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Timestamp:
Jun 16, 2006, 4:30:48 PM (18 years ago)
Author:
sexton
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more changes

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production/onslow_2006/report
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  • production/onslow_2006/report/computational_setup.tex

    r3171 r3173  
    3131commensurate with the underlying data. Referring to the onshore data
    3232discussed
    33 in Section \ref{sec:data}, we choose a cell area 500 m$^2$ per triangle
     33in Section \ref{sec:data}, we choose a cell area of 500 m$^2$ per triangle
    3434for the region surrounding the Onslow town centre.
    3535It is worth noting here that the cell
     
    494950km. For this scenario, the wavelength of the tsunami wave is
    5050approximately 20km near the boundary indicating that a minimum
    51 grid resolution of 20000m.
     51grid resolution of 20000m would be required.
    5252With this information, the remaining cell areas are
    53532500 m$^2$ for the region surrounding the coast,
     
    5555the remainder of the study area having a cell area of 100000 m$^2$.
    5656These choice of cell areas is more than adequate to propagate the tsunami wave
    57 in the deepest sections of the study area\footnote{
     57in the deepest sections of the study area.\footnote{
    5858With a wavelength of 20km, the minimum (square) grid resolution would
    5959be 2000m which results in a square cell area of 4000000 m$^2$. A minimum
     
    7878\end{figure}
    7979
    80 To complete the model setup, we describe the form of the
     80To complete the model setup, we illustrate the
    8181tsunami wave from the earthquake source described
    82 in Section \ref{sec:tsunamiscenario}. The Method of Splitting Tsunami (MOST)
    83 was used to initiate the event and propagate the wave in deep water. The
    84 waves amplitude and velocity is then determined at the
    85 boundary of the study area (see Figure \ref{fig:onslow_area}) whereupon
    86 ANUGA continues to propagate the tsunami wave in shallow water and onshore.
     82in Section \ref{sec:tsunamiscenario} which is used as the boundary condition,
     83as described in Section \ref{sec:methodology}.
     84MOST was used to initiate the event and propagate the wave in deep water.
     85ANUGA uses MOST's output in form of the waves amplitude and velocity at
     86the boundary (the 100m contour line as shown in Figure \ref{fig:onslow_area})
     87and continues to propagate the wave in shallow water and onshore.
    8788To illustrate the form of the tsunami wave, we select a number
    88 of point locations outside, on and within the boundary (shown in
    89 Figure \ref{fig:boundarypoints}) and show the moving
    90 wave amplitude and speed.
     89of point locations surrouding the boundary (shown in
     90Figure \ref{fig:boundarypoints}) and show the waves movement in terms
     91of water level and speed.
    9192
    9293\input{MOST_input_onslow}
  • production/onslow_2006/report/damage.tex

    r3172 r3173  
    2929which indicates it is inundated prior to the tsunami wave arriving.
    3030At 0m AHD, over 3m of water will inundate parts of the community (Figure
    31 \ref{fig:gaugeBindiBindiCommunity}) which indicates significant loss.
     31\ref{fig:gaugeBindiBindiCommunity}) indicating 100\% damage of contents.
    3232
    3333Once the maximum inundation is calculated for each building, the resultant
     
    3636coastline, \cite{ken:damage}. The damage to the residential
    3737structures in the Onslow community
    38 is summarised in Table \ref{table:damageoutput}.
     38is summarised in Table \ref{table:damageoutput}. The percentage
     39of repair cost to structural value shown is based on the total structural value
     40of \$60,187,955. Likewise, the percentage of contents loss shown is
     41based on the total contents value of \$85,410,060 for
     42the Onslow region. The injuries sustained in each scenario is summarised
     43in Table \ref{talbe:injuries}. Around 21 \%
     44of the population are affected in the 1.5m AHD scenario with around 10 \%
     45affected in the 0m AHD scenario.
     46
    3947
    4048\begin{table}[h]
     
    4452\begin{center}
    4553\begin{tabular}{|l|l|l|l|l|l|l|}\hline
    46 & Houses  & Houses  & Structural & Structural & Contents & Contents  \\
     54& Houses  & Houses  & Structural & Repair Cost & Contents & Contents Loss  \\
    4755& Inundation & Collapsed & Repair Cost
    48 & Total Value & Losses & Total Value \\ \hline
    49 1.5m AHD & 90 & 14 & & & &  \\ \hline
    50 0m AHD & 54 & 1 & & & & \\ \hline
    51 -1.5m AHD & 0 & 0 & & & &  \\ \hline
     56& \% of Total Value & Losses & \% of Total Value \\ \hline
     571.5m AHD & 90 & 14 & \$10,951,887 & 18.2 \% & \$24,020,309 & 28.12 \%\\ \hline
     580m AHD & 54 & 1 & \$5,317,783 &  8.8 \% & \$11,592,602 & 13.6 \% \\ \hline
     59-1.5m AHD & 0 & 0 & 0& 0& 0&  0\\ \hline
    5260\end{tabular}
    5361\end{center}
     
    6068\begin{tabular}{|l|l|l|l|l|}\hline
    6169 & Minor Injuries & Moderate & Serious & Fatal \\ \hline
    62 1.5m AHD & 59 & 17 & 8 & 23 \\ \hline
     701.5m AHD & 59 & 17 & 8 & 83 \\ \hline
    63710m AHD & 43 & 11 & 6 & 20 \\ \hline
    6472-1.5m AHD & 0 & 0 & 0 & \\ \hline
  • production/onslow_2006/report/onslow_2006_report.tex

    r3160 r3173  
    117117     \input{summary}
    118118     
    119    \section{References}
     119   %\section{References}
    120120    \input{references}
    121121   
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