In continuum mechanics, wave action refers to a conservable measure of the wave part of a motion. For small-amplitude and slowly varying waves, the wave action density is:
l{A}=
| E | |
| \omegai |
,
where
E
\omegai
The action of a wave was introduced by in the study of the (pseudo) energy and momentum of waves in plasmas. derived the conservation of wave action – identified as an adiabatic invariant – from an averaged Lagrangian description of slowly varying nonlinear wave trains in inhomogeneous media:
| \partial | |
| \partialt |
l{A}+\boldsymbol{\nabla} ⋅ \boldsymbol{l{B}}=0,
where
\boldsymbol{l{B}}
\boldsymbol{\nabla} ⋅ \boldsymbol{l{B}}
\boldsymbol{l{B}}
| \partial | |
| \partialt |
\left(
| E | |
| \omegai |
\right)+\boldsymbol{\nabla} ⋅ \left[\left(\boldsymbol{U}+\boldsymbol{c}g\right)
| E | |
| \omegai |
\right]=0,
l{A}=
| E | |
| \omegai |
\boldsymbol{l{B}}=\left(\boldsymbol{U}+\boldsymbol{c}g\right)l{A},
where
\boldsymbol{c}g
\boldsymbol{U}
The equation for the conservation of wave action is for instance used extensively in wind wave models to forecast sea states as needed by mariners, the offshore industry and for coastal defense. Also in plasma physics and acoustics the concept of wave action is used.
The derivation of an exact wave-action equation for more general wave motion – not limited to slowly modulated waves, small-amplitude waves or (non-dissipative) conservative systems – was provided and analysed by using the framework of the generalised Lagrangian mean for the separation of wave and mean motion.