Burgers' equation $u_y + uu_x = 0$ with $u(x,0)=-x$

I couldn't solve this problem, can you help me please?

The Burgers' equation

$$ u_y + uu_x = 0 $$ $ - \infty < x < \infty $ , $ y > 0 $ , $ u(x,0)=f(x) $

My question;

is there any solution $ f(x)= -x $ for all $ y>0 $ , if not, why?

Thank you for your help.

Solution 1:

I rewrite equation to common view

$$\frac{\partial u}{\partial t}+u\frac{\partial u}{\partial x}=0$$ There is a solution with each initial value, but this solution exists only for $t\le t_{r}$, where $t_{r}$ is a point where the phenomenon of "rollover" occurs. This phenomenon occurs if some characteristics of this equations intersect. Here is a picture of characteristics:

It shows that characteristics of this equations intersect on the moment $t=1$

Before the moment $t=1$ the solution is:

$$u(x,t)=f(x-ut),$$ where $$f(x)=-x $$

After the point $t=1$ the solution does not exist. There you should change your equation to conservation law:

$$\frac{\partial u}{\partial t}+\frac{\partial}{\partial x}\left(\frac{u^2}{2}\right)=0$$

and define the order of this law.

Solution 2:

As discussed in the other answers and this post, the method of characteristics yields the classical solution $u = -(x-uy)$, i.e. $$ u(x,y) = \frac{-x}{1-y} \, . $$ Obviously, the denominator vanishes when $y$ reaches unity: the classical solution breaks down as $y\to 1$. This is reflected by the computation of the breaking time $$ y_b = \inf \frac{-1}{(-\text{id})'(x)} = 1 \, . $$ There, all the characteristic curves intersect simultaneously (cf. picture in answer by @cool), i.e. the solution $u$ takes simultaneously all the values from $−∞$ to $+∞$. It literally blows up! There is no weak solution (e.g. of shock-wave type) to start after this blow-up happened.