×
Well done. You've clicked the tower. This would actually achieve something if you had logged in first. Use the key for that. The name takes you home. This is where all the applicables sit. And you can't apply any changes to my site unless you are logged in.

Our policy is best summarized as "we don't care about _you_, we care about _them_", no emails, so no forgetting your password. You have no rights. It's like you don't even exist. If you publish material, I reserve the right to remove it, or use it myself.

Don't impersonate. Don't name someone involuntarily. You can lose everything if you cross the line, and no, I won't cancel your automatic payments first, so you'll have to do it the hard way. See how serious this sounds? That's how serious you're meant to take these.

×
Register


Required. 150 characters or fewer. Letters, digits and @/./+/-/_ only.
  • Your password can’t be too similar to your other personal information.
  • Your password must contain at least 8 characters.
  • Your password can’t be a commonly used password.
  • Your password can’t be entirely numeric.
Enter the same password as before, for verification.
Login

Grow A Dic
Define A Word
Make Space
Set Task
Mark Post
Apply Votestyle
Create Votes
(From: saved spaces)
Exclude Votes
Apply Dic
Exclude Dic

A multiscale model for weakly nonlinear shallow water waves over periodic bathymetry. (arXiv:2311.02603v1 [math.AP])

Click here to flash read.

We study the behavior of shallow water waves over periodically-varying
bathymetry, based on the first-order hyperbolic Saint-Venant equations.
Although solutions of this system are known to generally exhibit wave breaking,
numerical experiments suggest a different behavior in the presence of periodic
bathymetry. Starting from the first-order variable-coefficient hyperbolic
system, we apply a multiple-scale perturbation approach in order to derive a
system of constant-coefficient high-order partial differential equations whose
solution approximates that of the original system. The high-order system turns
out to be dispersive and exhibits solitary-wave formation, in close agreement
with direct numerical simulations of the original system. We show that the
constant-coefficient homogenized system can be used to study the properties of
solitary waves and to conduct efficient numerical simulations.

Click here to read this post out
ID: 530308; Unique Viewers: 0
Unique Voters: 0
Total Votes: 0
Votes:
Latest Change: Nov. 7, 2023, 7:36 a.m. Changes:
/u/anonymous
Dictionaries:
Words:
Spaces:
Views: 11
CC:
No creative common's license
Comments: