, Bo; Zhao, Huaipu; Liu, Yinxing; Wang, Suyu; Li, Jianqiang; Li, Yong; Lang, Jianlei; Gu, Rentao

doi:10.1002/cpe.5645

Cited by 2 publications

(2 citation statements)

References 36 publications

(53 reference statements)

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“…With the rapid advancements in intelligent data‐driven methods, time series forecasting (TSF) systems have been extensively investigated due to their contribution to decision‐making processes in different real‐world applications such as environmental forecasting, 1 healthcare science, 2 traffic flow, 3 and financial markets 4 . In general, most researchers have employed the traditional statistical models and the classical machine learning techniques for modeling TSF problems that contain linear or complex nonlinear patterns.…”

Section: Introductionmentioning

confidence: 99%

A deep learning framework with convolutional long short‐term memory for influenza‐like illness trend estimation

Kara

2022

Concurrency and Computation

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Forecasting and modeling real‐world time series problems have been challenging for researchers due to nonlinear and complicated patterns. With the recent developments in deep learning, more accurate and efficient forecasting can be provided by learning the relationships between input and output data. This article has introduced a novel hybrid approach, called the GA‐ConvLSTM‐CNN, based on the genetic algorithm (GA), convolutional long short‐term memory (ConvLSTM) and convolutional neural network (CNN) to capture complex and sophisticated features from historical data. The GA‐ConvLSTM‐CNN approach is constructed with two‐stacked ConvLSTM networks, two‐stacked CNN, and a fully connected layer to alleviate the complexity of the real‐world time series problems with multivariate and multistep. In order to increase the accuracy of the GA‐ConvLSTM‐CNN, the genetic algorithm is adopted to simultaneously optimize the network's hyperparameters. With the aim of making comparisons, the weekly influenza‐like illness (ILI) and the weather data have been handled. The GA‐ConvLSTM‐CNN framework compared different techniques comprising machine learning and deep learning approaches. The results have indicated that the GA‐ConvLSTM‐CNN has the ability to accomplish more effective prediction accuracy and provide remarkable support for ILI outbreaks than the benchmark techniques.

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Section: Introductionmentioning

confidence: 99%

A deep learning framework with convolutional long short‐term memory for influenza‐like illness trend estimation

Kara

2022

Concurrency and Computation

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“…To study air pollution spillover throughout China, it is necessary to use a motif algorithm to further analyze the meso structure of air pollution spillover between regions. A motif is a form of algorithm that is adapted to analyze a time series of spillover among large areas and time scales [26,27], and it is the basic structure of a complex network [28]. Based on the complex network, to some extent, the motif algorithm can increase the accuracy of findings regarding the sources of air pollution spillover.…”

Section: Introductionmentioning

confidence: 99%

Spatial and Seasonal Characteristics of Air Pollution Spillover in China

Yu,

Fang,

Huang

et al. 2021

Sustainability

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Air pollution spillover can cause air pollution to negatively affect neighboring regions. The structure of air pollution spillover varies with changes in season and space. Researching the spatial and seasonal characteristics of air pollution spillover is beneficial for determining air pollution prevention and control policies. First, this paper uses the GARCH-BEKK model to correlate the air pollution spillover among cities. Second, a complex network is constructed, and cities that have stronger spillover correlations are grouped into the same region. Finally, motifs are analyzed regarding the spillover relationships among regions. This paper also compares the structure of air pollution spillover during various seasons. This study determines that every season has a core region where the air pollution spillover exits the region. The core region in the spring is western East China, in the summer it is northern East China, in the autumn it is northern East China, and in the winter it is northern North China. These regions interact with most other regions. Furthermore, in spring and winter, the phenomena of air pollution spillover between regions are stronger than those in summer and autumn. We can weaken the air pollution spillover by controlling the air pollution in core regions.

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Discovering multi‐dimensional motifs from multi‐dimensional time series for air pollution control

Cited by 2 publications

References 36 publications

A deep learning framework with convolutional long short‐term memory for influenza‐like illness trend estimation

A deep learning framework with convolutional long short‐term memory for influenza‐like illness trend estimation

Spatial and Seasonal Characteristics of Air Pollution Spillover in China

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