commit 7823943a8c21edb860ccd41515649a259b82e37d parent cd94b969b81e7bbf1ee5a7a22ad265042cd64d28 Author: Ivan Gankevich <igankevich@ya.ru> Date: Mon, 30 Oct 2017 15:00:53 +0300 Conclusion. Diffstat:
| arma-thesis.org | | | 12 | ++++++++---- |
1 file changed, 8 insertions(+), 4 deletions(-)
diff --git a/arma-thesis.org b/arma-thesis.org @@ -3682,11 +3682,15 @@ beyond linear wave theory the following main results were achieved. to the ones of a real sea surface. - New method was applied to compute velocity potentials under generated surface. The resulting velocity potential field was verified by comparing it to the one - given by formulae from linear wave theory for small-amplitude waves. For large - amplitude waves the new method gives a reasonably different field. The method - is computationally efficient because all the integrals in its formula are - written as Fourier transforms, for which there are high-performance + given by formulae from linear wave theory for small-amplitude waves. For + large-amplitude waves the new method gives a reasonably different field. The + method is computationally efficient because all the integrals in its formula + are written as Fourier transforms, for which there are high-performance implementations. +- The model and the method were implemented for both SMP and MPP systems, and + showed near linear scalability for different number of cores in several + benchmarks. AR model is more computationally efficient on CPU than on GPU, and + outperforms linear LH model. **** Further research directions. One of the topic of future research is studying generation of wave of arbitrary