Benjamin–Bona–Mahony equation explained

The Benjamin–Bona–Mahony equation (BBM equation, also regularized long-wave equation; RLWE) is the partial differential equation

u_t+u_x+uu_x-u_xxt=0.

This equation was studied in as an improvement of the Korteweg–de Vries equation (KdV equation) for modeling long surface gravity waves of small amplitude – propagating uni-directionally in 1+1 dimensions. They show the stability and uniqueness of solutions to the BBM equation. This contrasts with the KdV equation, which is unstable in its high wavenumber components. Further, while the KdV equation has an infinite number of integrals of motion, the BBM equation only has three.

Before, in 1966, this equation was introduced by Peregrine, in the study of undular bores.

A generalized n-dimensional version is given by

	2u
u
	t+\operatorname{div}\varphi(u)=0.

where

\varphi

is a sufficiently smooth function from

Rⁿ

. proved global existence of a solution in all dimensions.

Solitary wave solution

The BBM equation possesses solitary wave solutions of the form:

u=3

	c²
	1-c²

\operatorname{sech}²

	12
	\left(

cx-

	ct
	1-c²

+\delta\right),

where sech is the hyperbolic secant function and

\delta

is a phase shift (by an initial horizontal displacement). For

|c|<1

, the solitary waves have a positive crest elevation and travel in the positive

-direction with velocity

1/(1-c^2).

These solitary waves are not solitons, i.e. after interaction with other solitary waves, an oscillatory tail is generated and the solitary waves have changed.

Hamiltonian structure

The BBM equation has a Hamiltonian structure, as it can be written as:

u_t=-l{D}

	\deltaH
	\deltau

with Hamiltonian

	+infty
\int
	-infty

\left(\tfrac12u²+\tfrac16u³\right)dx

and operator

l{D}=\left(1-

	2
\partial
	x

\right)^-1\partial_x.

Here

\deltaH/\deltau

is the variation of the Hamiltonian

H(u)

with respect to

u(x),

and

\partial_x

denotes the partial differential operator with respect to

Conservation laws

The BBM equation possesses exactly three independent and non-trivial conservation laws. First

is replaced by

u=-v-1

in the BBM equation, leading to the equivalent equation:

v_t-v_xxt=vv_x.

The three conservation laws then are:

\begin{align} v_t-\left(v_xt+\tfrac12v²\right)_x&=0,\\ \left(\tfrac12v²+\tfrac12

	2
v
	x

\right)_t-\left(vv_xt+\tfrac13v³\right)_x&=0,\\ \left(\tfrac13v³\right)_t+\left(

	2
v
	t

	2
v
	xt

-v²v_xt-\tfrac14v⁴\right)_x&=0. \end{align}

Which can easily expressed in terms of

by using

v=-u-1.

Linear dispersion

The linearized version of the BBM equation is:

u_t+u_x-u_xxt=0.

Periodic progressive wave solutions are of the form:

u=aeⁱ,

with

the wavenumber and

\omega

the angular frequency. The dispersion relation of the linearized BBM equation is

\omega_BBM=

	k
	1+k²

Similarly, for the linearized KdV equation

u_t+u_x+u_xxx=0

the dispersion relation is:

\omega_KdV=k-k^3.

This becomes unbounded and negative for

k\toinfty,

and the same applies to the phase velocity

\omega_KdV/k

and group velocity

d\omega_KdV/dk.

Consequently, the KdV equation gives waves travelling in the negative

-direction for high wavenumbers (short wavelengths). This is in contrast with its purpose as an approximation for uni-directional waves propagating in the positive

-direction.

The strong growth of frequency

\omega_KdV

and phase speed with wavenumber

posed problems in the numerical solution of the KdV equation, while the BBM equation does not have these shortcomings.

References

- - - - (Warning: On p. 174 Zwillinger misstates the Benjamin–Bona–Mahony equation, confusing it with the similar KdV equation.)