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 that do not intersect. A projective plane can be thought of as an ordinary plane equipped with additional "points at infinity" where parallel lines intersect. Thus any two distinct lines in a projective plane intersect in one and only one point.
artists, in developing the techniques of drawing in perspective, laid the groundwork for this mathematical topic. The archetypical example is the real projective plane, also known as the extended Euclidean plane. This example, in slightly different guises, is important in algebraic geometry, topology and projective geometry where it may be denoted variously by, RP2, or P2, among other notations. There are many other projective planes, both infinite, such as the complex projective plane, and finite, such as the Fano plane.
A projective plane is a 2-dimensional projective space, but not all projective planes can be embedded in 3-dimensional projective spaces. Such embeddability is a consequence of a property known as Desargues' theorem, not shared by all projective planes.

Definition

A projective plane consists of a set of lines, a set of points, and a relation between points and lines called incidence, having the following properties:

  1. Given any two distinct points, there is exactly one line incident with both of them.
  2. Given any two distinct lines, there is exactly one point incident with both of them.
  3. There are four points such that no line is incident with more than two of them.

The second condition means that there are no parallel lines. The last condition excludes the so-called degenerate cases. The term "incidence" is used to emphasize the symmetric nature of the relationship between points and lines. Thus the expression "point P is incident with line " is used instead of either "P is on " or " passes through P ".

Examples

The extended Euclidean plane

To turn the ordinary Euclidean plane into a projective plane proceed as follows:
  1. To each parallel class of lines associate a single new point. That point is to be considered incident with each line in its class. The new points added are distinct from each other. These new points are called points at infinity.
  2. Add a new line, which is considered incident with all the points at infinity. This line is called the line at infinity.
The extended structure is a projective plane and is called the extended Euclidean plane or the real projective plane. The process outlined [|above], used to obtain it, is called "projective completion" or projectivization. This plane can also be constructed by starting from R3 viewed as a vector space, see [|below].

Projective Moulton plane

The points of the Moulton plane are the points of the Euclidean plane, with coordinates in the usual way. To create the Moulton plane from the Euclidean plane some of the lines are redefined. That is, some of their point sets will be changed, but other lines will remain unchanged. Redefine all the lines with negative slopes so that they look like "bent" lines, meaning that these lines keep their points with negative x-coordinates, but the rest of their points are replaced with the points of the line with the same y-intercept but twice the slope wherever their x-coordinate is positive.
The Moulton plane has parallel classes of lines and is an affine plane. It can be projectivized, as in the previous example, to obtain the projective Moulton plane. Desargues' theorem is not a valid theorem in either the Moulton plane or the projective Moulton plane.

A finite example

This example has just thirteen points and thirteen lines. We label the points P1,...,P13 and the lines m1,...,m13. The incidence relation can be given by the following incidence matrix. The rows are labelled by the points and the columns are labelled by the lines. A 1 in row i and column j means that the point Pi is on the line mj, while a 0 means that they are not incident. The matrix is in Paige-Wexler normal form.
To verify the conditions that make this a projective plane, observe that every two rows have exactly one common column in which 1's appear and that every two columns have exactly one common row in which 1's appear. Among many possibilities, the points P1,P4,P5,and P8, for example, will satisfy the [|third condition]. This example is known as the projective plane of order three.

Vector space construction

Though the line at infinity of the extended real plane may appear to have a different nature than the other lines of that projective plane, this is not the case. Another construction of the same projective plane shows that no line can be distinguished from any other. In this construction, each "point" of the real projective plane is the one-dimensional subspace through the origin in a 3-dimensional vector space, and a "line" in the projective plane arises from a plane through the origin in the 3-space. This idea can be generalized and made more precise as follows.
Let K be any division ring. Let K3 denote the set of all triples x = of elements of K. For any nonzero x in K3, the minimal subspace of K3 containing x is the subset
of K3. Similarly, let x and y be linearly independent elements of K3, meaning that implies that. The minimal subspace of K3 containing x and y is the subset
of K3. This 2-dimensional subspace contains various 1-dimensional subspaces through the origin that may be obtained by fixing k and m and taking the multiples of the resulting vector. Different choices of k and m that are in the same ratio will give the same line.
The projective plane over K, denoted PG or KP2, has a set of points consisting of all the 1-dimensional subspaces in K3. A subset L of the points of PG is a line in PG if there exists a 2-dimensional subspace of K3 whose set of 1-dimensional subspaces is exactly L.
Verifying that this construction produces a projective plane is usually left as a linear algebra exercise.
An alternate view of this construction is as follows. The points of this projective plane are the equivalence classes of the set modulo the equivalence relation
Lines in the projective plane are defined exactly as above.
The coordinates of a point in PG are called homogeneous coordinates. Each triple represents a well-defined point in PG, except for the triple, which represents no point. Each point in PG, however, is represented by many triples.
If K is a topological space, then KP2, inherits a topology via the product, subspace, and quotient topologies.

Classical examples

The real projective plane RP2, arises when K is taken to be the real numbers, R. As a closed, non-orientable real 2-manifold, it serves as a fundamental example in topology.
In this construction consider the unit sphere centered at the origin in R3. Each of the R3 lines in this construction intersects the sphere at two antipodal points. Since the R3 line represents a point of RP2, we will obtain the same model of RP2 by identifying the antipodal points of the sphere. The lines of RP2 will be the great circles of the sphere after this identification of antipodal points. This description gives the standard model of elliptic geometry.
The complex projective plane CP2, arises when K is taken to be the complex numbers, C. It is a closed complex 2-manifold, and hence a closed, orientable real 4-manifold. It and projective planes over other fields serve as fundamental examples in algebraic geometry.
The quaternionic projective plane HP2 is also of independent interest.

Finite field planes

By Wedderburn's Theorem, a finite division ring must be commutative and so a field. Thus, the finite examples of this construction are known as "field planes". Taking K to be the finite field of q = pn elements with prime p produces a projective plane of q2 + q + 1 points. The field planes are usually denoted by PG where PG stands for projective geometry, the "2" is the dimension and q is called the order of the plane. The Fano plane, discussed below, is denoted by PG. The [|third example above] is the projective plane PG.
The Fano plane is the projective plane arising from the field of two elements. It is the smallest projective plane, with only seven points and seven lines. In the figure at right, the seven points are shown as small black balls, and the seven lines are shown as six line segments and a circle. However, one could equivalently consider the balls to be the "lines" and the line segments and circle to be the "points" – this is an example of duality in the projective plane: if the lines and points are interchanged, the result is still a projective plane. A permutation of the seven points that carries collinear points to collinear points is called a collineation or symmetry of the plane. The collineations of a geometry form a group under composition, and for the Fano plane this group = PGL) has 168 elements.

Desargues' theorem and Desarguesian planes

The theorem of Desargues is universally valid in a projective plane if and only if the plane can be constructed from a three-dimensional vector space over a skewfield as above. These planes are called Desarguesian planes, named after Girard Desargues. The real projective plane and the projective plane of order 3 given above are examples of Desarguesian projective planes. The projective planes that can not be constructed in this manner are called non-Desarguesian planes, and the Moulton plane given above is an example of one. The PG notation is reserved for the Desarguesian planes. When K is a field, a very common case, they are also known as field planes and if the field is a finite field they can be called Galois planes.

Subplanes

A subplane of a projective plane is a subset of the points of the plane which themselves form a projective plane with the same incidence relations.
proves the following theorem. Let Π be a finite projective plane of order N with a proper subplane Π0 of order M. Then either N = M2 or NM2 + M.
When N is a square, subplanes of order are called Baer subplanes. Every point of the plane lies on a line of a Baer subplane and every line of the plane contains a point of the Baer subplane.
In the finite Desarguesian planes PG, the subplanes have orders which are the orders of the subfields of the finite field GF, that is, pi where i is a divisor of n. In non-Desarguesian planes however, Bruck's theorem gives the only information about subplane orders. The case of equality in the inequality of this theorem is not known to occur. Whether or not there exists a subplane of order M in a plane of order N with M2 + M = N is an open question. If such subplanes existed there would be projective planes of composite order.

Fano subplanes

A Fano subplane is a subplane isomorphic to PG, the unique projective plane of order 2.
If you consider a quadrangle in this plane, the points determine six of the lines of the plane. The remaining three points are the points where the lines that do not intersect at a point of the quadrangle meet. The seventh line consists of all the diagonal points.
In finite desarguesian planes, PG, Fano subplanes exist if and only if q is even. The situation in non-desarguesian planes is unsettled. They could exist in any non-desarguesian plane of order greater than 6, and indeed, they have been found in all non-desarguesian planes in which they have been looked for.
An open question is: Does every non-desarguesian plane contain a Fano subplane?
A theorem concerning Fano subplanes due to is:

Affine planes

Projectivization of the Euclidean plane produced the real projective plane. The inverse operation — starting with a projective plane, remove one line and all the points incident with that line — produces an affine plane.

Definition

More formally an affine plane consists of a set of lines and a set of points, and a relation between points and lines called incidence, having the following properties:

  1. Given any two distinct points, there is exactly one line incident with both of them.
  2. Given any line l and any point P not incident with l, there is exactly one line incident with P that does not meet l.
  3. There are four points such that no line is incident with more than two of them.

The second condition means that there are parallel lines and is known as Playfair's axiom. The expression "does not meet" in this condition is shorthand for "there does not exist a point incident with both lines."
The Euclidean plane and the Moulton plane are examples of infinite affine planes. A finite projective plane will produce a finite affine plane when one of its lines and the points on it are removed. The order of a finite affine plane is the number of points on any of its lines. The affine planes which arise from the projective planes PG are denoted by AG.
There is a projective plane of order N if and only if there is an affine plane of order N. When there is only one affine plane of order N there is only one projective plane of order N, but the converse is not true. The affine planes formed by the removal of different lines of the projective plane will be isomorphic if and only if the removed lines are in the same orbit of the collineation group of the projective plane. These statements hold for infinite projective planes as well.

Construction of projective planes from affine planes

The affine plane K2 over K embeds into KP2 via the map which sends affine coordinates to homogeneous coordinates,
The complement of the image is the set of points of the form. From the point of view of the embedding just given, these points are the points at infinity. They constitute a line in KP2 — namely, the line arising from the plane
in K3 — called the line at infinity. The points at infinity are the "extra" points where parallel lines intersect in the construction of the extended real plane; the point is where all lines of slope x2 / x1 intersect. Consider for example the two lines
in the affine plane K2. These lines have slope 0 and do not intersect. They can be regarded as subsets of KP2 via the embedding above, but these subsets are not lines in KP2. Add the point to each subset; that is, let
These are lines in KP2; ū arises from the plane
in K3, while ȳ arises from the plane
The projective lines ū and ȳ intersect at. In fact, all lines in K2 of slope 0, when projectivized in this manner, intersect at in KP2.
The embedding of K2 into KP2 given above is not unique. Each embedding produces its own notion of points at infinity. For example, the embedding
has as its complement those points of the form, which are then regarded as points at infinity.
When an affine plane does not have the form of K2 with K a division ring, it can still be embedded in a projective plane, but the construction used above does not work. A commonly used method for carrying out the embedding in this case involves expanding the set of affine coordinates and working in a more general "algebra".

Generalized coordinates

One can construct a coordinate "ring"—a so-called planar ternary ring —corresponding to any projective plane. A planar ternary ring need not be a field or division ring, and there are many projective planes that are not constructed from a division ring. They are called non-Desarguesian projective planes and are an active area of research. The Cayley plane, a projective plane over the octonions, is one of these because the octonions do not form a division ring.
Conversely, given a planar ternary ring, a projective plane can be constructed. The relationship is not one to one. A projective plane may be associated with several non-isomorphic planar ternary rings. The ternary operator T can be used to produce two binary operators on the set R, by:
The ternary operator is linear if T = x•m + k. When the set of coordinates of a projective plane actually form a ring, a linear ternary operator may be defined in this way, using the ring operations on the right, to produce a planar ternary ring.
Algebraic properties of this planar ternary coordinate ring turn out to correspond to geometric incidence properties of the plane. For example, Desargues' theorem corresponds to the coordinate ring being obtained from a division ring, while Pappus's theorem corresponds to this ring being obtained from a commutative field. A projective plane satisfying Pappus's theorem universally is called a Pappian plane. Alternative, not necessarily associative, division algebras like the octonions correspond to Moufang planes.
There is no known purely geometric proof of the purely geometric statement that Desargues' theorem implies Pappus' theorem in a finite projective plane. The most common proof uses coordinates in a division ring and Wedderburn's theorem that finite division rings must be commutative; give a proof that uses only more "elementary" algebraic facts about division rings.
To describe a finite projective plane of order N using non-homogeneous coordinates and a planar ternary ring:
On these points, construct the following lines:
For example, for N=2 we can use the symbols associated with the finite field of order 2. The ternary operation defined by T = xm + k with the operations on the right being the multiplication and addition in the field yields the following:

Degenerate planes

Degenerate planes do not fulfill the third condition in the [|definition] of a projective plane. They are not structurally complex enough to be interesting in their own right, but from time to time they arise as special cases in general arguments. There are seven degenerate planes according to. They are:
  1. the empty set;
  2. a single point, no lines;
  3. a single line, no points;
  4. a single point, a collection of lines, the point is incident with all of the lines;
  5. a single line, a collection of points, the points are all incident with the line;
  6. a point P incident with a line m, an arbitrary collection of lines all incident with P and an arbitrary collection of points all incident with m;
  7. a point P not incident with a line m, an arbitrary collection of lines all incident with P and all the points of intersection of these lines with m.
These seven cases are not independent, the fourth and fifth can be considered as special cases of the sixth, while the second and third are special cases of the fourth and fifth respectively. The special case of the seventh plane with no additional lines can be seen as an eighth plane. All the cases can therefore be organized into two families of degenerate planes as follows :
1) For any number of points P1,..., Pn, and lines L1,..., Lm,
2) For any number of points P1,..., Pn, and lines L1,..., Ln,

Collineations

A collineation of a projective plane is a bijective map of the plane to itself which maps points to points and lines to lines that preserves incidence, meaning that if σ is a bijection and point P is on line m, then Pσ is on mσ.
If σ is a collineation of a projective plane, a point P with P = Pσ is called a fixed point of σ, and a line m with m = mσ is called a fixed line of σ. The points on a fixed line need not be fixed points, their images under σ are just constrained to lie on this line. The collection of fixed points and fixed lines of a collineation form a closed configuration, which is a system of points and lines that satisfy the first two but not necessarily the third condition in the definition of a projective plane. Thus, the fixed point and fixed line structure for any collineation either form a projective plane by themselves, or a [|degenerate plane]. Collineations whose fixed structure forms a plane are called planar collineations.

Homography

A homography of PG is a collineation of this type of projective plane which is a linear transformation of the underlying vector space. Using homogeneous coordinates they can be represented by invertible 3 × 3 matrices over K which act on the points of PG by y = M xT, where x and y are points in K3 and M is an invertible 3 × 3 matrix over K. Two matrices represent the same projective transformation if one is a constant multiple of the other. Thus the group of projective transformations is the quotient of the general linear group by the scalar matrices called the projective linear group.
Another type of collineation of PG is induced by any automorphism of K, these are called automorphic collineations. If α is an automorphism of K, then the collineation given by → is an automorphic collineation. The fundamental theorem of projective geometry says that all the collineations of PG are compositions of homographies and automorphic collineations. Automorphic collineations are planar collineations.

Plane duality

A projective plane is defined axiomatically as an incidence structure, in terms of a set P of points, a set L of lines, and an incidence relation I that determines which points lie on which lines. As P and L are only sets one can interchange their roles and define a plane dual structure.
By interchanging the role of "points" and "lines" in
we obtain the dual structure
where I* is the inverse relation of I.
In a projective plane a statement involving points, lines and incidence between them that is obtained from another such statement by interchanging the words "point" and "line" and making whatever grammatical adjustments that are necessary, is called the plane dual statement of the first. The plane dual statement of "Two points are on a unique line." is "Two lines meet at a unique point." Forming the plane dual of a statement is known as dualizing the statement.
If a statement is true in a projective plane C, then the plane dual of that statement must be true in the dual plane C*. This follows since dualizing each statement in the proof "in C" gives a statement of the proof "in C*."
In the projective plane C, it can be shown that there exist four lines, no three of which are concurrent. Dualizing this theorem and the first two axioms in the definition of a projective plane shows that the plane dual structure C* is also a projective plane, called the dual plane of C.
If C and C* are isomorphic, then C is called self-dual. The projective planes PG for any division ring K are self-dual. However, there are non-Desarguesian planes which are not self-dual, such as the Hall planes and some that are, such as the Hughes planes.
The Principle of Plane Duality says that dualizing any theorem in a self-dual projective plane C produces another theorem valid in C.

Correlations

A duality is a map from a projective plane C = to its dual plane C* = which preserves incidence. That is, a duality σ will map points to lines and lines to points in such a way that if a point Q is on a line m then Qσ I* mσmσ I Qσ. A duality which is an isomorphism is called a correlation. If a correlation exists then the projective plane C is self-dual.
In the special case that the projective plane is of the PG type, with K a division ring, a duality is called a reciprocity. These planes are always self-dual. By the fundamental theorem of projective geometry a reciprocity is the composition of an automorphic function of K and a homography. If the automorphism involved is the identity, then the reciprocity is called a projective correlation.
A correlation of order two is called a polarity. If a correlation φ is not a polarity then φ2 is a nontrivial collineation.

Finite projective planes

It can be shown that a projective plane has the same number of lines as it has points. Thus, for every finite projective plane there is an integer N ≥ 2 such that the plane has
The number N is called the order of the projective plane.
The projective plane of order 2 is called the Fano plane. See also the article on finite geometry.
Using the vector space construction with finite fields there exists a projective plane of order N = pn, for each prime power pn. In fact, for all known finite projective planes, the order N is a prime power.
The existence of finite projective planes of other orders is an open question. The only general restriction known on the order is the Bruck-Ryser-Chowla theorem that if the order N is congruent to 1 or 2 mod 4, it must be the sum of two squares. This rules out N = 6. The next case N = 10 has been ruled out by massive computer calculations. Nothing more is known; in particular, the question of whether there exists a finite projective plane of order N = 12 is still open.
Another longstanding open problem is whether there exist finite projective planes of prime order which are not finite field planes.
A projective plane of order N is a Steiner S system
. Conversely, one can prove that all Steiner systems of this form are projective planes.
The number of mutually orthogonal Latin squares of order N is at most N − 1. N − 1 exist if and only if there is a projective plane of order N.
While the classification of all projective planes is far from complete, results are known for small orders:
Projective planes may be thought of as projective geometries of "geometric" dimension two. Higher-dimensional projective geometries can be defined in terms of incidence relations in a manner analogous to the definition of a projective plane. These turn out to be "tamer" than the projective planes since the extra degrees of freedom permit Desargues' theorem to be proved geometrically in the higher-dimensional geometry. This means that the coordinate "ring" associated to the geometry must be a division ring K, and the projective geometry is isomorphic to the one constructed from the vector space Kd+1, i.e. PG. As in the construction given earlier, the points of the d-dimensional projective space PG are the lines through the origin in Kd + 1 and a line in PG corresponds to a plane through the origin in Kd + 1. In fact, each i-dimensional object in PG, with i < d, is an -dimensional vector subspace of Kd + 1. The projective spaces in turn generalize to the Grassmannian spaces.
It can be shown that if Desargues' theorem holds in a projective space of dimension greater than two, then it must also hold in all planes that are contained in that space. Since there are projective planes in which Desargues' theorem fails, these planes can not be embedded in a higher-dimensional projective space. Only the planes from the vector space construction PG can appear in projective spaces of higher dimension. Some disciplines in mathematics restrict the meaning of projective plane to only this type of projective plane since otherwise general statements about projective spaces would always have to mention the exceptions when the geometric dimension is two.