Abstract
AbstractGiven that sensitive feature recognition plays an important role in the prediction and analysis of water supply and demand, how to conduct effective sensitive feature recognition has become a critical problem. The current algorithms and recognition models are easily affected by multicollinearity between features. Moreover, these algorithms include only a single learning machine, which exposes large limitations in the process of sensitive feature recognition. In this study, an ensemble learning random forest (ELRF) algorithm, including multiple learning machines, was proposed to recognize sensitive features. A self-adaptive regression coupling model was developed to predict water supply and demand in Shenzhen in the next ten years. Results validate that the ELRF algorithm can effectively recognize sensitive features compared with decision tree and regular random forest algorithms. The model used in this study shows a strong self-adaptive ability in the modeling process of multiple regression. The water demand in Shenzhen will reach 2.2 billion m3 in 2025 and 2.35 billion m3 in 2030, which will exceeded the water supply ability of Shenzhen. Furthermore, three scenarios are designed in terms of water supply security and economic operation, and a comparative analysis is performed to obtain an optimal scenario.
Highlights
The prediction of water supply and demand for water resources planning is essential
For the exhibition of the superiority of the algorithm and model developed in this study, the decision tree (DT) and regular random forest (RRF) algorithms are developed to compare their results with the results of the ensemble learning random forest (ELRF) algorithm
s rank correlation coefficient (SRCC) is utilized to filter out features that are not strongly correlated with water supply, and the ELRF algorithm, including multiple learning machines, is proposed to conduct sensitive feature recognition
Summary
The prediction of water supply and demand for water resources planning is essential. If the water supply and demand in the future can be accurately predicted, we can grasp the growth of water use and determine water resources shortage in time so that we can implement water resources planning more scientifically and effectively. Rapid city development, modernization construction, frequent population flow, and water resources pollution make the physical environments of cities constantly change These facts bring great challenges to the prediction of water supply and demand. Data-driven models, such as the regression model (Safari 2019; Reis et al 2020), artificial neural network model (Praveen et al 2020), and long short term memory recurrent neural network model (Nasser et al 2020; Bai et al 2021), do not depend on physical environments and assumptions They can find potential quantitative relations and correlation relationships between features and can learn valuable knowledge previously unknown. These models have been widely applied in many fields
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
