NUMERICAL MODEL OF WAVE RUN-UP ON A BEACH
The study of wave run-up on a beach has an important role in tsunami mitigation. Run-up is the maximum vertical extent of wave uprush on a beach or structure, measured from the still water level. The inundation area of a tsunami event is directly related to its run-up. When waves arrives at a sho...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/36075 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The study of wave run-up on a beach has an important role in tsunami mitigation.
Run-up is the maximum vertical extent of wave uprush on a beach or structure,
measured from the still water level. The inundation area of a tsunami event is
directly related to its run-up. When waves arrives at a shore, the height of wave
run-up depends on the bottom topography profiles, as well as the characteristics of
the incoming waves. In this dissertation, a comprehensive study regarding wave
run-up is conducted. The discussion is focused on the validation of numerical
scheme simulating wave run-up. The numerical scheme used here is the momentum
conservative scheme for hydrostatics Shallow Water Equations (SWE), first introduced
by Stelling & Duijnmejer (2003). Basically, this scheme is a finite volume
method for ShallowWater Equation that is applied on a staggered grid scheme. This
scheme can accommodate computation that involve wet-dry area, so it is suitable to
simulate waves run -up and run-down phenomena.
Starting with the run-up study of a one dimensional cases, the validation of the
proposed scheme was carried out by comparing the numerical result with Carrier-
Greenspan analytical solution for monochromatic waves. Then, a solitary wave
run-up simulation was performed to compare the numerical results to the experimental
results of Synolakis (1987). The comparison of run-up height shows a good
agreement, especially when the ratio of amplitudo to depth is less than 0:04, which
is a non-breaking wave case. Thus, we conclude that the momentum conservative
scheme can be used to estimate wave run-up reasonably well.
For the run up study of two dimensional cases, the momentum conservative scheme
is implemented to solve the two dimensional SWE. This scheme was validated with
experimental data from literature, those are wave run-up on conical island and
those of Monai Valley. These are two important benchmark tests for numerical
model of tsunami. Comparison results show that the momentum conservative
scheme can simulate wave run-up in two dimensional topography well. Thus, the
proposed momentum conservative scheme is ready to be used to predict run-up wave
using real topography. |
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