Flood Modeller

Flood Modeller
Developer(s)	Jacobs Engineering Group
Stable release	7.0
Written in	C#, Fortran, Delphi, C++
Operating system	Microsoft Windows
Type	Hydraulic simulation, Geographic information system
Website	https://www.floodmodeller.com/

Flood Modeller is a computer program developed by Jacobs that assesses flood risk by simulating the flow of water through river channels, urban drainage networks and across floodplains using a range of one- and two-dimensional hydraulic solvers. The software incorporates a user interface for building, running and viewing the results of models, including a GIS map interface.

The software has been independently benchmarked^[1] by the Environment Agency and is used extensively^[2] to undertake modelling of flood risk,^[3] develop flood risk management schemes and provide flood forecasting services.^[4]

Development History edit

Initially developed by Halcrow Group and then CH2M Hill, Flood Modeller is now developed by Jacobs Solutions. Flood Modeller was previously known as "ISIS" (after the local name for the Upper Thames).

Solvers edit

1D solvers edit

Flood Modeller includes steady-state and unsteady 1D river solvers for modelling open-channels.

It also provides a 1D urban solver for modelling urban drainage systems.

2D solvers edit

Flood Modeller includes three different 2D solvers:

The ADI solver is based on the DIVAST numerical engine first developed in the 1980s, and is designed to simulate fluvial, overland, estuarine and coastal situations where flow does not rapidly change.^[5]
The TVD solver is designed to represent rapid changes in the water surface profile, but results in longer run-times.
The FAST solver uses simplified hydraulics to perform rapid assessments of flooding.^[6]^[7]

References edit

^ "Benchmarking the latest generation of 2D hydraulic flood modelling packages". GOV.UK. Retrieved 21 June 2021.
^ "About Us". Flood Modeller. Retrieved 21 June 2021.
^ "Environment Agency Current Magazine issue 22". Environment Agency. Retrieved 9 January 2024.
^ "Real-time flood impacts mapping". GOV.UK. Retrieved 5 January 2024.
^ Lin, B.; Wicks, J. M.; Falconer, R. A.; Adams, K. (2006). "Integrating 1D and 2D hydrodynamic models for flood simulation". Proceedings of the ICE - Water Management. 159: 19–25. doi:10.1680/wama.2006.159.1.19.
^ Banks, J. C.; Camp, J. V.; Abkowitz, M. D. (2013). "Adaptation planning for floods: a review of available tools". Natural Hazards. 70 (2): 1327–1337. doi:10.1007/s11069-013-0876-7. S2CID 129095526.
^ Jacobs (2015). "2D FAST solver". Flood Modeller. Jacobs. Retrieved 13 February 2015.

External links edit

Flood Modeller website

[1] "Benchmarking the latest generation of 2D hydraulic flood modelling packages". GOV.UK. Retrieved 21 June 2021.

[2] "About Us". Flood Modeller. Retrieved 21 June 2021.

[3] "Environment Agency Current Magazine issue 22". Environment Agency. Retrieved 9 January 2024.

[4] "Real-time flood impacts mapping". GOV.UK. Retrieved 5 January 2024.

[5] Lin, B.; Wicks, J. M.; Falconer, R. A.; Adams, K. (2006). "Integrating 1D and 2D hydrodynamic models for flood simulation". Proceedings of the ICE - Water Management. 159: 19–25. doi:10.1680/wama.2006.159.1.19.

[6] Banks, J. C.; Camp, J. V.; Abkowitz, M. D. (2013). "Adaptation planning for floods: a review of available tools". Natural Hazards. 70 (2): 1327–1337. doi:10.1007/s11069-013-0876-7. S2CID 129095526.

[7] Jacobs (2015). "2D FAST solver". Flood Modeller. Jacobs. Retrieved 13 February 2015.

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