Let C be defined in homogeneous coordinates by f = 0 where f is a homogeneous polynomial of degree n, and let the homogeneous coordinates of Q be. Define the operator Then ΔQf is a homogeneous polynomial of degree n−1 and ΔQf = 0 defines a curve of degree n−1 called the first polar of C with respect of Q. If P= is a non-singular point on the curve C then the equation of the tangent at P is In particular, P is on the intersection of C and its first polar with respect to Qif and only ifQ is on the tangent to C at P. For a double point of C, the partial derivatives of f are all 0 so the first polar contains these points as well.
Class of a curve
The class of C may be defined as the number of tangents that may be drawn to C from a point not on C. Each of these tangents touches C at one of the points of intersection of C and the first polar, and by Bézout's theorem there are at most n of these. This puts an upper bound of n on the class of a curve of degree n. The class may be computed exactly by counting the number and type of singular points on C.
Higher polars
The p-th polar of a C for a natural numberp is defined as ΔQpf = 0. This is a curve of degree n−p. When p is n−1 the p-th polar is a line called the polar line of C with respect to Q. Similarly, when p is n−2 the curve is called the polar conic of C. Using Taylor series in several variables and exploiting homogeneity, f can be expanded in two ways as and Comparing coefficients of λpμn−p shows that In particular, the p-th polar of C with respect to Q is the locus of pointsP so that the -th polar of C with respect to P passes through Q.
Poles
If the polar line of C with respect to a point Q is a line L, then Q is said to be a pole of L. A given line has 2 poles where n is the degree of C. To see this, pick two points P and Q on L. The locus of points whose polar lines pass through P is the first polar of P and this is a curve of degree n−1. Similarly, the locus of points whose polar lines pass through Q is the first polar of Q and this is also a curve of degree n−1. The polar line of a point is L if and only if it contains both P and Q, so the poles of L are exactly the points of intersection of the two first polars. By Bézout's theorem these curves have 2 points of intersection and these are the poles of L.
For a given point Q=, the polar conic is the locus of points P so that Q is on the second polar of P. In other words, the equation of the polar conic is The conic is degenerate if and only if the determinant of the Hessian of f, vanishes. Therefore, the equation |H|=0 defines a curve, the locus of points whose polar conics are degenerate, of degree 3 called the Hessian curve of C.