基于季节趋势分解的树枝状神经元模型预测PM2.5时间序列。

IF 4.5 3区 计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Neural Computing & Applications Pub Date : 2023-01-01 Epub Date: 2023-04-11 DOI:10.1007/s00521-023-08513-0
Zijing Yuan, Shangce Gao, Yirui Wang, Jiayi Li, Chunzhi Hou, Lijun Guo
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引用次数: 1

摘要

人类社会工业的快速发展带来了空气污染,严重影响了人类健康。PM2.5浓度是造成大气污染的主要因素之一。为了准确预测PM2.5微米,我们提出了一种通过基于STL-LOESS的改进的物态启发式算法(DSMS)训练的树突神经元模型(DNM),即DS-DNM。首先,DS-DNM采用STL-LOESS进行数据预处理,从原始数据中获得三个特征量:季节分量、趋势分量和残差分量。然后,由DSMS训练的DNM预测残差值。最后,将三组特征量相加以获得预测值。在性能测试实验中,使用了五个真实世界的PM2.5浓度数据来测试DS-DNM。另一方面,选择了四种训练算法和七种预测模型进行比较,分别验证了训练算法的合理性和预测模型的准确性。实验结果表明,DS-DNM在PM2.5浓度预测问题上具有更强的竞争力。
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Prediction of PM2.5 time series by seasonal trend decomposition-based dendritic neuron model.

The rapid industrial development in the human society has brought about the air pollution, which seriously affects human health. PM2.5 concentration is one of the main factors causing the air pollution. To accurately predict PM2.5 microns, we propose a dendritic neuron model (DNM) trained by an improved state-of-matter heuristic algorithm (DSMS) based on STL-LOESS, namely DS-DNM. Firstly, DS-DNM adopts STL-LOESS for the data preprocessing to obtain three characteristic quantities from original data: seasonal, trend, and residual components. Then, DNM trained by DSMS predicts the residual values. Finally, three sets of feature quantities are summed to obtain the predicted values. In the performance test experiments, five real-world PM2.5 concentration data are used to test DS-DNM. On the other hand, four training algorithms and seven prediction models were selected for comparison to verify the rationality of the training algorithms and the accuracy of the prediction models, respectively. The experimental results show that DS-DNM has the more competitive performance in PM2.5 concentration prediction problem.

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来源期刊
Neural Computing & Applications
Neural Computing & Applications 工程技术-计算机:人工智能
CiteScore
11.40
自引率
8.30%
发文量
1280
审稿时长
6.9 months
期刊介绍: Neural Computing & Applications is an international journal which publishes original research and other information in the field of practical applications of neural computing and related techniques such as genetic algorithms, fuzzy logic and neuro-fuzzy systems. All items relevant to building practical systems are within its scope, including but not limited to: -adaptive computing- algorithms- applicable neural networks theory- applied statistics- architectures- artificial intelligence- benchmarks- case histories of innovative applications- fuzzy logic- genetic algorithms- hardware implementations- hybrid intelligent systems- intelligent agents- intelligent control systems- intelligent diagnostics- intelligent forecasting- machine learning- neural networks- neuro-fuzzy systems- pattern recognition- performance measures- self-learning systems- software simulations- supervised and unsupervised learning methods- system engineering and integration. Featured contributions fall into several categories: Original Articles, Review Articles, Book Reviews and Announcements.
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