Data-driven modeling of municipal water system responses to hydroclimate extremes

Ryan Johnson; Steven John Burian; Carlos Anthony Oroza; James Halgren; Trevor Irons; Danyal Aziz; Daniyal Hassan; Jiada Li; Carly Hansen; Tracie Kirkham; Jesse Stewart; Laura Briefer

doi:10.2166/hydro.2023.170

Data-driven modeling of municipal water system responses to hydroclimate extremes

Ryan Johnson
, Steven John Burian
, Carlos Anthony Oroza
, James Halgren
, Trevor Irons
, Danyal Aziz
, Daniyal Hassan
, Jiada Li
, Carly Hansen
, Tracie Kirkham
, Jesse Stewart
, Laura Briefer

Water Resources Science & Engineering

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Sustainable western US municipal water system (MWS) management depends on quantifying the impacts of supply and demand dynamics on system infrastructure reliability and vulnerability. Systems modeling can replicate the interactions but extensive parameterization, high complexity, and long development cycles present barriers to widespread adoption. To address these challenges, we develop the Machine Learning Water Systems Model (ML-WSM) – a novel application of data-driven modeling for MWS management. We apply the ML-WSM framework to the Salt Lake City, Utah water system, where we benchmark prediction performance on the seasonal response of reservoir levels, groundwater withdrawal, and imported water requests to climate anomalies at a daily resolution against an existing systems model. The ML-WSM accurately predicts the seasonal dynamics of all components; especially during supply-limiting conditions (KGE . 0.88, PBias, +3%). Extreme wet conditions challenged model skill but the ML-WSM communicated the appropriate seasonal trends and relationships to component thresholds (e.g., reservoir dead pool). The model correctly classified nearly all instances of vulnerability (83%) and peak severity (100%), encouraging its use as a guidance tool that complements systems models for evaluating the influences of climate on MWS performance.

Original language	English
Pages (from-to)	1584-1609
Number of pages	26
Journal	Journal of Hydroinformatics
Volume	25
Issue number	5
DOIs	https://doi.org/10.2166/hydro.2023.170
State	Published - Sep 1 2023

Funding

Funding for this project was provided by the National Oceanic and Atmospheric Administration (NOAA), and awarded to the Cooperative Institute for Research to Operations in Hydrology (CIROH) through the NOAA Cooperative Agreement with The University of Alabama, NA22NWS4320003. The authors would like to thank all the SLCDPU staff for their time and commitment to the Salt Lake City Vulnerability Project. The provided funding and enthusiasm for science accelerated this research. This research would also like to thank Margaret Wolf, Logan Jamison, Dr Paul Brooks, and Dr Courtney Strong for their collaborative work on this project.

Keywords

XGBoost
data-driven modeling
machine learning
municipal water system
water system climate vulnerability

Access to Document

10.2166/hydro.2023.170

Cite this

@article{efed18210710430b89e6349427f2e25e,

title = "Data-driven modeling of municipal water system responses to hydroclimate extremes",

abstract = "Sustainable western US municipal water system (MWS) management depends on quantifying the impacts of supply and demand dynamics on system infrastructure reliability and vulnerability. Systems modeling can replicate the interactions but extensive parameterization, high complexity, and long development cycles present barriers to widespread adoption. To address these challenges, we develop the Machine Learning Water Systems Model (ML-WSM) – a novel application of data-driven modeling for MWS management. We apply the ML-WSM framework to the Salt Lake City, Utah water system, where we benchmark prediction performance on the seasonal response of reservoir levels, groundwater withdrawal, and imported water requests to climate anomalies at a daily resolution against an existing systems model. The ML-WSM accurately predicts the seasonal dynamics of all components; especially during supply-limiting conditions (KGE . 0.88, PBias, +3\%). Extreme wet conditions challenged model skill but the ML-WSM communicated the appropriate seasonal trends and relationships to component thresholds (e.g., reservoir dead pool). The model correctly classified nearly all instances of vulnerability (83\%) and peak severity (100\%), encouraging its use as a guidance tool that complements systems models for evaluating the influences of climate on MWS performance.",

keywords = "XGBoost, data-driven modeling, machine learning, municipal water system, water system climate vulnerability",

author = "Ryan Johnson and Burian, \{Steven John\} and Oroza, \{Carlos Anthony\} and James Halgren and Trevor Irons and Danyal Aziz and Daniyal Hassan and Jiada Li and Carly Hansen and Tracie Kirkham and Jesse Stewart and Laura Briefer",

note = "Publisher Copyright: {\textcopyright} 2023 The Authors.",

year = "2023",

month = sep,

day = "1",

doi = "10.2166/hydro.2023.170",

language = "English",

volume = "25",

pages = "1584--1609",

journal = "Journal of Hydroinformatics",

issn = "1464-7141",

publisher = "IWA Publishing",

number = "5",

}

TY - JOUR

T1 - Data-driven modeling of municipal water system responses to hydroclimate extremes

AU - Johnson, Ryan

AU - Burian, Steven John

AU - Oroza, Carlos Anthony

AU - Halgren, James

AU - Irons, Trevor

AU - Aziz, Danyal

AU - Hassan, Daniyal

AU - Li, Jiada

AU - Hansen, Carly

AU - Kirkham, Tracie

AU - Stewart, Jesse

AU - Briefer, Laura

PY - 2023/9/1

Y1 - 2023/9/1

N2 - Sustainable western US municipal water system (MWS) management depends on quantifying the impacts of supply and demand dynamics on system infrastructure reliability and vulnerability. Systems modeling can replicate the interactions but extensive parameterization, high complexity, and long development cycles present barriers to widespread adoption. To address these challenges, we develop the Machine Learning Water Systems Model (ML-WSM) – a novel application of data-driven modeling for MWS management. We apply the ML-WSM framework to the Salt Lake City, Utah water system, where we benchmark prediction performance on the seasonal response of reservoir levels, groundwater withdrawal, and imported water requests to climate anomalies at a daily resolution against an existing systems model. The ML-WSM accurately predicts the seasonal dynamics of all components; especially during supply-limiting conditions (KGE . 0.88, PBias, +3%). Extreme wet conditions challenged model skill but the ML-WSM communicated the appropriate seasonal trends and relationships to component thresholds (e.g., reservoir dead pool). The model correctly classified nearly all instances of vulnerability (83%) and peak severity (100%), encouraging its use as a guidance tool that complements systems models for evaluating the influences of climate on MWS performance.

AB - Sustainable western US municipal water system (MWS) management depends on quantifying the impacts of supply and demand dynamics on system infrastructure reliability and vulnerability. Systems modeling can replicate the interactions but extensive parameterization, high complexity, and long development cycles present barriers to widespread adoption. To address these challenges, we develop the Machine Learning Water Systems Model (ML-WSM) – a novel application of data-driven modeling for MWS management. We apply the ML-WSM framework to the Salt Lake City, Utah water system, where we benchmark prediction performance on the seasonal response of reservoir levels, groundwater withdrawal, and imported water requests to climate anomalies at a daily resolution against an existing systems model. The ML-WSM accurately predicts the seasonal dynamics of all components; especially during supply-limiting conditions (KGE . 0.88, PBias, +3%). Extreme wet conditions challenged model skill but the ML-WSM communicated the appropriate seasonal trends and relationships to component thresholds (e.g., reservoir dead pool). The model correctly classified nearly all instances of vulnerability (83%) and peak severity (100%), encouraging its use as a guidance tool that complements systems models for evaluating the influences of climate on MWS performance.

KW - XGBoost

KW - data-driven modeling

KW - machine learning

KW - municipal water system

KW - water system climate vulnerability

UR - https://www.scopus.com/pages/publications/85174813251

U2 - 10.2166/hydro.2023.170

DO - 10.2166/hydro.2023.170

M3 - Article

AN - SCOPUS:85174813251

SN - 1464-7141

VL - 25

SP - 1584

EP - 1609

JO - Journal of Hydroinformatics

JF - Journal of Hydroinformatics

IS - 5

ER -

Data-driven modeling of municipal water system responses to hydroclimate extremes

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Cite this