In the mathematical field of algebraic geometry, a **singular point of an algebraic variety** *V* is a point *P* that is 'special' (so, singular), in the geometric sense that at this point the tangent space at the variety may not be regularly defined. In case of varieties defined over the reals, this notion generalizes the notion of local non-flatness. A point of an algebraic variety which is not singular is said to be **regular**. An algebraic variety which has no singular point is said to be **non-singular** or **smooth**.

## Definition

A plane curve defined by an implicit equation

*F*(*x*,*y*) = 0,

where *F* is a smooth function is said to be *singular* at a point if the Taylor series of *F* has order at least 2 at this point.

The reason for this is that, in differential calculus, the tangent at the point (*x*_{0}, *y*_{0}) of such a curve is defined by the equation

whose left-hand side is the term of degree one of the Taylor expansion. Thus, if this term is zero, the tangent may not be defined in the standard way, either because it does not exist or a special definition must be provided.

In general for a hypersurface

*F*(*x*,*y*,*z*, ...) = 0

the **singular points** are those at which all the partial derivatives simultaneously vanish. A general algebraic variety *V* being defined as the common zeros of several polynomials, the condition on a point *P* of *V* to be singular point is that the Jacobian matrix of the first order partial derivatives of the polynomials has a rank at *P* that is lower than the rank at other points of the variety.

Points of *V* that are not singular are called **non-singular** or **regular**. It is always true that almost all points are non-singular, in the sense that the non-singular points form a set that is both open and dense in the variety (for the Zariski topology, as well as for the usual topology, in the case of varieties defined over the complexes).^{[1]}

In case of a real variety (that is the set of the points with real coordinates of a variety defined by polynomials with real coefficients), the variety is a manifold near every regular point. But it is important to note that a real variety may be a manifold and have singular points. For example the equation defines a real analytic manifold but has a singular point at the origin.^{[2]} This may be explained by saying that the curve has two complex conjugate branches that cut the real branch at the origin.

## Singular points of smooth mappings

As the notion of singular points is a purely local property, the above definition can be extended to cover the wider class of smooth mappings, (functions from *M* to **R**^{n} where all derivatives exist). Analysis of these singular points can be reduced to the algebraic variety case by considering the jets of the mapping. The *k*-th jet is the Taylor series of the mapping truncated at degree *k* and deleting the constant term.

## Nodes

In classical algebraic geometry, certain special singular points were also called **nodes**. A node is a singular point where the Hessian matrix is non-singular; this implies that the singular point has multiplicity two and the tangent cone is not singular outside its vertex.

## See also

- Singular point of a curve
- Singularity theory
- Smooth scheme
- Zariski tangent space
- Resolution of singularities

## References

**^**Hartshorne, Robin (1977).*Algebraic Geometry*. Berlin, New York: Springer-Verlag. p. 33. ISBN 978-0-387-90244-9. MR 0463157. Zbl 0367.14001.**^**Milnor, pp. 12–13

This article needs additional citations for verification. (September 2008) (Learn how and when to remove this template message) |

- John Milnor (1969).
*Singular Points of Complex Hypersurfaces*. Annals of Mathematics Studies.**61**. Princeton University Press. ISBN 0-691-08065-8.