Tacnode

More general background

Consider a smooth real-valued function of two variables, say f(x, y) where x and y are real numbers. So f 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 A_k^±, where k is a non-negative integer. This notation was introduced by V. I. Arnold. A function f is said to be of type A_k^± if it lies in the orbit of x² ± y^k+1, i.e. there exists a diffeomorphic change of coordinate in source and target which takes f into one of these forms. These simple forms x² ± y^k+1 are said to give normal forms for the type A_k^±-singularities.

A curve with equation f = 0 will have a tacnode, say at the origin, if and only if f has a type A₃⁻-singularity at the origin.

Notice that a node (x² − y² = 0) corresponds to a type A₁⁻-singularity. A tacnode corresponds to a type A₃⁻-singularity. In fact each type A_2n+1⁻-singularity, where n ≥ 0 is an integer, corresponds to a curve with self intersection. As n increases the order of self intersection increases: transverse crossing, ordinary tangency, etc.

The type A_2n+1⁺-singularities are of no interest over the real numbers: they all give an isolated point. Over the complex numbers type A_2n+1⁺-singularities and type A_2n+1⁻-singularities are equivalent: (x,y) → (x, iy) gives the required diffeomorphism of the normal forms.