For example, consider the electromagnetic wave equation:

where ${\displaystyle c={\frac {1}{\sqrt {\mu _{0}\varepsilon _{0}}}}~.}$ 

If k₀ and ω₀ are the wave number and angular frequency of the (characteristic) carrier wave for the signal E(r,t), the following representation is useful:

where ${\displaystyle \operatorname {Re} [\,\cdot \,]}$  denotes the real part of the quantity between brackets, and ${\displaystyle i^{2}\equiv -1.}$ 

In the slowly varying envelope approximation (SVEA) it is assumed that the complex amplitude E₀(r, t) only varies slowly with r and t. This inherently implies that E(r, t) represents waves propagating forward, predominantly in the k₀ direction. As a result of the slow variation of E₀(r, t), when taking derivatives, the highest-order derivatives may be neglected:^[2]

${\displaystyle \left|\nabla ^{2}E_{0}\right|\ll \left|\mathbf {k} _{0}\cdot \nabla E_{0}\right|}$    and   ${\displaystyle \left|{\frac {\partial ^{2}E_{0}}{\partial t^{2}}}\right|\ll \left|\omega _{0}\,{\frac {\partial E_{0}}{\partial t}}\right|,}$    with   ${\displaystyle k_{0}\equiv \left|\mathbf {k} _{0}\right|.}$ 

Full approximation edit

Consequently, the wave equation is approximated in the SVEA as:

It is convenient to choose k₀ and ω₀ such that they satisfy the dispersion relation:

This gives the following approximation to the wave equation, as a result of the slowly varying envelope approximation:

This is a hyperbolic partial differential equation, like the original wave equation, but now of first-order instead of second-order. It is valid for coherent forward-propagating waves in directions near the k₀-direction. The space and time scales over which E₀ varies are generally much longer than the spatial wavelength and temporal period of the carrier wave. A numerical solution of the envelope equation thus can use much larger space and time steps, resulting in significantly less computational effort.

Parabolic approximation edit

Assume wave propagation is dominantly in the z-direction, and k₀ is taken in this direction. The SVEA is only applied to the second-order spatial derivatives in the z-direction and time. If ${\displaystyle \Delta _{\perp }\equiv \partial ^{2}/\partial x^{2}+\partial ^{2}/\partial y^{2}}$  is the Laplace operator in the x×y plane, the result is:^[3]

This is a parabolic partial differential equation. This equation has enhanced validity as compared to the full SVEA: It represents waves propagating in directions significantly different from the z-direction.

Alternative limit of validity edit

In the one-dimensional case, another sufficient condition for the SVEA validity is

${\displaystyle \ell _{\mathsf {g}}\gg \lambda }$    and   ${\displaystyle \ell _{\mathsf {p}}\gg \lambda \left(1-{\frac {v}{c}}\right)\,,}$    with   ${\displaystyle \lambda ={\frac {2\pi }{k_{0}}}\,,}$ 

where ${\displaystyle \ell _{\mathsf {g}}}$  is the length over which the radiation pulse is amplified, ${\displaystyle \ell _{\mathsf {p}}}$  is the pulse width and ${\displaystyle v}$  is the group velocity of the radiating system.^[4]

These conditions are much less restrictive in the relativistic limit where ${\displaystyle {\frac {v}{c}}}$  is close to 1, as in a free-electron laser, compared to the usual conditions required for the SVEA validity.

• Ultrashort pulse
• WKB approximation