In
projective geometry
In mathematics, projective geometry is the study of geometric properties that are invariant with respect to projective transformations. This means that, compared to elementary Euclidean geometry, projective geometry has a different setting, ...
, a dual curve of a given
plane curve
In mathematics, a plane curve is a curve in a plane that may be either a Euclidean plane, an affine plane or a projective plane. The most frequently studied cases are smooth plane curves (including piecewise smooth plane curves), and algebraic ...
is a curve in the
dual projective plane
In geometry, a striking feature of projective planes is the symmetry of the roles played by points and lines in the definitions and theorems, and (plane) duality is the formalization of this concept. There are two approaches to the subject of du ...
consisting of the set of lines
tangent
In geometry, the tangent line (or simply tangent) to a plane curve at a given point is the straight line that "just touches" the curve at that point. Leibniz defined it as the line through a pair of infinitely close points on the curve. Mo ...
to . There is a
map
A map is a symbolic depiction emphasizing relationships between elements of some space, such as objects, regions, or themes.
Many maps are static, fixed to paper or some other durable medium, while others are dynamic or interactive. Although ...
from a curve to its dual, sending each point to the point dual to its tangent line. If is
algebraic then so is its dual and the degree of the dual is known as the ''class'' of the original curve. The equation of the dual of , given in
line coordinates, is known as the ''tangential equation'' of . Duality is an
involution
Involution may refer to:
* Involute, a construction in the differential geometry of curves
* '' Agricultural Involution: The Processes of Ecological Change in Indonesia'', a 1963 study of intensification of production through increased labour inpu ...
: the dual of the dual of is the original curve .
The construction of the dual curve is the geometrical underpinning for the
Legendre transformation
In mathematics, the Legendre transformation (or Legendre transform), named after Adrien-Marie Legendre, is an involutive transformation on real-valued convex functions of one real variable. In physical problems, it is used to convert functions ...
in the context of
Hamiltonian mechanics
Hamiltonian mechanics emerged in 1833 as a reformulation of Lagrangian mechanics. Introduced by Sir William Rowan Hamilton, Hamiltonian mechanics replaces (generalized) velocities \dot q^i used in Lagrangian mechanics with (generalized) ''momenta ...
.
Equations
Let be the equation of a curve in
homogeneous coordinates
In mathematics, homogeneous coordinates or projective coordinates, introduced by August Ferdinand Möbius in his 1827 work , are a system of coordinates used in projective geometry, just as Cartesian coordinates are used in Euclidean geometry. ...
on the
projective plane
In mathematics, a projective plane is a geometric structure that extends the concept of a plane. In the ordinary Euclidean plane, two lines typically intersect in a single point, but there are some pairs of lines (namely, parallel lines) that d ...
. Let be the equation of a line, with being designated its
line coordinatesin a dual projective plane. The condition that the line is tangent to the curve can be expressed in the form which is the tangential equation of the curve.
At a on the curve, the tangent is given by
:
So is a tangent to the curve if
:
Eliminating , , , and from these equations, along with , gives the equation in , and of the dual curve.
For example, let be the
conic
In mathematics, a conic section, quadratic curve or conic is a curve obtained as the intersection of the surface of a cone with a plane. The three types of conic section are the hyperbola, the parabola, and the ellipse; the circle is a specia ...
. The dual is found by eliminating , , , and from the equations
:
The first three equations are easily solved for , , , and substituting in the last equation produces
:
Clearing from the denominators, the equation of the dual is
:
Consider a
parametrically defined curve in projective coordinates
. Its projective tangent line is a linear plane spanned by the point of tangency and the tangent vector, with linear equation coefficients given by the
cross product:
which in affine coordinates
is:
:
The dual of an
inflection point
In differential calculus and differential geometry, an inflection point, point of inflection, flex, or inflection (British English: inflexion) is a point on a smooth plane curve at which the curvature changes sign. In particular, in the case ...
will give a
cusp
A cusp is the most pointed end of a curve. It often refers to cusp (anatomy), a pointed structure on a tooth.
Cusp or CUSP may also refer to:
Mathematics
* Cusp (singularity), a singular point of a curve
* Cusp catastrophe, a branch of bifurc ...
and two points sharing the same tangent line will give a self-intersection point on the dual.
From the projective description, one may compute the dual of the dual:
which is projectively equivalent to the original curve
.
Properties of dual curve
Properties of the original curve correspond to dual properties on the dual curve. In the Introduction image, the red curve has three singularities – a node in the center, and two cusps at the lower right and lower left. The black curve has no singularities but has four distinguished points: the two top-most points correspond to the node (double point), as they both have the same tangent line, hence map to the same point in the dual curve, while the two inflection points correspond to the cusps, since the tangent lines first go one way then the other (slope increasing, then decreasing).
By contrast, on a smooth, convex curve the angle of the tangent line changes monotonically, and the resulting dual curve is also smooth and convex.
Further, both curves above have a reflectional symmetry: projective duality preserves symmetries a projective space, so dual curves have the same symmetry group. In this case both symmetries are realized as a left-right reflection; this is an artifact of how the space and the dual space have been identified – in general these are symmetries of different spaces.
Degree
If is a plane algebraic curve, then the degree of the dual is the number of points intersection with a line in the dual plane. Since a line in the dual plane corresponds to a point in the plane, the degree of the dual is the number of tangents to the that can be drawn through a given point. The points where these tangents touch the curve are the points of intersection between the curve and the
polar curve
In algebraic geometry, the first polar, or simply polar of an algebraic plane curve ''C'' of degree ''n'' with respect to a point ''Q'' is an algebraic curve of degree ''n''−1 which contains every point of ''C'' whose tangent line passes throu ...
with respect to the given point. If the degree of the curve is then the degree of the polar is and so the number of tangents that can be drawn through the given point is at most .
The dual of a line (a curve of degree 1) is an exception to this and is taken to be a point in the dual space (namely the original line). The dual of a single point is taken to be the collection of lines though the point; this forms a line in the dual space which corresponds to the original point.
If is smooth (no
singular points) then the dual of has maximum degree . This implies the dual of a conic is also a conic. Geometrically, the map from a conic to its dual is
one-to-one (since no line is tangent to two points of a conic, as that requires degree 4), and the tangent line varies smoothly (as the curve is convex, so the slope of the tangent line changes monotonically: cusps in the dual require an inflection point in the original curve, which requires degree 3).
For curves with singular points, these points will also lie on the intersection of the curve and its polar and this reduces the number of possible tangent lines. The
Plücker formula In mathematics, a Plücker formula, named after Julius Plücker, is one of a family of formulae, of a type first developed by Plücker in the 1830s, that relate certain numeric invariants of algebraic curves to corresponding invariants of their du ...
s give the degree of the dual in terms of ''d'' and the number and types of singular points of .
Polar reciprocal
The dual can be visualized as a locus in the plane in the form of the ''polar reciprocal''. This is defined with reference to a fixed conic as the locus of the poles of the tangent lines of the curve .
The conic is nearly always taken to be a circle, so the polar reciprocal is the
inverse of the
pedal
A pedal (from the Latin '' pes'' ''pedis'', "foot") is a lever designed to be operated by foot and may refer to:
Computers and other equipment
* Footmouse, a foot-operated computer mouse
* In medical transcription, a pedal is used to control p ...
of .
Generalizations
Higher dimensions
Similarly, generalizing to higher dimensions, given a
hypersurface
In geometry, a hypersurface is a generalization of the concepts of hyperplane, plane curve, and surface. A hypersurface is a manifold or an algebraic variety of dimension , which is embedded in an ambient space of dimension , generally a Euclidea ...
, the
tangent space
In mathematics, the tangent space of a manifold generalizes to higher dimensions the notion of '' tangent planes'' to surfaces in three dimensions and ''tangent lines'' to curves in two dimensions. In the context of physics the tangent space to a ...
at each point gives a family of
hyperplanes, and thus defines a dual hypersurface in the dual space. For any closed subvariety in a projective space, the set of all hyperplanes tangent to some point of is a closed subvariety of the dual of the projective space, called the dual variety of .
Examples
* If is a hypersurface defined by a homogeneous polynomial , then the dual variety of is the image of by the gradient map
::
:which lands in the dual projective space.
* The dual variety of a point is the hyperplane
::
Dual polygon
The dual curve construction works even if the curve is
piecewise linear or
piecewise differentiable
In mathematics, a piecewise-defined function (also called a piecewise function, a hybrid function, or definition by cases) is a function defined by multiple sub-functions, where each sub-function applies to a different interval in the domain. Pi ...
, but the resulting map is degenerate (if there are linear components) or ill-defined (if there are singular points).
In the case of a polygon, all points on each edge share the same tangent line, and thus map to the same vertex of the dual, while the tangent line of a vertex is ill-defined, and can be interpreted as all the lines passing through it with angle between the two edges. This accords both with projective duality (lines map to points, and points to lines), and with the limit of smooth curves with no linear component: as a curve flattens to an edge, its tangent lines map to closer and closer points; as a curve sharpens to a vertex, its tangent lines spread further apart.
More generally, any convex polyhedron or cone has a
polyhedral dual, and any convex set ''X'' with boundary hypersurface ''H'' has a
convex conjugate
In mathematics and mathematical optimization, the convex conjugate of a function is a generalization of the Legendre transformation which applies to non-convex functions. It is also known as Legendre–Fenchel transformation, Fenchel transformatio ...
''X*'' whose boundary is the dual variety ''H*''.
See also
*
Hough transform
*
Gauss map
In differential geometry, the Gauss map (named after Carl F. Gauss) maps a surface in Euclidean space R3 to the unit sphere ''S''2. Namely, given a surface ''X'' lying in R3, the Gauss map is a continuous map ''N'': ''X'' → ''S''2 such that ' ...
Notes
References
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