基于阶段式粒度重构的供水量分解集成预测模型

doi:10.12005/orms.2025.0252

运筹与管理 ›› 2025, Vol. 34 ›› Issue (8): 134-140.DOI: 10.12005/orms.2025.0252

基于阶段式粒度重构的供水量分解集成预测模型

白云^1,2, 严政杰², 曾波², 陈国强³, 谢晶晶^1,4

1.广西大学工商管理学院,广西南宁 530004;
2.重庆工商大学管理科学与工程学院,重庆 400067;
3.重庆市北碚区住房和城乡建设委员会,重庆 400700;
4.重庆科技发展战略研究院,重庆 401123

收稿日期:2023-11-01 发布日期:2025-12-04
通讯作者: 白云(1985-),男,山西阳泉人,博士,教授,研究方向:系统大数据分析与管理。Email: yunbai@foxmail.com。
基金资助:
国家自然科学基金资助项目(72271036,72071023);重庆市自然科学基金项目(CSTB2022NSCQ-MSX0510)

A Decomposition-integration Model with Staged GranularityReconstruction for Daily Water Supply Forecasting

BAI Yun^1,2, YAN Zhengjie², ZENG Bo², CHEN Guoqiang³, XIE Jingjing^1,4

1. School of Business, Guangxi University, Nanning 530004, China;
2. School of Management Science and Engineering, Chongqing Technology and Business University, Chongqing 400067, China;
3. Beibei Municipal Commission of Housing and Urban-Rural Development, Chongqing 400700, China;
4. Chongqing Academy of S & T for Development, Chongqing 401123, China

Received:2023-11-01 Published:2025-12-04

摘要/Abstract

摘要： 为提升城市供水量预测精度,基于“分而治之”和“粒度重构”的思想,本文提出了一种阶段式粒度重构的分解集成预测模型。首先,原始时间序列通过模态分解获得多个本征模态函数(Intrinsic Mode Functions,IMFs);然后,对IMFs开展阶段式粒度重构,即基于时频特征的第一次重构(识别不同粒度信息)与基于复杂度评估的第二次重构(提升高频粒度的表征度);最后,对阶段式重构的多粒度信息分别进行深度储备池建模并将预测结果集成。本文所提阶段式粒度重构方式提升了时序局部特征提取效果(特别是高频信息的特征),进而提升分解集成预测精度。实例研究表明,所提模型预测精度优于对比模型,可为城市日供水管理提供精准决策支持。

关键词: 时序分解, 阶段式粒度重构, 集成预测, 供水量, 深度储备池计算

Abstract: A stable water supply is the cornerstone of social stability and economic development, and accurately forecasting the water supply enables cities to allocate resources more effectively, so as to avoid waste and unnecessary costs in the water supply planning and management.
Inspired by the ideas of “division and conquest” and “granularity reconstruction”, this paper proposes a decomposition integration forecasting model with staged granularity reconstruction. First, we decompose the original time series into multiple intrinsic mode functions (IMF). Then, we perform staged granularity reconstruction on IMF, which include the first reconstruction in terms of time-frequency features (identifying different granularity information) and the second reconstruction based on complexity evaluation (improving the representativeness of high-frequency granularity). Finally, we construct deep reservoir computing networks (DeepLiESN) on each granularity after staged granularity reconstruction and integrate the results as the final forecast. The staged granularity reconstruction method proposed in this paper improves the performance of local feature extraction (especially high-frequency features), thereby improving the accuracy of decomposition-integration model.
To verify the effectiveness of the proposed model, this work investigates two types of tests (i.e., four independent models and two reconstruction patterns). The comparative analysis of independent models reveals that the DeepLiESN, by introducing leaky integrated spiking neurons and a deep learning framework, improves its ability to describe nonlinear systems and temporal features, enhances short-term memory capacity, captures rich inherent information from the data, and is more capable of tracking the dynamic evolution of daily urban water supply. The comparative analysis of reconstruction patterns reveals that the staged reconstruction is advantageous for enhancing feature representation, particularly in overcoming the problem of mixed-frequency features. It enhances the effective utilization of high-frequency granularity information while reducing random interference in high-frequency granularity. The proposed models in this paper comprehensively consider the advantages of single-model forecasting and staged granularity reconstruction. As a result, it achieves the best forecasting performance with (1)the global error MAE=1053m³/d, RMSE=1397m³/d, and MAPE=0.577%; and (2)the individual error distribution (0,1%) accounts for 81.74%, (1,2%) for 97%, and (2%,3%) for 100%.
In summary, the proposed decomposition-integration model with staged granularity reconstruction is enhanced from three perspectives: (1)converting one-dimensional mixed information into multidimensional components to reduce temporal complexity, (2)learning time-frequency features and entropy probability features of multidimensional components for granularity reconstruction, particularly for mitigating high-frequency noise interference, and (3)integrating deep reservoir computing networks to improve the learning of complex nonlinear system characteristics. This model can offer accurate decision-making support for urban daily water supply management.

Key words: sequence decomposition, staged granularity reconstruction, integration forecasting, water supply, deep reservoir computing

中图分类号:

白云, 严政杰, 曾波, 陈国强, 谢晶晶. 基于阶段式粒度重构的供水量分解集成预测模型[J]. 运筹与管理, 2025, 34(8): 134-140.

BAI Yun, YAN Zhengjie, ZENG Bo, CHEN Guoqiang, XIE Jingjing. A Decomposition-integration Model with Staged GranularityReconstruction for Daily Water Supply Forecasting[J]. Operations Research and Management Science, 2025, 34(8): 134-140.

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基于阶段式粒度重构的供水量分解集成预测模型

A Decomposition-integration Model with Staged GranularityReconstruction for Daily Water Supply Forecasting

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