Explicit scheme for a hydrological channel routing: mathematical model and practical application

The computation of hydrographs in large watersheds necessitates utilizing channel routing, which calculates the movement of hydrographs along channel branches. Routing methods rely on an implicit scheme to facilitate numerical resolution, which requires more computational time than the explicit sche...

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Autores:: Arrieta-Pastrana, Alfonso
Coronado-Hernández, Oscar E.
Coronado Hernandez, Jairo R.
Coronado Hernández, Oscar E.

Tipo de recurso:: Article of investigation

Fecha de publicación:: 2024

Institución:: Corporación Universidad de la Costa

Repositorio:: REDICUC - Repositorio CUC

Idioma:: eng

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network_acronym_str	RCUC2
network_name_str	REDICUC - Repositorio CUC
repository_id_str
dc.title.eng.fl_str_mv	Explicit scheme for a hydrological channel routing: mathematical model and practical application
title	Explicit scheme for a hydrological channel routing: mathematical model and practical application
spellingShingle	Explicit scheme for a hydrological channel routing: mathematical model and practical application Lumped method Mathematical model Open channel Rainfall-runoff Routing
title_short	Explicit scheme for a hydrological channel routing: mathematical model and practical application
title_full	Explicit scheme for a hydrological channel routing: mathematical model and practical application
title_fullStr	Explicit scheme for a hydrological channel routing: mathematical model and practical application
title_full_unstemmed	Explicit scheme for a hydrological channel routing: mathematical model and practical application
title_sort	Explicit scheme for a hydrological channel routing: mathematical model and practical application
dc.creator.fl_str_mv	Arrieta-Pastrana, Alfonso Coronado-Hernández, Oscar E. Coronado Hernandez, Jairo R. Coronado Hernández, Oscar E.
dc.contributor.author.none.fl_str_mv	Arrieta-Pastrana, Alfonso Coronado-Hernández, Oscar E. Coronado Hernandez, Jairo R. Coronado Hernández, Oscar E.
dc.subject.proposal.eng.fl_str_mv	Lumped method Mathematical model Open channel Rainfall-runoff Routing
topic	Lumped method Mathematical model Open channel Rainfall-runoff Routing
description	The computation of hydrographs in large watersheds necessitates utilizing channel routing, which calculates the movement of hydrographs along channel branches. Routing methods rely on an implicit scheme to facilitate numerical resolution, which requires more computational time than the explicit scheme. This study presents an explicit scheme channel routing model that offers a versatile approach to open channel flow analysis. The model is based on mass conservation principles and Manning equations, and it can accommodate varying bed slopes, making it highly adaptable to diverse hydraulic scenarios. In addition, the proposed model considers backwater effects, which enhances its applicability in practical scenarios. The model was tested in a practical application on a rectangular channel with a width of 7 m, and the results showed that it can accurately predict outflow hydrographs and handle different flow conditions. Comparative analyses with existing models revealed that the proposed model’s performance in generating water flow oscillations was competitive. Moreover, sensitivity analyses were performed, which showed that the model is highly responsive to parameter variations, such as Manning’s coefficient, bed slope, and channel width. The comparison of peak flows and peak times between the proposed model and existing methods further emphasized the model’s reliability and efficiency in simulating channel routing processes. This research introduces a valuable addition to the field of hydrology by proposing a practical and effective channel routing model that integrates essential hydraulic principles and parameters. The results of the proposed model (lumped routing) are comparable with the solution provided by the Muskingum–Cunge method (distributed routing). It is of utmost importance to note that the proposed model applies to channel branches with bed slopes below 6◦ .
publishDate	2024
dc.date.accessioned.none.fl_str_mv	2024-10-23T12:47:28Z
dc.date.available.none.fl_str_mv	2024-10-23T12:47:28Z
dc.date.issued.none.fl_str_mv	2024-05-23
dc.type.none.fl_str_mv	Artículo de revista
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dc.identifier.citation.none.fl_str_mv	Arrieta-Pastrana, A.; Coronado-Hernández, O.E.; Coronado-Hernández, J.R. Explicit Scheme for a Hydrological Channel Routing: Mathematical Model and Practical Application. Water 2024, 16, 1480. https://doi.org/10.3390/ w16111480
dc.identifier.uri.none.fl_str_mv	https://hdl.handle.net/11323/13484
dc.identifier.doi.none.fl_str_mv	10.3390/w16111480
dc.identifier.eissn.none.fl_str_mv	2073-4441
dc.identifier.instname.none.fl_str_mv	Corporación Universidad de la Costa
dc.identifier.reponame.none.fl_str_mv	REDICUC - Repositorio CUC
dc.identifier.repourl.none.fl_str_mv	https://repositorio.cuc.edu.co/
identifier_str_mv	Arrieta-Pastrana, A.; Coronado-Hernández, O.E.; Coronado-Hernández, J.R. Explicit Scheme for a Hydrological Channel Routing: Mathematical Model and Practical Application. Water 2024, 16, 1480. https://doi.org/10.3390/ w16111480 10.3390/w16111480 2073-4441 Corporación Universidad de la Costa REDICUC - Repositorio CUC
url	https://hdl.handle.net/11323/13484 https://repositorio.cuc.edu.co/
dc.language.iso.none.fl_str_mv	eng
language	eng
dc.relation.ispartofjournal.none.fl_str_mv	Water
dc.relation.references.none.fl_str_mv	1. Chow, V.T.; Maidment, D.R.; Mays, L.W. Applied Hydrology; McGraw-Hill: New York, NY, USA, 1988. 2. Fenton, J.D. Flood Routing Methods. J. Hydrol. 2019, 570, 251–264. [CrossRef] 3. G ˛asiorowski, D.; Szymkiewicz, R. Inverse Flood Routing Using Simplified Flow Equations. Water Resour. Manag. 2022, 36, 4115–4135. [CrossRef] 4. Todini, E. Hydraulic and Hydrologic Flood Routing Schemes. In Recent Advances in the Modeling of Hydrologic Systems; Bowles, D.S., O’Connell, P.E., Eds.; Springer: Dordrecht, The Netherlands, 1991; pp. 389–405. [CrossRef] 5. Theodor, S. Numerical Solution of Saint-Venant Equations. J. Hydraul. Div. 1970, 96, 223–252. [CrossRef] 6. Smith, A.A. A Generalized Approach to Kinematic Flood Routing. J. Hydrol. 1980, 45, 71–89. [CrossRef] 7. Tseng, M.-H. Kinematic Wave Computation Using an Efficient Implicit Method. J. Hydroinform. 2010, 12, 329–338. [CrossRef] 8. Unver, O.; Mays, L.W.; Lansey, K. Real-Time Flood Management Model for Highland Lake System. J. Water Resour. Plan. Manag. 1987, 113, 620–638. [CrossRef] 9. Moreda, F.; Gutierrez, A.; Reed, S.; Aschwanden, C. Transitioning NWS Operational Hydraulics Models from FLDWAV to HEC-RAS. In World Environmental and Water Resources Congress; ASCE: Reston, VA, USA, 2009; pp. 1–11. [CrossRef] 10. Barry, D.A.; Bajracharya, K. On the Muskingum-Cunge Flood Routing Method. Environ. Int. 1995, 21, 485–490. [CrossRef] 11. USACE. Hydrologic Modeling System HEC-HMS Technical Reference Manual; US Army Corps of Engineers: Davis, CA, USA, 2000. 12. Salvati, A.; Moghaddam Nia, A.; Salajegheh, A.; Shirzadi, A.; Shahabi, H.; Ahmadisharaf, E.; Han, D.; Clague, J.J. A Systematic Review of Muskingum Flood Routing Techniques. Hydrol. Sci. J. 2024, 69, 810–831. [CrossRef] 13. Tahiri, A.; Che, D.; Ladeveze, D.; Chiron, P.; Archimède, B. Network Flow and Flood Routing Model for Water Resources Optimization. Sci. Rep. 2022, 12, 3937. [CrossRef] [PubMed] 14. Cunge, J.A. On The Subject of A Flood Propagation Computation Method (Musklngum Method). J. Hydraul. Res. 1969, 7, 205–230. [CrossRef] 15. Tang, X.-N.; Knight, D.W.; Samuels, P.G. Volume Conservation in Variable Parameter Muskingum-Cunge Method. J. Hydraul. Eng. 1999, 125, 610–620. [CrossRef] 16. Lozano Sandoval, G.; Aníbal Monsalve, E.; García Reinoso, P.L.; Rodríguez Mejía, C.A.; Gómez Ospina, J.P.; Triviño Loaiza, H.J. Environmental Flow Estimation Using Hydrological and Hydraulic Methods for the Quindío River Basin: WEAP as a Support Tool. Inge Cuc 2015, 11, 34–48. [CrossRef] 17. Dotson, H.W. Watershed Modeling with HEC-HMS (Hydrologic Engineering Centers-Hydrologic Modeling System) Using Spatially Distributed Rainfall. In Coping with Flash Floods; Springer: Berlin/Heidelberg, Germany, 2001; pp. 219–230. 18. Francés, F.; Vélez, J.I.; Vélez, J.J. Split-parameter structure for the automatic calibration of distributed hydrological models. J. Hydrol. 2007, 332, 226–240. [CrossRef] 19. Lee, E.H. Development of a New 8-Parameter Muskingum Flood Routing Model with Modified Inflows. Water 2021, 13, 3170. [CrossRef] 20. Lee, E.H.; Lee, H.M.; Kim, J.H. Development and Application of Advanced Muskingum Flood Routing Model Considering Continuous Flow. Water 2018, 10, 760. [CrossRef] 21. Bindas, T.; Tsai, W.-P.; Liu, J.; Rahmani, F.; Feng, D.; Bian, Y.; Lawson, K.; Shen, C. Improving River Routing Using a Differentiable Muskingum-Cunge Model and Physics-Informed Machine Learning. Water Resour. Res. 2024, 60, e2023WR035337. [CrossRef] 22. Li, L.; Jun, K.S. Review of Machine Learning Methods for River Flood Routing. Water 2024, 16, 364. [CrossRef] 23. Singh Vijay, P.; Scarlatos Panagiotis, D. Analysis of Nonlinear Muskingum Flood Routing. J. Hydraul. Eng. 1987, 113, 61–79. [CrossRef] 24. Meisam, B.; Reza, B.; Emrah, D.; Gokmen, T. Reverse Flood Routing in Rivers Using Linear and Nonlinear Muskingum Models. J. Hydrol. Eng. 2021, 26, 04021018. [CrossRef] 25. Balamurugan, M.; Murty Bhallamudi, S. Flood Routing in an Ephemeral Channel with Compound Cross-Section. Sadhan ¯ a¯ 2016, 41, 771–785. [CrossRef] 26. Costabile, P.; Macchione, F. Analysis of One-Dimensional Modelling for Flood Routing in Compound Channels. Water Resour. Manag. 2012, 26, 1065–1087. [CrossRef] 27. Jesna, I.; Bhallamudi, S.M.; Sudheer, K.P. Impact of Cross-Sectional Orientation in One-Dimensional Hydrodynamic Modeling on Flood Inundation Mapping. J. Flood Risk Manag. 2023, 16, e12893. [CrossRef] 28. Rahimi, H.; Yuan, S.; Tang, X.; Lu, C.; Singh, P.; Dehrashid, F.A. Study on Conveyance Coefficient Influenced by Momentum Exchange Under Steady and Unsteady Flows in Compound Open Channels. Water Resour. Manag. 2022, 36, 2179–2199. [CrossRef] 29. Chow, V.T. Open-Channel Hydraulics; McGraw-Hill: Tokyo, Japan, 1959. 30. Prawira, D.; Soeryantono, H.; Anggraheni, E.; Sutjiningsih, D. Efficiency Analysis of Muskingum-Cunge Method and Kinematic Wave Method on the Stream Routing (Study Case: Upper Ciliwung Watershed, Indonesia). IOP Conf. Ser. Mater. Sci. Eng. 2019, 669, 012036. [CrossRef]
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dc.relation.citationissue.none.fl_str_mv	11
dc.relation.citationvolume.none.fl_str_mv	16
dc.relation.citationedition.none.fl_str_mv	15
dc.rights.eng.fl_str_mv	©2024 by the authors. Licensee MDPI, Basel, Switzerland.
dc.rights.license.none.fl_str_mv	Atribución 4.0 Internacional (CC BY 4.0)
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rights_invalid_str_mv	Atribución 4.0 Internacional (CC BY 4.0) ©2024 by the authors. Licensee MDPI, Basel, Switzerland. https://creativecommons.org/licenses/by/4.0/ http://purl.org/coar/access_right/c_abf2
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dc.format.extent.none.fl_str_mv	15 páginas
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publisher.none.fl_str_mv	Multidisciplinary Digital Publishing Institute (MDPI)
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institution	Corporación Universidad de la Costa
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spelling	Atribución 4.0 Internacional (CC BY 4.0)©2024 by the authors. Licensee MDPI, Basel, Switzerland.https://creativecommons.org/licenses/by/4.0/info:eu-repo/semantics/openAccesshttp://purl.org/coar/access_right/c_abf2Arrieta-Pastrana, AlfonsoCoronado-Hernández, Oscar E.Coronado Hernandez, Jairo R.virtual::127-1Coronado Hernández, Oscar E.2024-10-23T12:47:28Z2024-10-23T12:47:28Z2024-05-23Arrieta-Pastrana, A.; Coronado-Hernández, O.E.; Coronado-Hernández, J.R. Explicit Scheme for a Hydrological Channel Routing: Mathematical Model and Practical Application. Water 2024, 16, 1480. https://doi.org/10.3390/ w16111480https://hdl.handle.net/11323/1348410.3390/w161114802073-4441Corporación Universidad de la CostaREDICUC - Repositorio CUChttps://repositorio.cuc.edu.co/The computation of hydrographs in large watersheds necessitates utilizing channel routing, which calculates the movement of hydrographs along channel branches. Routing methods rely on an implicit scheme to facilitate numerical resolution, which requires more computational time than the explicit scheme. This study presents an explicit scheme channel routing model that offers a versatile approach to open channel flow analysis. The model is based on mass conservation principles and Manning equations, and it can accommodate varying bed slopes, making it highly adaptable to diverse hydraulic scenarios. In addition, the proposed model considers backwater effects, which enhances its applicability in practical scenarios. The model was tested in a practical application on a rectangular channel with a width of 7 m, and the results showed that it can accurately predict outflow hydrographs and handle different flow conditions. Comparative analyses with existing models revealed that the proposed model’s performance in generating water flow oscillations was competitive. Moreover, sensitivity analyses were performed, which showed that the model is highly responsive to parameter variations, such as Manning’s coefficient, bed slope, and channel width. The comparison of peak flows and peak times between the proposed model and existing methods further emphasized the model’s reliability and efficiency in simulating channel routing processes. This research introduces a valuable addition to the field of hydrology by proposing a practical and effective channel routing model that integrates essential hydraulic principles and parameters. The results of the proposed model (lumped routing) are comparable with the solution provided by the Muskingum–Cunge method (distributed routing). It is of utmost importance to note that the proposed model applies to channel branches with bed slopes below 6◦ .15 páginasapplication/pdfengMultidisciplinary Digital Publishing Institute (MDPI)Switzerlandhttps://www.mdpi.com/2073-4441/16/11/1480Explicit scheme for a hydrological channel routing: mathematical model and practical applicationArtículo de revistahttp://purl.org/coar/resource_type/c_2df8fbb1Textinfo:eu-repo/semantics/articlehttp://purl.org/redcol/resource_type/ARTinfo:eu-repo/semantics/publishedVersionhttp://purl.org/coar/version/c_970fb48d4fbd8a85Water1. Chow, V.T.; Maidment, D.R.; Mays, L.W. Applied Hydrology; McGraw-Hill: New York, NY, USA, 1988.2. Fenton, J.D. Flood Routing Methods. J. Hydrol. 2019, 570, 251–264. [CrossRef]3. G ˛asiorowski, D.; Szymkiewicz, R. Inverse Flood Routing Using Simplified Flow Equations. Water Resour. Manag. 2022, 36, 4115–4135. [CrossRef]4. Todini, E. Hydraulic and Hydrologic Flood Routing Schemes. In Recent Advances in the Modeling of Hydrologic Systems; Bowles, D.S., O’Connell, P.E., Eds.; Springer: Dordrecht, The Netherlands, 1991; pp. 389–405. [CrossRef]5. Theodor, S. Numerical Solution of Saint-Venant Equations. J. Hydraul. Div. 1970, 96, 223–252. [CrossRef]6. Smith, A.A. A Generalized Approach to Kinematic Flood Routing. J. Hydrol. 1980, 45, 71–89. [CrossRef]7. Tseng, M.-H. Kinematic Wave Computation Using an Efficient Implicit Method. J. Hydroinform. 2010, 12, 329–338. [CrossRef]8. Unver, O.; Mays, L.W.; Lansey, K. Real-Time Flood Management Model for Highland Lake System. J. Water Resour. Plan. Manag. 1987, 113, 620–638. [CrossRef]9. Moreda, F.; Gutierrez, A.; Reed, S.; Aschwanden, C. Transitioning NWS Operational Hydraulics Models from FLDWAV to HEC-RAS. In World Environmental and Water Resources Congress; ASCE: Reston, VA, USA, 2009; pp. 1–11. [CrossRef]10. Barry, D.A.; Bajracharya, K. On the Muskingum-Cunge Flood Routing Method. Environ. Int. 1995, 21, 485–490. [CrossRef]11. USACE. Hydrologic Modeling System HEC-HMS Technical Reference Manual; US Army Corps of Engineers: Davis, CA, USA, 2000.12. Salvati, A.; Moghaddam Nia, A.; Salajegheh, A.; Shirzadi, A.; Shahabi, H.; Ahmadisharaf, E.; Han, D.; Clague, J.J. A Systematic Review of Muskingum Flood Routing Techniques. Hydrol. Sci. J. 2024, 69, 810–831. [CrossRef]13. Tahiri, A.; Che, D.; Ladeveze, D.; Chiron, P.; Archimède, B. Network Flow and Flood Routing Model for Water Resources Optimization. Sci. Rep. 2022, 12, 3937. [CrossRef] [PubMed]14. Cunge, J.A. On The Subject of A Flood Propagation Computation Method (Musklngum Method). J. Hydraul. Res. 1969, 7, 205–230. [CrossRef]15. Tang, X.-N.; Knight, D.W.; Samuels, P.G. Volume Conservation in Variable Parameter Muskingum-Cunge Method. J. Hydraul. Eng. 1999, 125, 610–620. [CrossRef]16. Lozano Sandoval, G.; Aníbal Monsalve, E.; García Reinoso, P.L.; Rodríguez Mejía, C.A.; Gómez Ospina, J.P.; Triviño Loaiza, H.J. Environmental Flow Estimation Using Hydrological and Hydraulic Methods for the Quindío River Basin: WEAP as a Support Tool. Inge Cuc 2015, 11, 34–48. [CrossRef]17. Dotson, H.W. Watershed Modeling with HEC-HMS (Hydrologic Engineering Centers-Hydrologic Modeling System) Using Spatially Distributed Rainfall. In Coping with Flash Floods; Springer: Berlin/Heidelberg, Germany, 2001; pp. 219–230.18. Francés, F.; Vélez, J.I.; Vélez, J.J. Split-parameter structure for the automatic calibration of distributed hydrological models. J. Hydrol. 2007, 332, 226–240. [CrossRef]19. Lee, E.H. Development of a New 8-Parameter Muskingum Flood Routing Model with Modified Inflows. Water 2021, 13, 3170. [CrossRef]20. Lee, E.H.; Lee, H.M.; Kim, J.H. Development and Application of Advanced Muskingum Flood Routing Model Considering Continuous Flow. Water 2018, 10, 760. [CrossRef]21. Bindas, T.; Tsai, W.-P.; Liu, J.; Rahmani, F.; Feng, D.; Bian, Y.; Lawson, K.; Shen, C. Improving River Routing Using a Differentiable Muskingum-Cunge Model and Physics-Informed Machine Learning. Water Resour. Res. 2024, 60, e2023WR035337. [CrossRef]22. Li, L.; Jun, K.S. Review of Machine Learning Methods for River Flood Routing. Water 2024, 16, 364. [CrossRef]23. Singh Vijay, P.; Scarlatos Panagiotis, D. Analysis of Nonlinear Muskingum Flood Routing. J. Hydraul. Eng. 1987, 113, 61–79. [CrossRef]24. Meisam, B.; Reza, B.; Emrah, D.; Gokmen, T. Reverse Flood Routing in Rivers Using Linear and Nonlinear Muskingum Models. J. Hydrol. Eng. 2021, 26, 04021018. [CrossRef]25. Balamurugan, M.; Murty Bhallamudi, S. Flood Routing in an Ephemeral Channel with Compound Cross-Section. Sadhan ¯ a¯ 2016, 41, 771–785. [CrossRef]26. Costabile, P.; Macchione, F. Analysis of One-Dimensional Modelling for Flood Routing in Compound Channels. Water Resour. Manag. 2012, 26, 1065–1087. [CrossRef]27. Jesna, I.; Bhallamudi, S.M.; Sudheer, K.P. Impact of Cross-Sectional Orientation in One-Dimensional Hydrodynamic Modeling on Flood Inundation Mapping. J. Flood Risk Manag. 2023, 16, e12893. [CrossRef]28. Rahimi, H.; Yuan, S.; Tang, X.; Lu, C.; Singh, P.; Dehrashid, F.A. Study on Conveyance Coefficient Influenced by Momentum Exchange Under Steady and Unsteady Flows in Compound Open Channels. Water Resour. Manag. 2022, 36, 2179–2199. [CrossRef]29. Chow, V.T. Open-Channel Hydraulics; McGraw-Hill: Tokyo, Japan, 1959.30. Prawira, D.; Soeryantono, H.; Anggraheni, E.; Sutjiningsih, D. Efficiency Analysis of Muskingum-Cunge Method and Kinematic Wave Method on the Stream Routing (Study Case: Upper Ciliwung Watershed, Indonesia). IOP Conf. Ser. Mater. Sci. Eng. 2019, 669, 012036. [CrossRef]1111615Lumped methodMathematical modelOpen channelRainfall-runoffRoutingPublication3087a51e-a0b5-440e-8bc9-b7493f503f8cvirtual::127-1ed6debd7-390c-4454-988f-881ac48d12793087a51e-a0b5-440e-8bc9-b7493f503f8cvirtual::127-1https://scholar.google.ca/citations?user=ELMB_rQAAAAJ&hl=enhttps://scholar.google.com/citations?user=dZCUFXoAAAAJ&hl=envirtual::127-10000-0002-6574-08570000-0003-4360-6128virtual::127-1ORIGINALExplicit Scheme for a Hydrological Channel Routing Mathematical Model and Practical Application.pdfExplicit Scheme for a Hydrological Channel Routing Mathematical Model and Practical Application.pdfapplication/pdf2402635https://repositorio.cuc.edu.co/bitstreams/21259256-1cc3-424f-9905-33d83627635d/downloadefd05323e35cefb6597f4fdfec655025MD51LICENSElicense.txtlicense.txttext/plain; charset=utf-815543https://repositorio.cuc.edu.co/bitstreams/58d25c57-8a80-44ec-a97a-9595ad10f4e2/download73a5432e0b76442b22b026844140d683MD52TEXTExplicit Scheme for a Hydrological Channel Routing Mathematical Model and Practical Application.pdf.txtExplicit Scheme for a Hydrological Channel Routing Mathematical Model and Practical Application.pdf.txtExtracted texttext/plain55042https://repositorio.cuc.edu.co/bitstreams/7c812222-735a-41ce-ba88-4cbd861e15fe/download0f52dcf804b3e7b38b849fb78aee6eb7MD53THUMBNAILExplicit Scheme for a Hydrological Channel Routing Mathematical Model and Practical Application.pdf.jpgExplicit Scheme for a Hydrological Channel Routing Mathematical Model and Practical Application.pdf.jpgGenerated Thumbnailimage/jpeg16112https://repositorio.cuc.edu.co/bitstreams/2c2de971-54ae-450b-9e2b-cf0f405b03eb/download83d215a7ae4b0e6a86cc06e3b9c14dd8MD5411323/13484oai:repositorio.cuc.edu.co:11323/134842025-02-25 19:45:26.334https://creativecommons.org/licenses/by/4.0/©2024 by the authors. 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ara ejercer estos derechos sobre la Obra tal y como se indica a continuación:</p>
    <ol type="a">
      <li>Reproducir la Obra, incorporar la Obra en una o más Obras Colectivas, y reproducir la Obra incorporada en las Obras Colectivas.</li>
      <li>Distribuir copias o fonogramas de las Obras, exhibirlas públicamente, ejecutarlas públicamente y/o ponerlas a disposición pública, incluyéndolas como incorporadas en Obras Colectivas, según corresponda.</li>
      <li>Distribuir copias de las Obras Derivadas que se generen, exhibirlas públicamente, ejecutarlas públicamente y/o ponerlas a disposición pública.</li>
    </ol>
    <p>Los derechos mencionados anteriormente pueden ser ejercidos en todos los medios y formatos, actualmente conocidos o que se inventen en el futuro. Los derechos antes mencionados incluyen el derecho a realizar dichas modificaciones en la medida que sean técnicamente necesarias para ejercer los derechos en otro medio o formatos, pero de otra manera usted no está autorizado para realizar obras derivadas. Todos los derechos no otorgados expresamente por el Licenciante quedan por este medio reservados, incluyendo pero sin limitarse a aquellos que se mencionan en las secciones 4(d) y 4(e).</p>
  </li>
  <br/>
  <li>
    Restricciones.
    <p>La licencia otorgada en la anterior Sección 3 está expresamente sujeta y limitada por las siguientes restricciones:</p>
    <ol type="a">
      <li>Usted puede distribuir, exhibir públicamente, ejecutar públicamente, o poner a disposición pública la Obra sólo bajo las condiciones de esta Licencia, y Usted debe incluir una copia de esta licencia o del Identificador Universal de Recursos de la misma con cada copia de la Obra que distribuya, exhiba públicamente, ejecute públicamente o ponga a disposición pública. No es posible ofrecer o imponer ninguna condición sobre la Obra que altere o limite las condiciones de esta Licencia o el ejercicio de los derechos de los destinatarios otorgados en este documento. No es posible sublicenciar la Obra. Usted debe mantener intactos todos los avisos que hagan referencia a esta Licencia y a la cláusula de limitación de garantías. Usted no puede distribuir, exhibir públicamente, ejecutar públicamente, o poner a disposición pública la Obra con alguna medida tecnológica que controle el acceso o la utilización de ella de una forma que sea inconsistente con las condiciones de esta Licencia. Lo anterior se aplica a la Obra incorporada a una Obra Colectiva, pero esto no exige que la Obra Colectiva aparte de la obra misma quede sujeta a las condiciones de esta Licencia. Si Usted crea una Obra Colectiva, previo aviso de cualquier Licenciante debe, en la medida de lo posible, eliminar de la Obra Colectiva cualquier referencia a dicho Licenciante o al Autor Original, según lo solicitado por el Licenciante y conforme lo exige la cláusula 4(c).</li>
      <li>Usted no puede ejercer ninguno de los derechos que le han sido otorgados en la Sección 3 precedente de modo que estén principalmente destinados o directamente dirigidos a conseguir un provecho comercial o una compensación monetaria privada. El intercambio de la Obra por otras obras protegidas por derechos de autor, ya sea a través de un sistema para compartir archivos digitales (digital file-sharing) o de cualquier otra manera no será considerado como estar destinado principalmente o dirigido directamente a conseguir un provecho comercial o una compensación monetaria privada, siempre que no se realice un pago mediante una compensación monetaria en relación con el intercambio de obras protegidas por el derecho de autor.</li>
      <li>Si usted distribuye, exhibe públicamente, ejecuta públicamente o ejecuta públicamente en forma digital la Obra o cualquier Obra Derivada u Obra Colectiva, Usted debe mantener intacta toda la información de derecho de autor de la Obra y proporcionar, de forma razonable según el medio o manera que Usted esté utilizando: (i) el nombre del Autor Original si está provisto (o seudónimo, si fuere aplicable), y/o (ii) el nombre de la parte o las partes que el Autor Original y/o el Licenciante hubieren designado para la atribución (v.g., un instituto patrocinador, editorial, publicación) en la información de los derechos de autor del Licenciante, términos de servicios o de otras formas razonables; el título de la Obra si está provisto; en la medida de lo razonablemente factible y, si está provisto, el Identificador Uniforme de Recursos (Uniform Resource Identifier) que el Licenciante especifica para ser asociado con la Obra, salvo que tal URI no se refiera a la nota sobre los derechos de autor o a la información sobre el licenciamiento de la Obra; y en el caso de una Obra Derivada, atribuir el crédito identificando el uso de la Obra en la Obra Derivada (v.g., "Traducción Francesa de la Obra del Autor Original," o "Guión Cinematográfico basado en la Obra original del Autor Original"). Tal crédito puede ser implementado de cualquier forma razonable; en el caso, sin embargo, de Obras Derivadas u Obras Colectivas, tal crédito aparecerá, como mínimo, donde aparece el crédito de cualquier otro autor comparable y de una manera, al menos, tan destacada como el crédito de otro autor comparable.</li>
      <li>
        Para evitar toda confusión, el Licenciante aclara que, cuando la obra es una composición musical:
        <ol type="i">
          <li>Regalías por interpretación y ejecución bajo licencias generales. El Licenciante se reserva el derecho exclusivo de autorizar la ejecución pública o la ejecución pública digital de la obra y de recolectar, sea individualmente o a través de una sociedad de gestión colectiva de derechos de autor y derechos conexos (por ejemplo, SAYCO), las regalías por la ejecución pública o por la ejecución pública digital de la obra (por ejemplo Webcast) licenciada bajo licencias generales, si la interpretación o ejecución de la obra está primordialmente orientada por o dirigida a la obtención de una ventaja comercial o una compensación monetaria privada.</li>
          <li>Regalías por Fonogramas. El Licenciante se reserva el derecho exclusivo de recolectar, individualmente o a través de una sociedad de gestión colectiva de derechos de autor y derechos conexos (por ejemplo, los consagrados por la SAYCO), una agencia de derechos musicales o algún agente designado, las regalías por cualquier fonograma que Usted cree a partir de la obra (“versión cover”) y distribuya, en los términos del régimen de derechos de autor, si la creación o distribución de esa versión cover está primordialmente destinada o dirigida a obtener una ventaja comercial o una compensación monetaria privada.</li>
        </ol>
      </li>
      <li>Gestión de Derechos de Autor sobre Interpretaciones y Ejecuciones Digitales (WebCasting). Para evitar toda confusión, el Licenciante aclara que, cuando la obra sea un fonograma, el Licenciante se reserva el derecho exclusivo de autorizar la ejecución pública digital de la obra (por ejemplo, webcast) y de recolectar, individualmente o a través de una sociedad de gestión colectiva de derechos de autor y derechos conexos (por ejemplo, ACINPRO), las regalías por la ejecución pública digital de la obra (por ejemplo, webcast), sujeta a las disposiciones aplicables del régimen de Derecho de Autor, si esta ejecución pública digital está primordialmente dirigida a obtener una ventaja comercial o una compensación monetaria privada.</li>
    </ol>
  </li>
  <br/>
  <li>
    Representaciones, Garantías y Limitaciones de Responsabilidad.
    <p>A MENOS QUE LAS PARTES LO ACORDARAN DE OTRA FORMA POR ESCRITO, EL LICENCIANTE OFRECE LA OBRA (EN EL ESTADO EN EL QUE SE ENCUENTRA) “TAL CUAL”, SIN BRINDAR GARANTÍAS DE CLASE ALGUNA RESPECTO DE LA OBRA, YA SEA EXPRESA, IMPLÍCITA, LEGAL O CUALQUIERA OTRA, INCLUYENDO, SIN LIMITARSE A ELLAS, GARANTÍAS DE TITULARIDAD, COMERCIABILIDAD, ADAPTABILIDAD O ADECUACIÓN A PROPÓSITO DETERMINADO, AUSENCIA DE INFRACCIÓN, DE AUSENCIA DE DEFECTOS LATENTES O DE OTRO TIPO, O LA PRESENCIA O AUSENCIA DE ERRORES, SEAN O NO DESCUBRIBLES (PUEDAN O NO SER ESTOS DESCUBIERTOS). ALGUNAS JURISDICCIONES NO PERMITEN LA EXCLUSIÓN DE GARANTÍAS IMPLÍCITAS, EN CUYO CASO ESTA EXCLUSIÓN PUEDE NO APLICARSE A USTED.</p>
  </li>
  <br/>
  <li>
    Limitación de responsabilidad.
    <p>A MENOS QUE LO EXIJA EXPRESAMENTE LA LEY APLICABLE, EL LICENCIANTE NO SERÁ RESPONSABLE ANTE USTED POR DAÑO ALGUNO, SEA POR RESPONSABILIDAD EXTRACONTRACTUAL, PRECONTRACTUAL O CONTRACTUAL, OBJETIVA O SUBJETIVA, SE TRATE DE DAÑOS MORALES O PATRIMONIALES, DIRECTOS O INDIRECTOS, PREVISTOS O IMPREVISTOS PRODUCIDOS POR EL USO DE ESTA LICENCIA O DE LA OBRA, AUN CUANDO EL LICENCIANTE HAYA SIDO ADVERTIDO DE LA POSIBILIDAD DE DICHOS DAÑOS. ALGUNAS LEYES NO PERMITEN LA EXCLUSIÓN DE CIERTA RESPONSABILIDAD, EN CUYO CASO ESTA EXCLUSIÓN PUEDE NO APLICARSE A USTED.</p>
  </li>
  <br/>
  <li>
    Término.
    <ol type="a">
      <li>Esta Licencia y los derechos otorgados en virtud de ella terminarán automáticamente si Usted infringe alguna condición establecida en ella. Sin embargo, los individuos o entidades que han recibido Obras Derivadas o Colectivas de Usted de conformidad con esta Licencia, no verán terminadas sus licencias, siempre que estos individuos o entidades sigan cumpliendo íntegramente las condiciones de estas licencias. Las Secciones 1, 2, 5, 6, 7, y 8 subsistirán a cualquier terminación de esta Licencia.</li>
      <li>Sujeta a las condiciones y términos anteriores, la licencia otorgada aquí es perpetua (durante el período de vigencia de los derechos de autor de la obra). No obstante lo anterior, el Licenciante se reserva el derecho a publicar y/o estrenar la Obra bajo condiciones de licencia diferentes o a dejar de distribuirla en los términos de esta Licencia en cualquier momento; en el entendido, sin embargo, que esa elección no servirá para revocar esta licencia o que deba ser otorgada , bajo los términos de esta licencia), y esta licencia continuará en pleno vigor y efecto a menos que sea terminada como se expresa atrás. La Licencia revocada continuará siendo plenamente vigente y efectiva si no se le da término en las condiciones indicadas anteriormente.</li>
    </ol>
  </li>
  <br/>
  <li>
    Varios.
    <ol type="a">
      <li>Cada vez que Usted distribuya o ponga a disposición pública la Obra o una Obra Colectiva, el Licenciante ofrecerá al destinatario una licencia en los mismos términos y condiciones que la licencia otorgada a Usted bajo esta Licencia.</li>
      <li>Si alguna disposición de esta Licencia resulta invalidada o no exigible, según la legislación vigente, esto no afectará ni la validez ni la aplicabilidad del resto de condiciones de esta Licencia y, sin acción adicional por parte de los sujetos de este acuerdo, aquélla se entenderá reformada lo mínimo necesario para hacer que dicha disposición sea válida y exigible.</li>
      <li>Ningún término o disposición de esta Licencia se estimará renunciada y ninguna violación de ella será consentida a menos que esa renuncia o consentimiento sea otorgado por escrito y firmado por la parte que renuncie o consienta.</li>
      <li>Esta Licencia refleja el acuerdo pleno entre las partes respecto a la Obra aquí licenciada. No hay arreglos, acuerdos o declaraciones respecto a la Obra que no estén especificados en este documento. El Licenciante no se verá limitado por ninguna disposición adicional que pueda surgir en alguna comunicación emanada de Usted. Esta Licencia no puede ser modificada sin el consentimiento mutuo por escrito del Licenciante y Usted.</li>
    </ol>
  </li>
  <br/>
</ol>


Explicit scheme for a hydrological channel routing: mathematical model and practical application

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