Your search keyword '"Imhoff, Ruben O' showing total 14 results

1. A fast high resolution distributed hydrological model for forecasting, climate scenarios and digital twin applications using wflow_sbm

Author

Imhoff, Ruben O., Buitink, Joost, van Verseveld, Willem J., and Weerts, Albrecht H.

Published

2024

2. Wflow-sbm v0.7.3, a spatially distributed hydrological model : From global data to local applications

Author

Van Verseveld, Willem J., Weerts, Albrecht H., Visser, Martijn, Buitink, Joost, Imhoff, Ruben O., Boisgontier, Hélène, Bouaziz, Laurène, Eilander, Dirk, Hegnauer, Mark, Ten Velden, Corine, Russell, Bobby, Van Verseveld, Willem J., Weerts, Albrecht H., Visser, Martijn, Buitink, Joost, Imhoff, Ruben O., Boisgontier, Hélène, Bouaziz, Laurène, Eilander, Dirk, Hegnauer, Mark, Ten Velden, Corine, and Russell, Bobby

Abstract

The wflow-sbm hydrological model, recently released by Deltares, as part of the Wflow.jl (v0.7.3) modelling framework, is being used to better understand and potentially address multiple operational and water resource planning challenges from a catchment scale to national scale to continental and global scale. Wflow.jl is a free and open-source distributed hydrological modelling framework written in the Julia programming language. The development of wflow_sbm, the model structure, equations and functionalities are described in detail, including example applications of wflow_sbm. The wflow-sbm model aims to strike a balance between low-resolution, low-complexity and high-resolution, high-complexity hydrological models. Most wflow-sbm parameters are based on physical characteristics or processes, and at the same time wflow-sbm has a runtime performance well suited for large-scale high-resolution model applications. Wflow-sbm models can be set a priori for any catchment with the Python tool HydroMT-Wflow based on globally available datasets and through the use of point-scale (pedo)transfer functions and suitable upscaling rules and generally result in a satisfactory (0.4g≥Kling-Gupta efficiency (KGE)g

Published

2024

3. Wflow_sbm v0.7.3, a spatially distributed hydrological model: from global data to local applications.

Author

van Verseveld, Willem J., Weerts, Albrecht H., Visser, Martijn, Buitink, Joost, Imhoff, Ruben O., Boisgontier, Hélène, Bouaziz, Laurène, Eilander, Dirk, Hegnauer, Mark, ten Velden, Corine, and Russell, Bobby

Subjects

HYDROLOGIC models, WATER rights, PYTHON programming language, WATER supply, GRAPHICS processing units, EVAPOTRANSPIRATION, PROGRAMMING languages, TRANSFER functions, GLACIERS

Abstract

The wflow_sbm hydrological model, recently released by Deltares, as part of the Wflow.jl (v0.7.3) modelling framework, is being used to better understand and potentially address multiple operational and water resource planning challenges from a catchment scale to national scale to continental and global scale. Wflow.jl is a free and open-source distributed hydrological modelling framework written in the Julia programming language. The development of wflow_sbm, the model structure, equations and functionalities are described in detail, including example applications of wflow_sbm. The wflow_sbm model aims to strike a balance between low-resolution, low-complexity and high-resolution, high-complexity hydrological models. Most wflow_sbm parameters are based on physical characteristics or processes, and at the same time wflow_sbm has a runtime performance well suited for large-scale high-resolution model applications. Wflow_sbm models can be set a priori for any catchment with the Python tool HydroMT-Wflow based on globally available datasets and through the use of point-scale (pedo)transfer functions and suitable upscaling rules and generally result in a satisfactory (0.4 ≥ Kling–Gupta efficiency (KGE) < 0.7) to good (KGE ≥ 0.7) performance for discharge a priori (without further tuning). Wflow_sbm includes relevant hydrological processes such as glacier and snow processes, evapotranspiration processes, unsaturated zone dynamics, (shallow) groundwater, and surface flow routing including lakes and reservoirs. Further planned developments include improvements on the computational efficiency and flexibility of the routing scheme, implementation of a water demand and allocation module for water resource modelling, the addition of a deep groundwater concept, and computational efficiency improvements through for example distributed computing and graphics processing unit (GPU) acceleration. [ABSTRACT FROM AUTHOR]

Published

2024

4. Scale-dependent blending of ensemble rainfall nowcasts and numerical weather prediction in the open-source pysteps library

Author

Imhoff, Ruben O., De Cruz, Lesley, Dewettinck, Wout, Brauer, Claudia C., Uijlenhoet, Remko, van Heeringen, Klaas Jan, Velasco-Forero, Carlos, Nerini, Daniele, Van Ginderachter, Michiel, Weerts, Albrecht H., Imhoff, Ruben O., De Cruz, Lesley, Dewettinck, Wout, Brauer, Claudia C., Uijlenhoet, Remko, van Heeringen, Klaas Jan, Velasco-Forero, Carlos, Nerini, Daniele, Van Ginderachter, Michiel, and Weerts, Albrecht H.

Abstract

Flash flood early warning requires accurate rainfall forecasts with a high spatial and temporal resolution. As the first few hours ahead are already not sufficiently well captured by the rainfall forecasts of numerical weather prediction (NWP) models, radar rainfall nowcasting can provide an alternative. Because this observation-based method quickly loses skill after the first 2 hr of the forecast, it needs to be combined with NWP forecasts to extend the skillful lead time of short-term rainfall forecasts, which should increase decision-making times. We implemented an adaptive scale-dependent ensemble blending method in the open-source pysteps library, based on the Short-Term Ensemble Prediction System scheme. In this implementation, the extrapolation (ensemble) nowcast, (ensemble) NWP, and noise components are combined with skill-dependent weights that vary per spatial scale level. To constrain the (dis)appearance of rain in the ensemble members to regions around the rainy areas, we have developed a Lagrangian blended probability matching scheme and incremental masking strategy. We describe the implementation details and evaluate the method using three heavy and extreme (July 2021) rainfall events in four Belgian and Dutch catchments. We benchmark the results of the 48-member blended forecasts against the Belgian NWP forecast, a 48-member nowcast, and a simple 48-member linear blending approach. Both on the radar domain and catchment scale, the introduced blending approach predominantly performs similarly or better than only nowcasting (in terms of event-averaged continuous ranked probability score and critical success index values) and adds value compared with NWP for the first hours of the forecast, although the difference, particularly with the linear blending method, reduces when we focus on catchment-average cumulative rainfall sums instead of instantaneous rainfall rates. By properly combining observations and NWP forecasts, blending methods such as these are

Published

2023

5. Scale-dependent blending of ensemble rainfall nowcasts and numerical weather prediction in the open-source pysteps library

Author

Imhoff, Ruben O. (author), De Cruz, Lesley (author), Dewettinck, Wout (author), Brauer, Claudia C. (author), Uijlenhoet, R. (author), van Heeringen, Klaas Jan (author), Velasco-Forero, Carlos (author), Nerini, Daniele (author), Van Ginderachter, Michiel (author), Weerts, Albrecht H. (author), Imhoff, Ruben O. (author), De Cruz, Lesley (author), Dewettinck, Wout (author), Brauer, Claudia C. (author), Uijlenhoet, R. (author), van Heeringen, Klaas Jan (author), Velasco-Forero, Carlos (author), Nerini, Daniele (author), Van Ginderachter, Michiel (author), and Weerts, Albrecht H. (author)

Abstract

Flash flood early warning requires accurate rainfall forecasts with a high spatial and temporal resolution. As the first few hours ahead are already not sufficiently well captured by the rainfall forecasts of numerical weather prediction (NWP) models, radar rainfall nowcasting can provide an alternative. Because this observation-based method quickly loses skill after the first 2 hr of the forecast, it needs to be combined with NWP forecasts to extend the skillful lead time of short-term rainfall forecasts, which should increase decision-making times. We implemented an adaptive scale-dependent ensemble blending method in the open-source pysteps library, based on the Short-Term Ensemble Prediction System scheme. In this implementation, the extrapolation (ensemble) nowcast, (ensemble) NWP, and noise components are combined with skill-dependent weights that vary per spatial scale level. To constrain the (dis)appearance of rain in the ensemble members to regions around the rainy areas, we have developed a Lagrangian blended probability matching scheme and incremental masking strategy. We describe the implementation details and evaluate the method using three heavy and extreme (July 2021) rainfall events in four Belgian and Dutch catchments. We benchmark the results of the 48-member blended forecasts against the Belgian NWP forecast, a 48-member nowcast, and a simple 48-member linear blending approach. Both on the radar domain and catchment scale, the introduced blending approach predominantly performs similarly or better than only nowcasting (in terms of event-averaged continuous ranked probability score and critical success index values) and adds value compared with NWP for the first hours of the forecast, although the difference, particularly with the linear blending method, reduces when we focus on catchment-average cumulative rainfall sums instead of instantaneous rainfall rates. By properly combining observations and NWP forecasts, blending methods such as these, Water Resources

Published

2023

6. Where should hydrology go? An early-career perspective on the next IAHS Scientific Decade: 2023–2032

Author

van Hateren, Theresa C., Jongen, Harro J., Alzawaidah, Hadeel, Beemster, Joris G.W., Boekee, Judith, Bogerd, Linda, Gao, Sijia, Kannen, Christin, van Meerveld, Ilja, de Lange, Sjoukje I., Linke, Felicia, Pinto, Rose B., Remmers, Janneke O.E., Ruijsch, Jessica, Rusli, Steven R., van de Vijsel, Roeland C., Aerts, Jerom P.M., Agoungbome, Sehouevi M.D., Anys, Markus, Blanco ramírez, Sara, van Emmerik, Tim, Gallitelli, Luca, Chiquito Gesualdo, Gabriela, Gonzalez Otero, Wendy, Hanus, Sarah, He, Zixiao, Hoffmeister, Svenja, Imhoff, Ruben O., Kerlin, Tim, Meshram, Sumit M., Meyer, Judith, Meyer Oliveira, Aline, Müller, Andreas C.T., Nijzink, Remko, Scheller, Mirjam, Schreyers, Louise, Sehgal, Dhruv, Tasseron, Paolo F., Teuling, Adriaan J., Trevisson, Michele, Waldschläger, Kryss, Walraven, Bas, Wannasin, Chanoknun, Wienhöfer, Jan, Zander, Mar J., Zhang, Shulin, Zhou, Jingwei, Zomer, Judith Y., Zwartendijk, Bob W., van Hateren, Theresa C., Jongen, Harro J., Alzawaidah, Hadeel, Beemster, Joris G.W., Boekee, Judith, Bogerd, Linda, Gao, Sijia, Kannen, Christin, van Meerveld, Ilja, de Lange, Sjoukje I., Linke, Felicia, Pinto, Rose B., Remmers, Janneke O.E., Ruijsch, Jessica, Rusli, Steven R., van de Vijsel, Roeland C., Aerts, Jerom P.M., Agoungbome, Sehouevi M.D., Anys, Markus, Blanco ramírez, Sara, van Emmerik, Tim, Gallitelli, Luca, Chiquito Gesualdo, Gabriela, Gonzalez Otero, Wendy, Hanus, Sarah, He, Zixiao, Hoffmeister, Svenja, Imhoff, Ruben O., Kerlin, Tim, Meshram, Sumit M., Meyer, Judith, Meyer Oliveira, Aline, Müller, Andreas C.T., Nijzink, Remko, Scheller, Mirjam, Schreyers, Louise, Sehgal, Dhruv, Tasseron, Paolo F., Teuling, Adriaan J., Trevisson, Michele, Waldschläger, Kryss, Walraven, Bas, Wannasin, Chanoknun, Wienhöfer, Jan, Zander, Mar J., Zhang, Shulin, Zhou, Jingwei, Zomer, Judith Y., and Zwartendijk, Bob W.

Abstract

This paper shares an early-career perspective on potential themes for the upcoming International Association of Hydrological Sciences (IAHS) Scientific Decade (SD). This opinion paper synthesizes six discussion sessions in western Europe identifying three themes that all offer a different perspective on the hydrological threats the world faces and could serve to direct the broader hydrological community: “Tipping points and thresholds in hydrology,” “Intensification of the water cycle,” and “Water services under pressure.” Additionally, four trends were distinguished concerning the way in which hydrological research is conducted: big data, bridging science and practice, open science, and inter- and multidisciplinarity. These themes and trends will provide valuable input for future discussions on the theme for the next IAHS SD. We encourage other early-career scientists to voice their opinion by organizing their own discussion sessions and commenting on this paper to make this initiative grow from a regional initiative to a global movement.

Published

2023

7. Where should hydrology go? An early-career perspective on the next IAHS Scientific Decade: 2023-2032

Author

van Hateren, Theresa C; https://orcid.org/0000-0002-1589-6079, Jongen, Harro J; https://orcid.org/0000-0002-7538-4796, Al-Zawaidah, Hadeel; https://orcid.org/0000-0002-4644-3224, Beemster, Joris G W; https://orcid.org/0000-0002-3178-6689, Boekee, Judith; https://orcid.org/0000-0002-1861-2596, Bogerd, Linda; https://orcid.org/0000-0002-7343-4542, Gao, Sijia; https://orcid.org/0000-0001-7050-0527, Kannen, Christin; https://orcid.org/0000-0002-0412-4970, van Meerveld, H J; https://orcid.org/0000-0002-7547-3270, de Lange, Sjoukje I; https://orcid.org/0000-0002-8898-3501, Linke, Felicia; https://orcid.org/0000-0001-7230-0975, Pinto, Rose B; https://orcid.org/0000-0003-4520-9548, Remmers, Janneke O E; https://orcid.org/0000-0002-7594-890X, Ruijsch, Jessica; https://orcid.org/0000-0001-6510-7499, Rusli, Steven R; https://orcid.org/0000-0002-1189-1553, van de Vijsel, Roeland C; https://orcid.org/0000-0002-5615-8101, Aerts, Jerom P M; https://orcid.org/0000-0003-0157-4818, Agoungbome, Sehouevi M D; https://orcid.org/0000-0003-4923-3924, Anys, Markus; https://orcid.org/0000-0001-9643-9939, Blanco Ramírez, Sara; https://orcid.org/0000-0002-9638-6272, van Emmerik, Tim; https://orcid.org/0000-0002-4773-9107, Gallitelli, Luca; https://orcid.org/0000-0002-2188-4584, chiquito Gesualdo, Gabriela; https://orcid.org/0000-0001-6589-3397, Gonzalez Otero, Wendy, Hanus, Sarah; https://orcid.org/0000-0002-5232-6964, He, Zixiao; https://orcid.org/0000-0001-7576-8055, Hoffmeister, Svenja; https://orcid.org/0000-0002-4785-1836, Imhoff, Ruben O; https://orcid.org/0000-0002-4096-3528, Kerlin, Tim; https://orcid.org/0000-0002-0424-6193, Meshram, Sumit M, Meyer Oliveira, Aline; https://orcid.org/0000-0002-7076-4570, Scheller, Mirjam; https://orcid.org/0009-0005-3826-8007, et al, van Hateren, Theresa C; https://orcid.org/0000-0002-1589-6079, Jongen, Harro J; https://orcid.org/0000-0002-7538-4796, Al-Zawaidah, Hadeel; https://orcid.org/0000-0002-4644-3224, Beemster, Joris G W; https://orcid.org/0000-0002-3178-6689, Boekee, Judith; https://orcid.org/0000-0002-1861-2596, Bogerd, Linda; https://orcid.org/0000-0002-7343-4542, Gao, Sijia; https://orcid.org/0000-0001-7050-0527, Kannen, Christin; https://orcid.org/0000-0002-0412-4970, van Meerveld, H J; https://orcid.org/0000-0002-7547-3270, de Lange, Sjoukje I; https://orcid.org/0000-0002-8898-3501, Linke, Felicia; https://orcid.org/0000-0001-7230-0975, Pinto, Rose B; https://orcid.org/0000-0003-4520-9548, Remmers, Janneke O E; https://orcid.org/0000-0002-7594-890X, Ruijsch, Jessica; https://orcid.org/0000-0001-6510-7499, Rusli, Steven R; https://orcid.org/0000-0002-1189-1553, van de Vijsel, Roeland C; https://orcid.org/0000-0002-5615-8101, Aerts, Jerom P M; https://orcid.org/0000-0003-0157-4818, Agoungbome, Sehouevi M D; https://orcid.org/0000-0003-4923-3924, Anys, Markus; https://orcid.org/0000-0001-9643-9939, Blanco Ramírez, Sara; https://orcid.org/0000-0002-9638-6272, van Emmerik, Tim; https://orcid.org/0000-0002-4773-9107, Gallitelli, Luca; https://orcid.org/0000-0002-2188-4584, chiquito Gesualdo, Gabriela; https://orcid.org/0000-0001-6589-3397, Gonzalez Otero, Wendy, Hanus, Sarah; https://orcid.org/0000-0002-5232-6964, He, Zixiao; https://orcid.org/0000-0001-7576-8055, Hoffmeister, Svenja; https://orcid.org/0000-0002-4785-1836, Imhoff, Ruben O; https://orcid.org/0000-0002-4096-3528, Kerlin, Tim; https://orcid.org/0000-0002-0424-6193, Meshram, Sumit M, Meyer Oliveira, Aline; https://orcid.org/0000-0002-7076-4570, Scheller, Mirjam; https://orcid.org/0009-0005-3826-8007, and et al

Abstract

This paper shares an early-career perspective on potential themes for the upcoming International Association of Hydrological Sciences (IAHS) scientific decade (SD). This opinion paper synthesizes six discussion sessions in western Europe identifying three themes that all offer a different perspective on the hydrological threats the world faces and could serve to direct the broader hydrological community: “Tipping points and thresholds in hydrology”, “Intensification of the water cycle”, and “Water services under pressure”. Additionally, four trends were distinguished concerning the way in which hydrological research is conducted: big data, bridging science and practice, open science, and inter- and multidisciplinarity. These themes and trends will provide valuable input for future discussions on the theme for the next IAHS SD. We encourage other Early-Career Scientists to voice their opinion by organizing their own discussion sessions and commenting on this paper to make this initiative grow from a regional initiative to a global movement.

Published

2023

8. Scale‐dependent blending of ensemble rainfall nowcasts and NWP in the open‐source pysteps library

Author

Imhoff, Ruben O., primary, De Cruz, Lesley, additional, Dewettinck, Wout, additional, Brauer, Claudia C., additional, Uijlenhoet, Remko, additional, van Heeringen, Klaas‐Jan, additional, Velasco‐Forero, Carlos, additional, Nerini, Daniele, additional, Van Ginderachter, Michiel, additional, and Weerts, Albrecht H., additional

Published

2023

9. Where should hydrology go? An early-career perspective on the next IAHS Scientific Decade: 2023–2032

Author

van Hateren, Theresa C., primary, Jongen, Harro J., additional, Al-Zawaidah, Hadeel, additional, Beemster, Joris G.W., additional, Boekee, Judith, additional, Bogerd, Linda, additional, Gao, Sijia, additional, Kannen, Christin, additional, van Meerveld, Ilja, additional, de Lange, Sjoukje I., additional, Linke, Felicia, additional, Pinto, Rose B., additional, Remmers, Janneke O.E., additional, Ruijsch, Jessica, additional, Rusli, Steven R., additional, van de Vijsel, Roeland C., additional, Aerts, Jerom P.M., additional, Agoungbome, Sehouevi M.D., additional, Anys, Markus, additional, Blanco Ramírez, Sara, additional, van Emmerik, Tim, additional, Gallitelli, Luca, additional, Chiquito Gesualdo, Gabriela, additional, Gonzalez Otero, Wendy, additional, Hanus, Sarah, additional, He, Zixiao, additional, Hoffmeister, Svenja, additional, Imhoff, Ruben O., additional, Kerlin, Tim, additional, Meshram, Sumit M., additional, Meyer, Judith, additional, Meyer Oliveira, Aline, additional, Müller, Andreas C.T., additional, Nijzink, Remko, additional, Scheller, Mirjam, additional, Schreyers, Louise, additional, Sehgal, Dhruv, additional, Tasseron, Paolo F., additional, Teuling, Adriaan J., additional, Trevisson, Michele, additional, Waldschläger, Kryss, additional, Walraven, Bas, additional, Wannasin, Chanoknun, additional, Wienhöfer, Jan, additional, Zander, Mar J., additional, Zhang, Shulin, additional, Zhou, Jingwei, additional, Zomer, Judith Y., additional, and Zwartendijk, Bob W., additional

Published

2023

10. Scale-dependent blending of ensemble rainfall nowcasts and numerical weather prediction in the open-source pysteps library

Author

Ruben O. Imhoff, Lesley De Cruz, Wout Dewettinck, Claudia C. Brauer, Remko Uijlenhoet, Klaas‐Jan van Heeringen, Carlos Velasco‐Forero, Daniele Nerini, Michiel Van Ginderachter, Albrecht H. Weerts, and Electronics and Informatics

Subjects

early warning, Atmospheric Science, open source, rainfall, numerical weather prediction, Nowcasting, Blending

Abstract

Flash flood early warning requires accurate rainfall forecasts with a high spatial and temporal resolution. As the first few hours ahead are already not sufficiently well captured by the rainfall forecasts of numerical weather prediction (NWP) models, radar rainfall nowcasting can provide an alternative. Because this observation-based method quickly loses skill after the first 2 hr of the forecast, it needs to be combined with NWP forecasts to extend the skillful lead time of short-term rainfall forecasts, which should increase decision-making times. We implemented an adaptive scale-dependent ensemble blending method in the open-source pysteps library, based on the Short-Term Ensemble Prediction System scheme. In this implementation, the extrapolation (ensemble) nowcast, (ensemble) NWP, and noise components are combined with skill-dependent weights that vary per spatial scale level. To constrain the (dis)appearance of rain in the ensemble members to regions around the rainy areas, we have developed a Lagrangian blended probability matching scheme and incremental masking strategy. We describe the implementation details and evaluate the method using three heavy and extreme (July 2021) rainfall events in four Belgian and Dutch catchments. We benchmark the results of the 48-member blended forecasts against the Belgian NWP forecast, a 48-member nowcast, and a simple 48-member linear blending approach. Both on the radar domain and catchment scale, the introduced blending approach predominantly performs similarly or better than only nowcasting (in terms of event-averaged continuous ranked probability score and critical success index values) and adds value compared with NWP for the first hours of the forecast, although the difference, particularly with the linear blending method, reduces when we focus on catchment-average cumulative rainfall sums instead of instantaneous rainfall rates. By properly combining observations and NWP forecasts, blending methods such as these are a crucial component of seamless prediction systems.

Published

2023

11. Where should hydrology go? An early-career perspective on the next IAHS Scientific Decade: 2023-2032

Author

van Hateren, Theresa C, Jongen, Harro J, Al-Zawaidah, Hadeel, Beemster, Joris G W, Boekee, Judith, Bogerd, Linda, Gao, Sijia, Kannen, Christin, van Meerveld, H J, de Lange, Sjoukje I, Linke, Felicia, Pinto, Rose B, Remmers, Janneke O E, Ruijsch, Jessica, Rusli, Steven R, van de Vijsel, Roeland C, Aerts, Jerom P M, Agoungbome, Sehouevi M D, Anys, Markus, Blanco Ramírez, Sara, van Emmerik, Tim, Gallitelli, Luca, chiquito Gesualdo, Gabriela, Gonzalez Otero, Wendy, Hanus, Sarah, He, Zixiao, Hoffmeister, Svenja, Imhoff, Ruben O, Kerlin, Tim, Meshram, Sumit M, Meyer Oliveira, Aline, Scheller, Mirjam, et al, and University of Zurich

Subjects

10122 Institute of Geography, 910 Geography & travel, Water Science and Technology

Published

2023

12. Wflow_sbm v0.6.1, a spatially distributed hydrologic model: from global data to local applications

Author

Willem J. van Verseveld, Albrecht H. Weerts, Martijn Visser, Joost Buitink, Ruben O. Imhoff, Hélène Boisgontier, Laurène Bouaziz, Dirk Eilander, Mark Hegnauer, Corine ten Velden, and Bobby Russell

Abstract

The wflow_sbm hydrologic model, recently released by Deltares, as part of the Wflow.jl (v0.6.1) modelling framework is being used to better understand and potentially address multiple operational and water resources planning challenges from catchment scale, national scale to continental and global scale. Wflow.jl is a free and open-source distributed hydrologic modelling framework written in the Julia programming language. The development of wflow_sbm, the model structure, equations and functionalitities are described in detail, including example applications of wflow_sbm. The wflow_sbm model aims to strike a balance between low-resolution, low-complexity and high-resolution, high-complexity hydrologic models. Most wflow_sbm parameters are based on physical characteristics or processes and at the same time wflow_sbm has a runtime performance well suited for large-scale high-resolution model applications. Wflow_sbm models can be set a priori for any catchment with the Python tool HydroMT-Wflow based on globally available datasets and through the use of point-scale (pedo)transfer functions and suitable upscaling rules and generally results in a satisfactory (0.4 ≥ Kling-Gupta Efficiency (KGE) < 0.7) to good (KGE ≥ 0.7) performance a-priori (without further tuning). Wflow_sbm includes relevant hydrologic processes as glacier and snow processes, evapotranspiration processes, unsaturated zone dynamics, (shallow) groundwater and surface flow routing including lakes and reservoirs. Further planned developments include improvements on the computational efficiency and flexibility of the routing scheme, implementation of a water demand and allocation module for water resources modelling, the addition of a deep groundwater concept and distributed computing with a focus on multi-node parallelism.

Published

2022

13. Wflow_sbm v0.6.1, a spatially distributed hydrologic model: from global data to local applications

Author

van Verseveld, Willem J., primary, Weerts, Albrecht H., additional, Visser, Martijn, additional, Buitink, Joost, additional, Imhoff, Ruben O., additional, Boisgontier, Hélène, additional, Bouaziz, Laurène, additional, Eilander, Dirk, additional, Hegnauer, Mark, additional, ten Velden, Corine, additional, and Russell, Bobby, additional

Published

2022

14. Wflow_sbm v0.6.1, a spatially distributed hydrologic model: from global data to local applications.

Author

van Verseveld, Willem J., Weerts, Albrecht H., Visser, Martijn, Buitink, Joost, Imhoff, Ruben O., Boisgontier, Hélène, Bouaziz, Laurène, Eilander, Dirk, Hegnauer, Mark, ten Velden, Corine, and Russell, Bobby

Subjects

HYDROLOGIC models, WATER rights, PYTHON programming language, WATER table, WATER supply, GROUNDWATER flow, EVAPOTRANSPIRATION

Abstract

The wflow_sbm hydrologic model, recently released by Deltares, as part of the Wflow.jl (v0.6.1) modelling framework is being used to better understand and potentially address multiple operational and water resources planning challenges from catchment scale, national scale to continental and global scale. Wflow.jl is a free and open-source distributed hydrologic modelling framework written in the Julia programming language. The development of wflow_sbm, the model structure, equations and functionalitities are described in detail, including example applications of wflow_sbm. The wflow_sbm model aims to strike a balance between low-resolution, low-complexity and high-resolution, high-complexity hydrologic models. Most wflow_sbm parameters are based on physical characteristics or processes and at the same time wflow_sbm has a runtime performance well suited for large-scale high-resolution model applications. Wflow_sbm models can be set a priori for any catchment with the Python tool HydroMT-Wflow based on globally available datasets and through the use of point-scale (pedo)transfer functions and suitable upscaling rules and generally results in a satisfactory (0.4 = Kling-Gupta Efficiency (KGE) < 0.7) to good (KGE = 0.7) performance a-priori (without further tuning). Wflow_sbm includes relevant hydrologic processes as glacier and snow processes, evapotranspiration processes, unsaturated zone dynamics, (shallow) groundwater and surface flow routing including lakes and reservoirs. Further planned developments include improvements on the computational efficiency and flexibility of the routing scheme, implementation of a water demand and allocation module for water resources modelling, the addition of a deep groundwater concept and distributed computing with a focus on multi-node parallelism. [ABSTRACT FROM AUTHOR]

Published

2022