TY - GEN
T1 - Clustering and Forecasting Model for Water Distribution Systems Analysis
AU - Salazar, Alessandro Toledo
AU - Perelman, Gal
AU - Ostfeld, Avi
AU - Pesantez, Jorge E.
N1 - Publisher Copyright: © 2025 ASCE.
PY - 2025
Y1 - 2025
N2 - The operation and management of water distribution systems rely on water metering devices installed throughout the network. However, the rapid urban development and population growth and the relatively high cost of meters can hinder water providers from uniformly collecting water demand data across the network for billing, operational, or maintenance purposes. As a result, predictive methods are required to understand consumption patterns in areas with missing or malfunctioning metering infrastructure by utilizing information from similar, measured areas to bridge this gap in demand data. This study presents a two-step method to partition a water network into similar demand areas in order to predict demand conditions in unmeasured regions. The clustering step employs network topology and hydraulic characteristics to minimize demand variation across clusters. Next, a data-driven model is trained using demand data from multiple clusters to forecast demand in an unmetered cluster outside of the train set. Our two-step method reports R² values as high as 0.90 when trained on a set of 10 clusters from a benchmark hydraulic network. The developed predictive model for unmetered areas offers water providers an alternative approach to understanding demand dynamics across the entire network.
AB - The operation and management of water distribution systems rely on water metering devices installed throughout the network. However, the rapid urban development and population growth and the relatively high cost of meters can hinder water providers from uniformly collecting water demand data across the network for billing, operational, or maintenance purposes. As a result, predictive methods are required to understand consumption patterns in areas with missing or malfunctioning metering infrastructure by utilizing information from similar, measured areas to bridge this gap in demand data. This study presents a two-step method to partition a water network into similar demand areas in order to predict demand conditions in unmeasured regions. The clustering step employs network topology and hydraulic characteristics to minimize demand variation across clusters. Next, a data-driven model is trained using demand data from multiple clusters to forecast demand in an unmetered cluster outside of the train set. Our two-step method reports R² values as high as 0.90 when trained on a set of 10 clusters from a benchmark hydraulic network. The developed predictive model for unmetered areas offers water providers an alternative approach to understanding demand dynamics across the entire network.
UR - http://www.scopus.com/inward/record.url?scp=105006894411&partnerID=8YFLogxK
U2 - 10.1061/9780784486184.077
DO - 10.1061/9780784486184.077
M3 - منشور من مؤتمر
T3 - World Environmental and Water Resources Congress 2025: Cool Solutions to Hot Topics - Proceedings of World Environmental and Water Resources Congress 2025
SP - 824
EP - 831
BT - World Environmental and Water Resources Congress 2025
A2 - Ahmad, Sajjad
A2 - Struck, Scott
A2 - Drummond, Chad
T2 - World Environmental and Water Resources Congress 2025: Cool Solutions to Hot Topics
Y2 - 18 May 2025 through 21 May 2025
ER -