Burgers' equation

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Burgers' equation or Bateman–Burgers equation is a fundamental partial differential equation and convection–diffusion equation^[1] occurring in various areas of applied mathematics, such as fluid mechanics,^[2] nonlinear acoustics,^[3] gas dynamics, and traffic flow.^[4] The equation was first introduced by Harry Bateman in 1915^[5][6] and later studied by Johannes Martinus Burgers in 1948.^[7] For a given field ${\displaystyle u(x,t)}$ and diffusion coefficient (or kinematic viscosity, as in the original fluid mechanical context) ${\displaystyle \nu }$, the general form of Burgers' equation (also known as viscous Burgers' equation) in one space dimension is the dissipative system:

${\displaystyle \frac{\partial u}{\partial t}+u\frac{\partial u}{\partial x}=\nu \frac{{\partial }^{2}u}{\partial x^2}.}$

The term ${\displaystyle u\partial u/\partial x}$ can also rewritten as ${\displaystyle \partial (u^2/2)/\partial x}$. When the diffusion term is absent (i.e. ${\displaystyle \nu =0}$), Burgers' equation becomes the inviscid Burgers' equation:

${\displaystyle \frac{\partial u}{\partial t}+u\frac{\partial u}{\partial x}=0,}$

which is a prototype for conservation equations that can develop discontinuities (shock waves).

The reason for the formation of sharp gradients for small values of ${\displaystyle \nu }$ becomes intuitively clear when one examines the left-hand side of the equation. The term ${\displaystyle \partial /\partial t+u\partial /\partial x}$ is evidently a wave operator describing a wave propagating in the positive ${\displaystyle x}$-direction with a speed ${\displaystyle u}$. Since the wave speed is ${\displaystyle u}$, regions exhibiting large values of ${\displaystyle u}$ will be propagated rightwards quicker than regions exhibiting smaller values of ${\displaystyle u}$; in other words, if ${\displaystyle u}$ is decreasing in the ${\displaystyle x}$-direction, initially, then larger ${\displaystyle u}$'s that lie in the backside will catch up with smaller ${\displaystyle u}$'s on the front side. The role of the right-side diffusive term is essentially to stop the gradient becoming infinite.

The inviscid Burgers' equation is a conservation equation, more generally a first order quasilinear hyperbolic equation. The solution to the equation and along with the initial condition

${\displaystyle \frac{\partial u}{\partial t}+u\frac{\partial u}{\partial x}=0,u(x,0)=f(x)}$

can be constructed by the method of characteristics. Let ${\displaystyle t}$ be the parameter characterising any given characteristics in the ${\displaystyle x}$-${\displaystyle t}$ plane, then the characteristic equations are given by

${\displaystyle \frac{dx}{dt}=u,\frac{du}{dt}=0.}$

Integration of the second equation tells us that ${\displaystyle u}$ is constant along the characteristic and integration of the first equation shows that the characteristics are straight lines, i.e.,

${\displaystyle u=c,x=ut+\xi }$

where ${\displaystyle \xi }$ is the point (or parameter) on the x-axis (t = 0) of the x-t plane from which the characteristic curve is drawn. Since ${\displaystyle u}$ at ${\displaystyle x}$-axis is known from the initial condition and the fact that ${\displaystyle u}$ is unchanged as we move along the characteristic emanating from each point ${\displaystyle x=\xi }$, we write ${\displaystyle u=c=f(\xi )}$ on each characteristic. Therefore, the family of trajectories of characteristics parametrized by ${\displaystyle \xi }$ is

${\displaystyle x=f(\xi )t+\xi .}$

Thus, the solution is given by

${\displaystyle u(x,t)=f(\xi )=f(x-ut),\xi =x-f(\xi )t.}$

This is an implicit relation that determines the solution of the inviscid Burgers' equation provided characteristics don't intersect. If the characteristics do intersect, then a classical solution to the PDE does not exist and leads to the formation of a shock wave. Whether characteristics can intersect or not depends on the initial condition. In fact, the breaking time before a shock wave can be formed is given by^[8][9]

${\displaystyle t_b=\frac{-1}{\underset{x}{\inf }(f^{\prime }(x))}.}$

The implicit solution described above containing an arbitrary function ${\displaystyle f}$ is called the general integral. However, the inviscid Burgers' equation, being a first-order partial differential equation, also has a complete integral which contains two arbitrary constants (for the two independent variables).^[10]Template:Better source needed Subrahmanyan Chandrasekhar provided the complete integral in 1943,^[11] which is given by

${\displaystyle u(x,t)=\frac{ax+b}{at+1}.}$

where ${\displaystyle a}$ and ${\displaystyle b}$ are arbitrary constants. The complete integral satisfies a linear initial condition, i.e., ${\displaystyle f(x)=ax+b}$. One can also construct the general integral using the above complete integral.

The viscous Burgers' equation can be converted to a linear equation by the Cole–Hopf transformation,^[12][13][14]

${\displaystyle u(x,t)=-2\nu \frac{\partial }{\partial x}\ln \phi (x,t),}$

which turns it into the equation

${\displaystyle 2\nu \frac{\partial }{\partial x}\left[\frac{1}{\phi }(\frac{\partial \phi }{\partial t}-\nu \frac{{\partial }^2\phi }{\partial x^2})\right]=0,}$

which can be integrated with respect to ${\displaystyle x}$ to obtain

${\displaystyle \frac{\partial \phi }{\partial t}-\nu \frac{{\partial }^2\phi }{\partial x^2}=\phi \frac{df(t)}{dt},}$

where ${\displaystyle df/dt}$ is an arbitrary function of time. Introducing the transformation ${\displaystyle \phi \to \phi e^f}$ (which does not affect the function ${\displaystyle u(x,t)}$), the required equation reduces to that of the heat equation^[15]

${\displaystyle \frac{\partial \phi }{\partial t}=\nu \frac{{\partial }^2\phi }{\partial x^2}.}$

The diffusion equation can be solved. That is, if ${\displaystyle \phi (x,0)={\phi }_0(x)}$, then

${\displaystyle \phi (x,t)=\frac{1}{\sqrt{4\pi \nu t}}{\displaystyle \underset{-\mathrm{\infty }}{\overset{\mathrm{\infty }}{\int }}}{\phi }_0(x^{\prime })\exp [-\frac{(x-x^{\prime }{)}^2}{4\nu t}]d{x}^{\prime }.}$

The initial function ${\displaystyle {\phi }_0(x)}$ is related to the initial function ${\displaystyle u(x,0)=f(x)}$ by

${\displaystyle \ln {\phi }_0(x)=-\frac{1}{2\nu }{\displaystyle \underset{0}{\overset{x}{\int }}}f(x^{\prime })d{x}^{\prime },}$

where the lower limit is chosen arbitrarily. Inverting the Cole–Hopf transformation, we have

${\displaystyle u(x,t)=-2\nu \frac{\partial }{\partial x}\ln \{\frac{1}{\sqrt{4\pi \nu t}}{\displaystyle \underset{-\mathrm{\infty }}{\overset{\mathrm{\infty }}{\int }}}\exp [-\frac{(x-x^{\prime }{)}^2}{4\nu t}-\frac{1}{2\nu }{\displaystyle \underset{0}{\overset{x^{\prime }}{\int }}}f(x^{″})d{x}^{″}]d{x}^{\prime }\}}$

which simplifies, by getting rid of the time-dependent prefactor in the argument of the logarithm, to

${\displaystyle u(x,t)=-2\nu \frac{\partial }{\partial x}\ln \{{\displaystyle \underset{-\mathrm{\infty }}{\overset{\mathrm{\infty }}{\int }}}\exp [-\frac{(x-x^{\prime }{)}^2}{4\nu t}-\frac{1}{2\nu }{\displaystyle \underset{0}{\overset{x^{\prime }}{\int }}}f(x^{″})d{x}^{″}]d{x}^{\prime }\}.}$

This solution is derived from the solution of the heat equation for ${\displaystyle \phi }$ that decays to zero as ${\displaystyle x\to \pm \mathrm{\infty }}$; other solutions for ${\displaystyle u}$ can be obtained starting from solutions of ${\displaystyle \phi }$ that satisfies different boundary conditions.

Explicit expressions for the viscous Burgers' equation are available. Some of the physically relevant solutions are given below:^[16]

If ${\displaystyle u(x,0)=f(x)}$ is such that ${\displaystyle f(-\mathrm{\infty })=f^{+}}$ and ${\displaystyle f(+\mathrm{\infty })=f^{-}}$ and ${\displaystyle f^{\prime }(x)<0}$, then we have a traveling-wave solution (with a constant speed ${\displaystyle c=(f^{+}+f^{-})/2}$) given by

${\displaystyle u(x,t)=c-\frac{f^{+}-f^{-}}{2}\tanh [\frac{f^{+}-f^{-}}{4\nu }(x-ct)].}$

This solution, that was originally derived by Harry Bateman in 1915,Template:R is used to describe the variation of pressure across a weak shock waveTemplate:R. When ${\displaystyle f^{+}=2}$ and ${\displaystyle f^{-}=0}$ to

${\displaystyle u(x,t)=\frac{2}{1+e^{\frac{x-t}{\nu }}}}$

with ${\displaystyle c=1}$.

If ${\displaystyle u(x,0)=2\nu Re\delta (x)}$, where ${\displaystyle Re}$ (say, the Reynolds number) is a constant, then we have^[17]

${\displaystyle u(x,t)=\sqrt{\frac{\nu }{\pi t}}\left[\frac{(e^{Re}-1)e^{-x^2/4\nu t}}{1+(e^{Re}-1)\mathrm{e}\mathrm{r}\mathrm{f}\mathrm{c}(x/\sqrt{4\nu t})/2}\right].}$

In the limit ${\displaystyle Re\to 0}$, the limiting behaviour is a diffusional spreading of a source and therefore is given by

${\displaystyle u(x,t)=\frac{2\nu Re}{\sqrt{4\pi \nu t}}\exp (-\frac{x^2}{4\nu t}).}$

On the other hand, In the limit ${\displaystyle Re\to \mathrm{\infty }}$, the solution approaches that of the aforementioned Chandrasekhar's shock-wave solution of the inviscid Burgers' equation and is given by

${\displaystyle u(x,t)=\{\begin{array}{c}\frac{x}{t},0<x<\sqrt{2\nu Ret},\\ 0,\text{otherwise}.\end{array}}$

The shock wave location and its speed are given by ${\displaystyle x=\sqrt{2\nu Ret}}$ and ${\displaystyle \sqrt{\nu Re/t}.}$

The N-wave solution comprises a compression wave followed by a rarafaction wave. A solution of this type is given by

${\displaystyle u(x,t)=\frac{x}{t}{[1+\frac{1}{e^{R{e}_0-1}}\sqrt{\frac{t}{t_0}}\exp (-\frac{Re(t)x^2}{4\nu R{e}_{0}t})]}^{-1}}$

where ${\displaystyle R_0}$ may be regarded as an initial Reynolds number at time ${\displaystyle t=t_0}$ and ${\displaystyle Re(t)=(1/2\nu ){\displaystyle \underset{0}{\overset{\mathrm{\infty }}{\int }}}udx=\ln (1+\sqrt{\tau /t})}$ with ${\displaystyle \tau =t_0\sqrt{e^{R{e}_0}-1}}$, may be regarded as the time-varying Reynold number.

In two or more dimensions, the Burgers' equation becomes

${\displaystyle \frac{\partial u}{\partial t}+u\cdot \mathrm{\nabla }u=\nu {\mathrm{\nabla }}^{2}u.}$

One can also extend the equation for the vector field ${\displaystyle 𝐮}$, as in

${\displaystyle \frac{\partial 𝐮}{\partial t}+𝐮\cdot \mathrm{\nabla }𝐮=\nu {\mathrm{\nabla }}^2𝐮.}$

The generalized Burgers' equation extends the quasilinear convective to more generalized form, i.e.,

${\displaystyle \frac{\partial u}{\partial t}+c(u)\frac{\partial u}{\partial x}=\nu \frac{{\partial }^{2}u}{\partial x^2}.}$

where ${\displaystyle c(u)}$ is any arbitrary function of u. The inviscid ${\displaystyle \nu =0}$ equation is still a quasilinear hyperbolic equation for ${\displaystyle c(u)>0}$ and its solution can be constructed using method of characteristics as before.^[18]

Added space-time noise ${\displaystyle \eta (x,t)=\dot{W}(x,t)}$, where ${\displaystyle W}$ is an ${\displaystyle L^2(ℝ)}$ Wiener process, forms a stochastic Burgers' equation^[19]

${\displaystyle \frac{\partial u}{\partial t}+u\frac{\partial u}{\partial x}=\nu \frac{{\partial }^{2}u}{\partial x^2}-\lambda \frac{\partial \eta }{\partial x}.}$

This stochastic PDE is the one-dimensional version of Kardar–Parisi–Zhang equation in a field ${\displaystyle h(x,t)}$ upon substituting ${\displaystyle u(x,t)=-\lambda \partial h/\partial x}$.

• Chaplygin's equation
• Conservation equation
• Euler–Tricomi equation
• Fokker–Planck equation
• KdV-Burgers equation

Template:Reflist

• Burgers' Equation at EqWorld: The World of Mathematical Equations.
• Burgers' Equation at NEQwiki, the nonlinear equations encyclopedia.