Cusp (singularity) explained
In mathematics, a cusp, sometimes called spinode in old texts, is a point on a curve where a moving point must reverse direction. A typical example is given in the figure. A cusp is thus a type of singular point of a curve.
For a plane curve defined by an analytic, parametric equation
\begin{align}
x&=f(t)\\
y&=g(t),
\end{align}
a cusp is a point where both
derivatives of and are zero, and the
directional derivative, in the direction of the
tangent, changes sign (the direction of the tangent is the direction of the slope
). Cusps are
local singularities in the sense that they involve only one value of the parameter, in contrast to self-intersection points that involve more than one value. In some contexts, the condition on the directional derivative may be omitted, although, in this case, the singularity may look like a regular point.
which is
smooth, cusps are points where the terms of lowest degree of the
Taylor expansion of are a power of a linear polynomial; however, not all singular points that have this property are cusps. The theory of
Puiseux series implies that, if is an
analytic function (for example a
polynomial), a linear change of coordinates allows the curve to be
parametrized, in a
neighborhood of the cusp, as
\begin{align}
x&=atm\\
y&=S(t),
\end{align}
where is a
real number, is a positive
even integer, and is a
power series of order (degree of the nonzero term of the lowest degree) larger than . The number is sometimes called the
order or the
multiplicity of the cusp, and is equal to the degree of the nonzero part of lowest degree of . In some contexts, the definition of a cusp is restricted to the case of cusps of order two—that is, the case where .
The definitions for plane curves and implicitly-defined curves have been generalized by René Thom and Vladimir Arnold to curves defined by differentiable functions: a curve has a cusp at a point if there is a diffeomorphism of a neighborhood of the point in the ambient space, which maps the curve onto one of the above-defined cusps.
Classification in differential geometry
Consider a smooth real-valued function of two variables, say where and are real numbers. So is a function from the plane to the line. The space of all such smooth functions is acted upon by the group of diffeomorphisms of the plane and the diffeomorphisms of the line, i.e. diffeomorphic changes of coordinate in both the source and the target. This action splits the whole function space up into equivalence classes, i.e. orbits of the group action.
One such family of equivalence classes is denoted by where is a non-negative integer. A function is said to be of type if it lies in the orbit of
i.e. there exists a diffeomorphic change of coordinate in source and target which takes into one of these forms. These simple forms
are said to give
normal forms for the type -singularities. Notice that the are the same as the since the diffeomorphic change of coordinate in the source takes
to
So we can drop the ± from notation.
The cusps are then given by the zero-level-sets of the representatives of the equivalence classes, where is an integer.
Examples
- An ordinary cusp is given by
i.e. the zero-level-set of a type -singularity. Let be a smooth function of and and assume, for simplicity, that . Then a type -singularity of at can be characterised by:
- Having a degenerate quadratic part, i.e. the quadratic terms in the Taylor series of form a perfect square, say, where is linear in and, and
- does not divide the cubic terms in the Taylor series of .
- A rhamphoid cusp denoted originally a cusp such that both branches are on the same side of the tangent, such as for the curve of equation
As such a singularity is in the same differential class as the cusp of equation
which is a singularity of type, the term has been extended to all such singularities. These cusps are non-generic as
caustics and
wave fronts. The rhamphoid cusp and the ordinary cusp are non-diffeomorphic. A parametric form is
For a type -singularity we need to have a degenerate quadratic part (this gives type), that does divide the cubic terms (this gives type), another divisibility condition (giving type), and a final non-divisibility condition (giving type exactly).
To see where these extra divisibility conditions come from, assume that has a degenerate quadratic part and that divides the cubic terms. It follows that the third order taylor series of is given by
where is quadratic in and . We can
complete the square to show that
We can now make a diffeomorphic change of variable (in this case we simply substitute polynomials with
linearly independent linear parts) so that
where is
quartic (order four) in and . The divisibility condition for type is that divides . If does not divide then we have type exactly (the zero-level-set here is a
tacnode). If divides we complete the square on
and change coordinates so that we have
where is
quintic (order five) in and . If does not divide then we have exactly type, i.e. the zero-level-set will be a rhamphoid cusp.
Applications
Cusps appear naturally when projecting into a plane a smooth curve in three-dimensional Euclidean space. In general, such a projection is a curve whose singularities are self-crossing points and ordinary cusps. Self-crossing points appear when two different points of the curves have the same projection. Ordinary cusps appear when the tangent to the curve is parallel to the direction of projection (that is when the tangent projects on a single point). More complicated singularities occur when several phenomena occur simultaneously. For example, rhamphoid cusps occur for inflection points (and for undulation points) for which the tangent is parallel to the direction of projection.
In many cases, and typically in computer vision and computer graphics, the curve that is projected is the curve of the critical points of the restriction to a (smooth) spatial object of the projection. A cusp appears thus as a singularity of the contour of the image of the object (vision) or of its shadow (computer graphics).
Caustics and wave fronts are other examples of curves having cusps that are visible in the real world.
See also
References
- Book: Bruce, J. W.. Peter. Giblin. Peter Giblin. Curves and Singularities. Cambridge University Press. 1984. 978-0-521-42999-3.
- Book: Porteous, Ian . Ian R. Porteous. Geometric Differentiation . registration . 1994 . Cambridge University Press . 978-0-521-39063-7.
External links