Difference between revisions of "TUFLOW Remapping"

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<poem lang="fr" style="float:left;">
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The 2020 release of TUFLOW included new Quadtree mesh and Sub-grid Sampling (SGS) functionality. The SGS feature now supports the
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hydraulic analysis of partially wet cells on the flood fringe. Currently, cells that are partially wet are displayed in model output
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as being fully wet. This page introduces how to use the ASC_to_ASC remap function, and discusses limitations of the method.</poem><br><br>
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[[File: Remap_Advice_LinkedIn.jpg ||450px|right]]
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<br><br><br><br><br><br>
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__TOC__
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= Introduction =
 
= Introduction =
With the release of TUFLOW 2020, the combination of Quadtree mesh and Sub-grid Sampling (SGS) method has offered great flexibility to build a model with a range of mesh sizes. SGS samples the digital elevation model (DEM) at a number of points within a cell and computing the water surface elevation as a function of cell stored volume. With SGS, cells and faces can be considered as "partially wet", and this means the impact of the sub-grid scale geometry can be represented by cells with larger sizes. The example below shows a Quadtree model with 10/20m cell size can conduct water as smoothly as a 2.5/5/10/20m model along a narrow stream.<br>
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With the release of TUFLOW 2020, the combination of Quadtree mesh and Sub-grid Sampling (SGS) method has offered great flexibility for rapidly building flood models of varying resolution and increased topographic detail. Now a wide range of mesh sizes can be applied in a model based on the geographic feature and the area of interest in a project. Especially with the SGS method, cells and faces can be treated as 'partially wet', and the impact of the sub-grid scale geometry may be represented by cells with larger sizes.<br>
 +
The example below shows that a Quadtree model with 10/20m cell size (right) can convey water as smoothly as a 2.5/5/10/20m model along the narrow and meandering gully line.<br>
 
[[File:Fig1 H sgs.png|700px]]<br>
 
[[File:Fig1 H sgs.png|700px]]<br>
'''Figure 1 Water level simulation results with SGS. Lefe: 2.5/5/10/20m Quadtree model. Right: 10/20m Quadtree model.'''<br>
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'''Figure 1 Water level simulation results with SGS. Left: 2.5/5/10/20m Quadtree model. Right: 10/20m Quadtree model.'''<br><br>
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On the other hand, the same model running without SGS applied creates notably different results in the distance of water travelled and the area of inundation on the floodplain due to the poor topographic representation (one elevation per cell centre and cell face).<br>  
 
[[File:Fig2 H nonsgs.png|700px]]<br>
 
[[File:Fig2 H nonsgs.png|700px]]<br>
However, this has also create a need to "remap" the water level in large Quadtree cells to a DEM with much finer resolution. While we are developing high resolution SGS output in the future release, we have also added a new functionality in the [[ASC_to_ASC|ASC_to_ASC]] utility to remap a water level grid to a finer DEM grid. This page introduce how to use the ASC_to_ASC remap function, and also discuss the limitation of the method.
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'''Figure 2 Water level simulation results without SGS. Left: 2.5/5/10/20m Quadtree model. Right: 10/20m Quadtree model.'''<br><br>
 +
These examples show how the mesh size sensitivity are significantly reduced if using TUFLOW's implementation of SGS. Therefore, modellers can confidently use a coarser mesh at areas away from the area of interest without adversely affecting the results. However, this has created a challenge on how to map results in areas of coarser mesh. For example, the images below show that whilst the 10/20m mesh and the 2.5/5/10/20m mesh SGS models produce similar water levels, the depth output is much 'smoother' in the 2.5/5/10/20m model due to the finer computational mesh. <br>
 +
[[File:Fig3 D sgs zoom.png|700px]]<br>
 +
'''Figure 3 Water depth simulation results with SGS. Left: 2.5/5/10/20m Quadtree model. Right: 10/20m Quadtree model.'''<br><br>
  
=Base Case=
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In TUFLOW, the depth output is interpolated from the depths at the nearest cell centre and cell corners surrounding the output grid. Because TUFLOW currently doesn't store the underlying high resolution DEM values other than those needed for the SGS hydraulic computations, the interpolated depth may not perfectly represent the actual depth as illustrated in the figure below. <br>
A simple 1D/2D model has been constructed based on [[Tutorial Module02|Tutorial Module 2]]. SX points have been used to connect a 1D culvert (FC01.2) with the 2D domain. The culvert details are: <br>
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[[File:Fig4 sgs depth interporation.png|500px]]<br>
* Type = R (Rectangular)
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'''Figure 4 TIN interpolation used for water depth map output with SGS.'''<br><br>
* Number of barrels = 5
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This page introduces how to use the [[ASC_to_ASC|ASC_to_ASC]] remap function, and discusses limitations of the method.
* Width per culvert = 2.4m (i.e. the total width of the bank of culverts is 12m)
 
* Height = 1.2m
 
Three 2D cell resolutions have been tested: 5m, 2m and 1m. The figure below shows the 1D/2D linking cells of the culvert.<br>  
 
[[File:1D2D_Model_Stability_001.png|500px]]<br>
 
 
This figure highlights the variation in 2D storage volume associated with the 1D/2D SX connections. The storage associated with a single 1D/2D linking cell for each cell size is:
 
* 5m 2D cell size = 25m<sup>2</sup>/m
 
* 2m 2D cell size = 4m<sup>2</sup>/m
 
* 1m 2D cell size = 1m<sup>2</sup>/m <br>
 
The modelled flow rates in the culvert are presented in the figure below.<br>
 
[[File:1D2D_Model_Stability_002.png|500px]]<br>
 
Two key observations can be made:<br>
 
* The 1D/2D link associated with the 1m 2D cell size is not stable.
 
* The flow rate results through the 1D culvert decrease with cell size. This is an issue. It indicates cell size convergence (i.e. consistent results independent of cell size) was not achieved. This is caused by the 2D storage volume associated with the 1D/2D connection being insufficient compared to the flow area associated with the 1D channel (12m width). As a result, the 2D boundary cell is the model feature limiting flow exchange between the 1D and 2D, rather than the dimension and hydraulics associated with the 1D structure.
 
''Please note that a culvert connection to a single 2D cell is provided here as an example. Connections with a 2D cell width less than the structure face width is not recommended. For example, a 12m wide set of culverts should be connected to at least 12 x 1m cells, 6 x 2m cells and 3 x 5m cells respectively. Examples how this can be done are shown in the following sections.'' <br>
 
  
=1D Timestep=
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=Remapping Water Level to a Finer DEM=
Selection of a 1D timestep that is too large can cause instability. The TUFLOW manual includes some discussion on 1D timestep selection and courant number criterion. Conceptually a 1D timestep should be chosen to ensure a volume of water does not travel a distance longer than the shortest 1D channel within a model. For example, if the flow velocity and celerity is 5m/s and the 1D channel length is 10 metres, the 1D timestep should be less than 2 seconds. To provide some tolerance for faster flows associated with different flood events, a timestep of 1 second may be appropriate.  
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The remap function in [[ASC_to_ASC|ASC_to_ASC]] remaps a TUFLOW water level grid to a high resolution DEM using TIN interpolation. The output is a high resolution water level grid and a high resolution depth grid.<br>
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<tt>asc_to_asc.exe -remap -wl lowres_h.asc -dem DEM_highres.asc</tt>
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where:<br>
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'''"-wl <wl_file>"'''<br>
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sets the coarser resolution water level grid to use for the remap.<br>
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'''"-dem <dem_file>"'''<br>
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sets the finer resolution DEM.<br><br>
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The first image below shows the remapped water depth on top of the 10/20m model water level output, and compares it with the original water depth output in the second image. As can be seen, much smooth water depths along the gully and the flood fringes are produced.<br>
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[[File:Fig5 D sgs remap zoom.png|700px]]<br>
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'''Figure 5 Remapped vs original water depth for 10/20m mesh SGS model.'''<br><br>
  
During real world studies it is good practice to check the 1D timestep sensitivity: <br>
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The next example presents the water level output and the remapped depth output from a flood model using SGS with the buildings included in the DEM. As can be seen in the first image, large portions of the smaller buildings appear submerged by the SGS water level output due to the cells containing these buildings being partially wet. However, the remapped depths (second image) clearly shows the buildings and produces a much higher resolution flood map.<br>
* Select a 1D timestep based on the smallest channel length and the expected flow velocity within your model. <br>
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[[File:Fig6 IR.png|1050px]]<br>
* Trial using a smaller 1D timestep to establish whether the problem is timestep related. <br>
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'''Figure 6 Water level output and remapped water depth in a river flood model.'''<br><br>
If the instability is not timestep related, reducing the timestep should have a negligible change in results. <br>
 
  
A 1s 1D timestep has been used for this testing. It is appropriate for the 1D features being modelled.<br>
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=Remapping of Other Map Output Grids=
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The utility can also remap additional map output grids (e.g. velocity, hazard and others) to the resolution of the DEM file.<br>
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<tt>asc_to_asc.exe -remap -wl lowres_h.asc -dem DEM_highres.asc lowres_v.asc lowres_hazard.asc</tt>
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This command reads in an additional grids 'lowres_v.asc' and 'lowres_hazard.asc' and remaps it to the finer DEM resolution. The figure below compares the original and the remapped hazard outputs from the 10/20m SGS model.<br>
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[[File:fig7 ZAEM1 sgs.png|700px]]<br>
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'''Figure 7 Original vs remapped hazard output for 10/20m mesh SGS model.'''<br><br>
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It is important to note that, for any output types other than depth, this utility does NOT interpolate the result from the coarser grid to the finer grid, but only extends/reduces the output extent to the dry/wet extent. Therefore, the detail of the remapped hazard above remains the same as the original output grid. The interpolation is not carried out for the following reasons:
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* Hazard categories are usually dependent on both water depth and velocity, and it is problematic to interpolate/extrapolate the computed cell averaged velocity to sub-cell scale velocities with varying water depth.
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* Should a higher output resolution be required for outputs utilising velocity, a finer mesh in the area should be used.
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The figure below shows the hazard output from the 2.5/5/10/20m model, and as can be seen the hazard result is much smoother and more accurate along the gully where the finer cell sizes occur. <br>
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[[File:SGS 02-20m ZAEM1.png|400px]]<br>
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'''Figure 8 Original hazard output for 2.5/5/10/20m mesh SGS model.'''<br><br>
  
''Note: The 1D timestep for a HPC 1D/2D linked model is the 'limiting' timestep the 1D solver can use. The 1D solver has been reconfigured to act as an adaptive/varying timestep solution, and the 1D timesteps are set at different multiple of 2D timesteps. <br>''
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''Tip: multiple file names or wildcard are allowed for the extra grid files for remapping.''
  
=1D/2D SX Links Defined Using 1D Nodes (1d_nwk) =
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=Model Mesh Size vs Remap Result=
As of the 2017 release of TUFLOW, nodes within a 1d_nwk file can be used to specify the location of 1D/2D boundary cells and also automatically assign an estimate of the appropriate number of 2D cells for the connection.  
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Beside the quality of velocity based outputs discussed above, the model mesh size can also impact the remapped output at locations with steep slope as discussed below.
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==Road Crests==
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When water flows over a road crest, the remapped water depth may become negative if the output grid size is coarse. The figure below shows the remapped depth over a road crest from models with mesh sizes ranging from 5m to 1.25m. As can be seen, some areas don't have remapped depths despite the water clearly over-topping the road.<br>
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[[File:Fig9 road mesh size.png|1050px]]<br>
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'''Figure 9 Remapped depths over a road crest from models of different mesh resolutions.'''<br><br>
  
For a culvert, this is done by snapping a 1d_nwk point feature to the end of the 1d_nwk line feature and setting the 1d_nwk point attributes:
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As illustrated in the chart below, the DEM has a much finer resolution and the elevation changes rapidly across the road crest, so when interpolating a coarser water level grid to the finer DEM, the interpolated water level may become lower than the local DEM level. In the 2D solver, this type of location is treated as upstream controlled weir flow with the upstream depth used for the calculation. However, the information that the flow is upstream controlled is not known when remapping, hence the appearance of dry patches on the downstream face of the road crest.<br>
* Type =  Node
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[[File:Fig10 road mesh size2.png|500px]]<br>
* UCS = T
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'''Figure 10 Modelled water level line over the road crest.'''<br>
* CONN_1D_2D = SX
 
2D cells will be automatically selected as a 1D/2D SX links. The number of cells that are associated with the 1D/2D SX link will be defined by the nodal storage of the 1D channel. The figure below shows the 1D/2D linking cells in the 5m, 2m and 1m cell size models using this method.<br>
 
  
[[File:1D2D Model Stability 004.png|500px]]<br>
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==Steep Catchments==
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In direct rainfall models, substantial benefits are being realised from applying SGS. The cell faces now correctly capture the lowest elevations along the gullies to preserve the sub-cell scale flow paths, which can significantly improve the hydrologic response for a whole catchment model (see Duncan Kitts' LinkedIn post: https://www.linkedin.com/pulse/sub-grid-sampling-step-change-way-we-create-apply-hydraulic-kitts/). However, if the cell size becomes too large in areas of significant topographic change, only a small portion of the cell may be wet. This makes the depth plotting extremely challenging and the remapped depth may become negative even though water is flowing through the cell. The blue contour below shows the remapped water depth of a 60m mesh direct rainfall model. As can be seen the flow paths are not continuous along some valleys. The remapped water depth from a 20m mesh model is also plotted as the pink contours underneath the 60m result demonstrating that how the flow paths have become clearer as the mesh size is refined even though the results from these two models are very similar when using SGS. <br>
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[[File:Fig11 Innisfall remapped D.png|600px]]<br>
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'''Figure 11 Remapped depth at upstream catchment from different mesh size models.'''
  
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=Conclusion=
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The benefits of using the combination of Quadtree mesh and Sub-grid Sampling method are many. In this page we focused on the ability of representing the sub-grid scale geometry by SGS method, which allows the user to apply a coarser mesh to reduce the total simulation time without adversely affecting the results. However, the interpolation of map output from a coarser mesh can be challenging as illustrated in the examples above. While we are developing a high resolution output feature within TUFLOW to tackle this issue, the new remapping functions of the [[ASC_to_ASC|ASC_to_ASC]] utility can be used to post process water level outputs to high resolution depth results. This produces smooth depth output along main flow paths and flood fringes. However, the SGS method and remapping tool is not a panacea, and a computational mesh with sufficient resolution is still needed to produce reasonable and meaningful simulation results, especially where high resolution velocity based map outputs are needed.<br>
  
The modelled flow rates are shown in the figure below. As can be seen, comparable peak flow rates are obtained regardless of the cell size (i.e. cell size convergence is demonstrated). The stability in the 1m cell size case has been improved markedly, though there are still some oscillations at low flows. <br>
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'''Tip''': Run your model once with small cell size in a test mode (-t) to produce DEM_Z with all topography modifications with the same resolution as the original DEM for use in the TUFLOW Remapping function.<br>
 
 
[[File:1D2D Model Stability 005.png|500px]]<br>
 
 
 
=SX Boundary Lines (2d_bc)=
 
2d_bc SX line features are often used to connect 1D structure to the 2D domain if the structure width is greater than one 2D cell wide (e.g. [[Tute_M02_QGIS_1d2d_Link#2d_bc_Link_as_Line_Object|Tutorial Module02]]). This configuration not only increases the number of 1D/2D linking cells, it also has the added benefit of defining the 1D/2D boundary cells at the approximate location of the inlet/outlet of the 1D culvert. An additional benefit of this approach is that the "width" of the linking cells remains similar in length and location irrespective of 2D cell size.  <br>
 
 
 
The 1D/2D linking cells in the 5m, 2m and 1m cell size models are shown in the the figure below.<br>
 
 
 
[[File:1D2D_Model_Stability_006.png|500px]]<br>
 
 
 
The result below indicates cell size convergence is achieved, the flow oscillations have also been reduced (compared to the model using the 1d_nwk Node 1D/2D link method).<br>
 
  
[[File:1D2D Model Stability 007.png|500px]]<br>
+
Finally, should you have some interesting results using SGS, Quadtree or the remapping feature that you would like to share with the TUFLOW community, please feel free to email [mailto:support@tuflow.com support@tuflow.com].
 
 
=SX Storage Factor (2d_bc)=
 
A new "SX Storage Factor" feature was been added to TUFLOW in the 2017 release. As the name suggests, this feature adds additional storage to the 1D/2D linking (SX) cells. The storage factor is specified by adjusting the 2d_bc "a" attribute value. "a" is treated as a storage multiplier. For example, specifying an "a" value of 2.0 doubles the storage associated with the 1D/2D boundary. Note that an "a" value of 0.0 assumes a multiplier of 1.0.<br>
 
 
 
The modelling result with an "a" value of 2.0 are presented in the figure below. The flow rate is now very smooth and the difference in peak flow rates is negligible.<br>
 
[[File:1D2D Model Stability 008.png|500px]]<br>
 
 
 
Testing has shown small increases in storage usually has immeasurable effect on results, however, sensitivity testing is recommended to confirm this assumption in different models. For example, if specifying an "a" value of 2 stabilises the link, sensitivity test by increasing "a" further to 3. If there is no appreciable or unacceptable change in results, increasing the storage by a factor within these bounds can be considered to have negligible effect on results.
 
 
 
=SX Boundary Regions/Polygons (2d_bc)=
 
SX boundary regions/polygons are another feature that was added for the 2017 TUFLOW release. Polygons can now be used as a 2d_bc SX input. All cells with a cell centre within the polygon are set as SX cells. A CN line is required to connect the 1D feature to the SX polygon, snapped to any vertex on the perimeter of the polygon. An example of this configuration and the 1D/2D linking cells produced in the 5m, 2m and 1m cell size models are shown in the figure below.<br>
 
 
 
[[File:1D2D_Model_Stability_009.png|500px]]<br>
 
 
 
The modelling results are presented in the figure below. Again, cell size convergence is demonstrated and the oscillations at low flow is removed.<br>
 
 
 
[[File:1D2D Model Stability 010.png|500px]]<br>
 
 
 
=Conclusion=
 
When the spatial resolution of a model is increased (i.e. cell size reduced) review of result sensitivity at 1D/2D SX link locations is recommended. This can be done quickly and easily by plotting 1D results and checking for unwanted oscillations. This page demonstrated some useful methods for stabilising 1D/2D boundary (SX) links, in particular where the 1D structure is large in comparison to the 2D cell size. Available options that were introduced included reviewing the 1D timestep, using 1D nodes to define the 1D/2D boundary link, SX boundary lines, SX storage factors and SX boundary polygons.
 

Latest revision as of 12:22, 8 August 2024

The 2020 release of TUFLOW included new Quadtree mesh and Sub-grid Sampling (SGS) functionality. The SGS feature now supports the
hydraulic analysis of partially wet cells on the flood fringe. Currently, cells that are partially wet are displayed in model output
as being fully wet. This page introduces how to use the ASC_to_ASC remap function, and discusses limitations of the method.



Remap Advice LinkedIn.jpg







Introduction

With the release of TUFLOW 2020, the combination of Quadtree mesh and Sub-grid Sampling (SGS) method has offered great flexibility for rapidly building flood models of varying resolution and increased topographic detail. Now a wide range of mesh sizes can be applied in a model based on the geographic feature and the area of interest in a project. Especially with the SGS method, cells and faces can be treated as 'partially wet', and the impact of the sub-grid scale geometry may be represented by cells with larger sizes.
The example below shows that a Quadtree model with 10/20m cell size (right) can convey water as smoothly as a 2.5/5/10/20m model along the narrow and meandering gully line.
Fig1 H sgs.png
Figure 1 Water level simulation results with SGS. Left: 2.5/5/10/20m Quadtree model. Right: 10/20m Quadtree model.

On the other hand, the same model running without SGS applied creates notably different results in the distance of water travelled and the area of inundation on the floodplain due to the poor topographic representation (one elevation per cell centre and cell face).
Fig2 H nonsgs.png
Figure 2 Water level simulation results without SGS. Left: 2.5/5/10/20m Quadtree model. Right: 10/20m Quadtree model.

These examples show how the mesh size sensitivity are significantly reduced if using TUFLOW's implementation of SGS. Therefore, modellers can confidently use a coarser mesh at areas away from the area of interest without adversely affecting the results. However, this has created a challenge on how to map results in areas of coarser mesh. For example, the images below show that whilst the 10/20m mesh and the 2.5/5/10/20m mesh SGS models produce similar water levels, the depth output is much 'smoother' in the 2.5/5/10/20m model due to the finer computational mesh.
Fig3 D sgs zoom.png
Figure 3 Water depth simulation results with SGS. Left: 2.5/5/10/20m Quadtree model. Right: 10/20m Quadtree model.

In TUFLOW, the depth output is interpolated from the depths at the nearest cell centre and cell corners surrounding the output grid. Because TUFLOW currently doesn't store the underlying high resolution DEM values other than those needed for the SGS hydraulic computations, the interpolated depth may not perfectly represent the actual depth as illustrated in the figure below.
Fig4 sgs depth interporation.png
Figure 4 TIN interpolation used for water depth map output with SGS.

This page introduces how to use the ASC_to_ASC remap function, and discusses limitations of the method.

Remapping Water Level to a Finer DEM

The remap function in ASC_to_ASC remaps a TUFLOW water level grid to a high resolution DEM using TIN interpolation. The output is a high resolution water level grid and a high resolution depth grid.

asc_to_asc.exe -remap -wl lowres_h.asc -dem DEM_highres.asc

where:
"-wl <wl_file>"
sets the coarser resolution water level grid to use for the remap.
"-dem <dem_file>"
sets the finer resolution DEM.

The first image below shows the remapped water depth on top of the 10/20m model water level output, and compares it with the original water depth output in the second image. As can be seen, much smooth water depths along the gully and the flood fringes are produced.
Fig5 D sgs remap zoom.png
Figure 5 Remapped vs original water depth for 10/20m mesh SGS model.

The next example presents the water level output and the remapped depth output from a flood model using SGS with the buildings included in the DEM. As can be seen in the first image, large portions of the smaller buildings appear submerged by the SGS water level output due to the cells containing these buildings being partially wet. However, the remapped depths (second image) clearly shows the buildings and produces a much higher resolution flood map.
Fig6 IR.png
Figure 6 Water level output and remapped water depth in a river flood model.

Remapping of Other Map Output Grids

The utility can also remap additional map output grids (e.g. velocity, hazard and others) to the resolution of the DEM file.

asc_to_asc.exe -remap -wl lowres_h.asc -dem DEM_highres.asc lowres_v.asc lowres_hazard.asc

This command reads in an additional grids 'lowres_v.asc' and 'lowres_hazard.asc' and remaps it to the finer DEM resolution. The figure below compares the original and the remapped hazard outputs from the 10/20m SGS model.
Fig7 ZAEM1 sgs.png
Figure 7 Original vs remapped hazard output for 10/20m mesh SGS model.

It is important to note that, for any output types other than depth, this utility does NOT interpolate the result from the coarser grid to the finer grid, but only extends/reduces the output extent to the dry/wet extent. Therefore, the detail of the remapped hazard above remains the same as the original output grid. The interpolation is not carried out for the following reasons:

  • Hazard categories are usually dependent on both water depth and velocity, and it is problematic to interpolate/extrapolate the computed cell averaged velocity to sub-cell scale velocities with varying water depth.
  • Should a higher output resolution be required for outputs utilising velocity, a finer mesh in the area should be used.

The figure below shows the hazard output from the 2.5/5/10/20m model, and as can be seen the hazard result is much smoother and more accurate along the gully where the finer cell sizes occur.
SGS 02-20m ZAEM1.png
Figure 8 Original hazard output for 2.5/5/10/20m mesh SGS model.

Tip: multiple file names or wildcard are allowed for the extra grid files for remapping.

Model Mesh Size vs Remap Result

Beside the quality of velocity based outputs discussed above, the model mesh size can also impact the remapped output at locations with steep slope as discussed below.

Road Crests

When water flows over a road crest, the remapped water depth may become negative if the output grid size is coarse. The figure below shows the remapped depth over a road crest from models with mesh sizes ranging from 5m to 1.25m. As can be seen, some areas don't have remapped depths despite the water clearly over-topping the road.
Fig9 road mesh size.png
Figure 9 Remapped depths over a road crest from models of different mesh resolutions.

As illustrated in the chart below, the DEM has a much finer resolution and the elevation changes rapidly across the road crest, so when interpolating a coarser water level grid to the finer DEM, the interpolated water level may become lower than the local DEM level. In the 2D solver, this type of location is treated as upstream controlled weir flow with the upstream depth used for the calculation. However, the information that the flow is upstream controlled is not known when remapping, hence the appearance of dry patches on the downstream face of the road crest.
Fig10 road mesh size2.png
Figure 10 Modelled water level line over the road crest.

Steep Catchments

In direct rainfall models, substantial benefits are being realised from applying SGS. The cell faces now correctly capture the lowest elevations along the gullies to preserve the sub-cell scale flow paths, which can significantly improve the hydrologic response for a whole catchment model (see Duncan Kitts' LinkedIn post: https://www.linkedin.com/pulse/sub-grid-sampling-step-change-way-we-create-apply-hydraulic-kitts/). However, if the cell size becomes too large in areas of significant topographic change, only a small portion of the cell may be wet. This makes the depth plotting extremely challenging and the remapped depth may become negative even though water is flowing through the cell. The blue contour below shows the remapped water depth of a 60m mesh direct rainfall model. As can be seen the flow paths are not continuous along some valleys. The remapped water depth from a 20m mesh model is also plotted as the pink contours underneath the 60m result demonstrating that how the flow paths have become clearer as the mesh size is refined even though the results from these two models are very similar when using SGS.
Fig11 Innisfall remapped D.png
Figure 11 Remapped depth at upstream catchment from different mesh size models.

Conclusion

The benefits of using the combination of Quadtree mesh and Sub-grid Sampling method are many. In this page we focused on the ability of representing the sub-grid scale geometry by SGS method, which allows the user to apply a coarser mesh to reduce the total simulation time without adversely affecting the results. However, the interpolation of map output from a coarser mesh can be challenging as illustrated in the examples above. While we are developing a high resolution output feature within TUFLOW to tackle this issue, the new remapping functions of the ASC_to_ASC utility can be used to post process water level outputs to high resolution depth results. This produces smooth depth output along main flow paths and flood fringes. However, the SGS method and remapping tool is not a panacea, and a computational mesh with sufficient resolution is still needed to produce reasonable and meaningful simulation results, especially where high resolution velocity based map outputs are needed.

Tip: Run your model once with small cell size in a test mode (-t) to produce DEM_Z with all topography modifications with the same resolution as the original DEM for use in the TUFLOW Remapping function.

Finally, should you have some interesting results using SGS, Quadtree or the remapping feature that you would like to share with the TUFLOW community, please feel free to email support@tuflow.com.