Machine-learning methods for stream water temperature prediction

Feigl, Moritz; Lebiedzinski, Katharina; Herrnegger, Mathew; Schulz, Karsten

doi:10.5194/hess-25-2951-2021

Cited by 73 publications

(50 citation statements)

References 115 publications

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“…Stream temperature is a widely measured physical water quality variable and has been successfully predicted using different ML methods. For example, classical ML methods have been used for monthly to daily predictions of stream temperatures in catchments with different characteristics, and include support vector regression (SVR; Rehana, 2019;Weierbach et al, 2022); decision tree-based regression models such as RF, XGBoost, and their variations (Feigl et al, 2021;Lu & Ma, 2020;Weierbach et al, 2022); and simple ANNs (Feigl et al, 2021;Zhu & Piotrowski, 2020). Among DL models, the LSTM deep neural network has become an increasingly popular choice for regional-scale hydrological predictions due to its ability to encode prior system states in the cell memory (e.g., Kratzert et al, 2018).…”

Section: State-of-the-art Machine Learning In River Water Quality Modelsmentioning

confidence: 99%

Can machine learning accelerate process understanding and decision‐relevant predictions of river water quality?

Varadharajan

Appling

Arora

et al. 2022

Hydrological Processes

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The global decline of water quality in rivers and streams has resulted in a pressing need to design new watershed management strategies. Water quality can be affected by multiple stressors including population growth, land use change, global warming, and extreme events, with repercussions on human and ecosystem health. A scientific understanding of factors affecting riverine water quality and predictions at local to regional scales, and at sub‐daily to decadal timescales are needed for optimal management of watersheds and river basins. Here, we discuss how machine learning (ML) can enable development of more accurate, computationally tractable, and scalable models for analysis and predictions of river water quality. We review relevant state‐of‐the art applications of ML for water quality models and discuss opportunities to improve the use of ML with emerging computational and mathematical methods for model selection, hyperparameter optimization, incorporating process knowledge into ML models, improving explainablity, uncertainty quantification, and model‐data integration. We then present considerations for using ML to address water quality problems given their scale and complexity, available data and computational resources, and stakeholder needs. When combined with decades of process understanding, interdisciplinary advances in knowledge‐guided ML, information theory, data integration, and analytics can help address fundamental science questions and enable decision‐relevant predictions of riverine water quality.

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Section: State-of-the-art Machine Learning In River Water Quality Modelsmentioning

confidence: 99%

Can machine learning accelerate process understanding and decision‐relevant predictions of river water quality?

Varadharajan

Appling

Arora

et al. 2022

Hydrological Processes

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“…Machine learning has been applied to various aspects of snowmelt modeling, such as filling missing observation data [80,81], generating high accuracy rainfall observation data [82], merging satellite precipitation products and measured precipitation [83,84], forecasting real-time rainfall from radar [85], estimating snow cover from satellite data [86], estimating snow water equivalent [87,88], and calculating soil moisture and soil saturated hydraulic conductivity [89][90][91]. In addition, there are also many applications of machine learning in the field of hydrology, such as river water regime simulation [92][93][94], flood hydrograph prediction [95], groundwater dynamics simulation [96], parameter identification of hydrological models [97], and establishment of hydrological evaluation tools [98].…”

Section: Data-driven Modelmentioning

confidence: 99%

A Review on Snowmelt Models: Progress and Prospect

et al. 2021

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The frequency and intensity of flood events have been increasing recently under the warming climate, with snowmelt floods being a significant part. As an effective manner of simulating snowmelt flood, snowmelt models have attracted more and more attention. Through comprehensive analysis of the literature, this paper reviewed the characteristics and current status of different types of snowmelt models, as well as the different coupling methods of models for runoff generation and confluence. We then discussed key issues in snowmelt modelling, including blowing snow model, frozen ground model, and rain-on-snow model. Finally, we give some perspectives from four aspects: data, model structure, forecast and early warning, and forecast and estimation. At present, most of the snowmelt models do not have blowing snow or frozen ground modules. Explicit consideration of blowing snow and soil freezing/thawing processes can improve the accuracy of snowmelt runoff simulations. With climate warming, rain-on-snow events have increased, but the mechanism of enhanced rain and snow mixed flooding is still unclear, particularly for the mechanism of rain-snow-ice mixed runoff generation. The observation and simulation of rain and snow processes urgently need further study. A distributed physical snowmelt model based on energy balance is an advanced tool for snowmelt simulation, but the model structure and parameter schemes still need further improvements. Moreover, the integration of satellite-based snow products, isotopes, and terrestrial water storage change, monitored by gravity satellites, can help improve the calibration and validation of snowmelt models.

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“…Higher water temperatures of water abstracted for the operation of the power plants lead to a reduction of cooling efficiency on the one hand but can also lead to the violation of legal constraints regarding maximum allowed river temperatures due to ecological reasons. These thresholds may be exceeded when warmed-up water is directed into the river after the power plant [58]. Knowledge of current temperature conditions could therefore help thermal power plant operators to plan accordingly, and the implementation of water temperature simulations in the HIS, e.g., following the methods shown in [58], is feasible for the future.…”

Section: Limitations and Future Prospectsmentioning

confidence: 99%

“…These thresholds may be exceeded when warmed-up water is directed into the river after the power plant [58]. Knowledge of current temperature conditions could therefore help thermal power plant operators to plan accordingly, and the implementation of water temperature simulations in the HIS, e.g., following the methods shown in [58], is feasible for the future.…”

Section: Limitations and Future Prospectsmentioning

confidence: 99%

A Near Real-Time Hydrological Information System for the Upper Danube Basin

Pulka¹,

Santos²,

Schulz³

et al. 2021

Hydrology

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The multi-national catchment of the Upper Danube covers an area of more than 100,000 km2 and is of great ecological and economic value. Its hydrological states (e.g., runoff conditions, snow cover states or groundwater levels) affect fresh-water supply, agriculture, hydropower, transport and many other sectors. The timely knowledge of the current status is therefore of importance to decision makers from administration or practice but also the interested public. Therefore, a web-based, near real-time hydrological information system was conceptualized and developed for the Upper Danube upstream of Vienna (Upper Danube HIS), utilizing ERA5 reanalysis data (ERA5) and hydrological simulations provided by the semi-distributed hydrological model COSERO. The ERA5 reanalysis data led to comparatively high simulation performance for a total of 65 subbasins with a median NSE and KGE of 0.69 and 0.81 in the parameter calibration and 0.63 and 0.75 in the validation period. The Upper Danube HIS was implemented within the R programming environment as a web application based on the Shiny framework. This enables an intuitive, interactive access to the system. It offers various capabilities for a hydrometeorological analysis of the 65 subbasins of the Upper Danube basin, inter alia, a method for the identification of hydrometeorological droughts. This proof of concept and system underlines how valuable information can be obtained from freely accessible data and by the means of open source software and is made available to the hydrological community, water managers and the public.

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Machine-learning methods for stream water temperature prediction

Cited by 73 publications

References 115 publications

Can machine learning accelerate process understanding and decision‐relevant predictions of river water quality?

Can machine learning accelerate process understanding and decision‐relevant predictions of river water quality?

A Review on Snowmelt Models: Progress and Prospect

A Near Real-Time Hydrological Information System for the Upper Danube Basin

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