In mathematical analysis, more precisely in microlocal analysis, the wave front (set) WF(f) characterizes the singularities of a generalized function f, not only in space, but also with respect to its Fourier transform at each point. The term "wave front" was coined by Lars Hörmander around 1970.
In more familiar terms, WF(f) tells not only where the function f is singular (which is already described by its singular support), but also how or why it is singular, by being more exact about the direction in which the singularity occurs. This concept is mostly useful in dimension at least two, since in one dimension there are only two possible directions. The complementary notion of a function being non-singular in a direction is microlocal smoothness.
Intuitively, as an example, consider a function ƒ whose singular support is concentrated on a smooth curve in the plane at which the function has a jump discontinuity. In the direction tangent to the curve, the function remains smooth. By contrast, in the direction normal to the curve, the function has a singularity. To decide on whether the function is smooth in another direction v, one can try to smooth the function out by averaging in directions perpendicular to v. If the resulting function is smooth, then we regard ƒ to be smooth in the direction of v. Otherwise, v is in the wavefront set.
Formally, in Euclidean space, the wave front set of ƒ is defined as the complement of the set of all pairs (x0,v) such that there exists a test function
\phi\in
| infty | |
| C | |
| c |
\phi
|(\phif)\wedge(\xi)|\le
| -N | |
| C | |
| N(1+|\xi|) |
forall \xi\in\Gamma
(\phif)\wedge
Because the definition involves cutoff by a compactly supported function, the notion of a wave front set can be transported to any differentiable manifold X. In this more general situation, the wave front set is a closed conical subset of the cotangent bundle T*(X), since the ξ variable naturally localizes to a covector rather than a vector. The wave front set is defined such that its projection on X is equal to the singular support of the function.
In Euclidean space, the wave front set of a distribution ƒ is defined as
{\rmWF}(f)=\{(x,\xi)\inRn x Rn\mid\xi\in\Sigmax(f)\}
where
\Sigmax(f)
\xi
\xi
\Sigmax(f)
|(\phif)\wedge(\xi)|<
| -N | |
| c | |
| N(1+|\xi|) |
{\rmfor~all} \xi\in\Gamma.
Once such an estimate holds for a particular cutoff function φ at x, it also holds for all cutoff functions with smaller support, possibly for a different open cone containing v.
On a differentiable manifold M, using local coordinates
x,\xi
{\rmWF}(f)=\{(x,\xi)\inT*(X)\mid\xi\in\Sigmax(f)\}
where the singular fibre
\Sigmax(f)
\xi
\xi
The notion of a wave front set can be adapted to accommodate other notions of regularity of a function. Localized can here be expressed by saying that f is truncated by some smooth cutoff function not vanishing at x. (The localization process could be done in a more elegant fashion, using germs.)
More concretely, this can be expressed as
\xi\notin\Sigmax(f)\iff\xi=0or\exists\phi\inlDx, \existsV\inlV\xi:\widehat{\phif}|V\inO(V)
lDx
lV\xi
\xi
c ⋅ V\subsetV
c>0
\widehatu|V
O:\Omega\toO(\Omega)
Typically, sections of O are required to satisfy some growth (or decrease) condition at infinity, e.g. such that
(1+|\xi|)sv(\xi)
\phi
The most difficult "problem", from a theoretical point of view,is finding the adequate sheaf O characterizing functions belonging to a given subsheaf E of the space G of generalized functions.
If we take G = D′ the space of Schwartz distributions and want to characterize distributions which are locally
Cinfty
Then the projection on the first component of a distribution's wave front set is nothing else than its classical singular support, i.e. the complement of the set on which its restriction would be a smooth function.
The wave front set is useful, among others, when studying propagation of singularities by pseudodifferential operators.