| 1 | To initiate the modelling, the computational mesh is constructed to |
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| 2 | cover the available data. The resolution is chosen to balance |
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| 3 | computational time and desired resolution in areas of interest, |
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| 4 | particularly in the interface between the on and offshore. he |
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| 5 | following figure illustrates the data extent for the |
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| 6 | scenario and where further mesh refinement has been made. The choice |
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| 7 | of the refinement is based around the important inter-tidal zones and |
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| 8 | other important features such as islands and rivers. |
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| 9 | The resultant computational mesh is then seen in \ref{fig:mesh_onslow} |
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| 10 | which has an area of around ? km$^2$. |
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| 11 | In contrast to the Onslow study, the most northern |
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| 12 | boundary of the study area is placed approximately around the 50m contour |
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| 13 | line. The driver for this change was the computational time taken to |
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| 14 | develop the mesh and associate the points to that mesh. By comparison, the |
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| 15 | 100m contour for the Onslow study is approximately 100km from the coast, |
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| 16 | with that distance approximately 200km for Pt Hedland. The increased |
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| 17 | study area (from 6300 km$^2 for Onslow to 24400 km$^2 for Pt Hedland) |
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| 18 | then increases the number of triangles, thereby increasing |
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| 19 | the computational time. It would be possible to increase the cell resolution |
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| 20 | to minimise the number of triangles, however, the cell resolution would have |
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| 21 | to be raised to an unacceptable level. |
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| 22 | However, initial comparisons between the deep water model MOST (Method of |
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| 23 | Splitting Tsunami) and ANUGA show that they are reasonably well matched |
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| 24 | to the 50m contour line. More detailed investigations are necessary to |
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| 25 | confirm this position as the point may be dependent on the local bathymetry. |
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| 26 | |
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| 27 | \begin{figure}[hbt] |
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| 28 | |
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| 29 | \centerline{ \includegraphics[width=100mm, height=75mm] |
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| 30 | {../report_figures/pt_hedland_data_poly.png}} |
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| 31 | |
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| 32 | \caption{Study area for Pt Hedland scenario} |
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| 33 | \label{fig:pthedland_area} |
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| 34 | \end{figure} |
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| 35 | |
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| 36 | |
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| 37 | \begin{figure}[hbt] |
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| 38 | |
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| 39 | %\centerline{ \includegraphics[width=100mm, height=75mm]{}} |
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| 40 | |
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| 41 | \caption{Computational mesh for Pt Hedland study area} |
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| 42 | \label{fig:meshpthedland} |
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| 43 | \end{figure} |
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| 44 | |
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| 45 | For the simulations, we have chosen a resolution of 500 m$^2$ for the |
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| 46 | region surrounding the Pt Hedland town centre. The resolution is increased |
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| 47 | to 2500 m$^2$ for the region surrounding the coast and further increased |
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| 48 | to 100000 m$^2$ for the region reaching approximately the 50m contour line. |
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| 49 | With these resolutions in place, the study area consists of ? triangles. |
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| 50 | The associated accuracy |
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| 51 | for these resolutions is approximatly 22m, 50m, and 315m for the increasing |
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| 52 | resolutions. This means |
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| 53 | that we can only be confident in the calculated inundation to approximately |
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| 54 | 22m accuracy within the Pt Hedland town centre. |
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| 55 | This is because ANUGA calculates whether each cell in the triangular |
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| 56 | mesh is wet or dry. It is important |
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| 57 | to refine the mesh to be commensurate with the underlying data especially in |
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| 58 | those regions where complex behaviour will occur, such as the inter-tidal |
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| 59 | zone and estuaries. |
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| 60 | |
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| 61 | Whilst friction has been incorporated into the model, we have not |
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| 62 | implemented it here. |
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| 63 | We have an outstanding issue with regard how friction is |
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| 64 | modelled which is not yet resolved. |
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