T-II-1: Difference between revisions
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=Model 0 : Deep water= | =Model 0 : Deep water= | ||
Consider the following equation for the shape of the wave: | Consider the following equation for the shape of the wave: | ||
<math>\partial_t u(x,t) = c \partial_x u(,t) </math> | <math>\partial_t u(x,t) = c \partial_x u(,t) </math> | ||
where <math>u(x,t) </math> is the height of the wave with respect to the unperturbed sea level, and c is constant. We will use the following initial condition | where <math>u(x,t) </math> is the height of the wave with respect to the unperturbed sea level, and c is constant. We will use the following initial condition | ||
=Model 1 : Approaching the sea shore= | =Model 1 : Approaching the sea shore= | ||
Revision as of 12:07, 20 September 2011
Far from the beach , i.e., when the sea is deep, water waves travel on the surface of the sea and their shape is not deformed too much. When the waves approach the beach their shape begins to change and eventually breaks upon touching the seashore.
Here we are interested in studying a simple model that captures the essential features of this physical system. More precisely we will examine the Burgers equation, a non-linear equation introduced as a toy model for turbulence. this equation can be explicitly integrated and, in the limit of zero viscosity, its solution generally displays discontinuities called shocks.
Model 0 : Deep water
Consider the following equation for the shape of the wave:
where is the height of the wave with respect to the unperturbed sea level, and c is constant. We will use the following initial condition
