Real projective line

Real projective line

In real analysis, the real projective line (also called the one-point compactification of the real line, or the "projectively extended real numbers"), is the set mathbb{R}cup{infty}, also denoted by widehat{mathbb{R and by mathbb{R}P^1.

The symbol infty represents the point at infinity, an idealized point that bridges the two "ends" of the real line.

Dividing by zero

Unlike most mathematical models of the intuitive concept of 'number', this structure allows division by zero:

:frac{a}{0} = infty

for nonzero "a". This structure, however is not a field, and division does not retain its original algebraic meaning in it. The geometric interpretation is this: a vertical line has "infinite" slope.

Extensions of the real line

The real projective line extends the field of real numbers in the same way that the Riemann sphere extends the field of complex numbers, by adding a single point called conventionally ∞.

Compare the extended real number line (also called the two-point compactification of the real line), which does distinguish between +infty and -infty.

Order

The order relation cannot be extended to widehat{mathbb{R in a meaningful way. Given a real number "a", there is no convincing reason to decide that a > infty or that a < infty. Since infty can't be compared with any of the other elements, there's no point in using this relation at all. However, order is used to make definitions in widehat{mathbb{R that are based on the properties of reals.

Geometry

Fundamental to the idea that &infin; is a point "no different from any other" is the way the real projective line is a homogeneous space, in fact homeomorphic to a circle. For example the general linear group of 2×2 real invertible matrices has a transitive action on it. The group action may be expressed by Möbius transformations, with the understanding that when the denominator of the linear fractional transformation is 0, the image is &infin;.

The detailed analysis of the action shows that for any three distinct points "P", "Q" and "R", there is a linear fractional transformation taking "P" to 0, "Q" to 1, and "R" to &infin;. This cannot be extended to 4-tuples of points, because the cross-ratio is invariant.

The terminology projective line is appropriate, because the points are in 1-1 correspondence with one-dimensional linear subspaces of R2.

Arithmetic operations

Motivation for arithmetic operations

The arithmetic operations in this space are an extension of the same operations on reals. The motivation for the new definitions is the limits of functions of real numbers.

Arithmetic operations which are defined

:egin{align} \a + infty = infty + a & = infty, & quad a in mathbb{R} \a - infty = infty - a & = infty, & quad a in mathbb{R} \a cdot infty = infty cdot a & = infty, & quad a in mathbb{R}, a eq 0 \infty cdot infty & = infty \frac{a}{infty} & = 0, & quad a in mathbb{R} \frac{infty}{a} & = infty, & quad a in mathbb{R} \frac{a}{0} & = infty, & quad a in mathbb{R}, a eq 0end{align}

Arithmetic operations which are left undefined

The following cannot be motivated by considering limits of real functions, and any definition of them would require us to give up additional algebraic properties. Therefore, they are left undefined::egin{align}& infty + infty \& infty - infty \& infty cdot 0 \& 0 cdot infty \& frac{infty}{infty} \& frac{0}{0}end{align}

Algebraic properties

"The following equalities mean: Either both sides are undefined, or both sides are defined and equal." This is true for any a, b, c in widehat{mathbb{R.:egin{align}(a + b) + c & = a + (b + c) \a + b & = b + a \(a cdot b) cdot c & = a cdot (b cdot c) \a cdot b & = b cdot a \a cdot infty & = frac{a}{0} \end{align}The following is true whenever the right-hand side is defined, for any a, b, c in widehat{mathbb{R.:egin{align}a cdot (b + c) & = a cdot b + a cdot c \a & = (frac{a}{b}) cdot b & = ,,& frac{(a cdot b)}{b} \a & = (a + b) - b & = ,,& (a - b) + bend{align}In general, all laws of arithmetic are valid as long as all the occurring expressions are defined.

Intervals and topology

The concept of an interval can be extended to widehat{mathbb{R. However, since it is an unordered set, the interval has a slightly different meaning. The definitions for closed intervals are as follows (it is assumed that a, b in mathbb{R}, a < b):

:egin{align}left [a, a ight] & = lbrace a brace \left [a, b ight] & = lbrace x vert x in mathbb{R}, a leq x leq b brace \left [a, infty ight] & = lbrace x vert x in mathbb{R}, a leq x brace cup lbrace infty brace \left [b, a ight] & = lbrace x vert x in mathbb{R}, b leq x brace cup lbrace infty brace cup lbrace x vert x in mathbb{R}, x leq a brace \left [infty, a ight] & = lbrace infty brace cup lbrace x vert x in mathbb{R}, x leq a brace \left [infty, infty ight] & = lbrace infty brace end{align}

The corresponding open and half-open intervals are obtained by removing the endpoints.

widehat{mathbb{R itself is also an interval, but cannot be represented with this bracket notation.

The open intervals as base define a topology on widehat{mathbb{R. Sufficient for a base are the finite open intervals and the intervals [b, a] = {x | x in mathbb{R}, b < x} cup {infty} cup {x | x in mathbb{R}, x < a}.

As said, the topology is homeomorphic to a circle. Thus it is metrizable corresponding (for a given homeomorphism) to the ordinary metric on this circle (either measured straight or along the circle). There is no metric which is an extension of the ordinary metric on R.

Interval arithmetic

Interval arithmetic is trickier in widehat{mathbb{R than in mathbb{R}. However, the result of an arithmetic operation on intervals is always an interval. In particular, we have, for every a, b in widehat{mathbb{R::x in [a, b] iff frac{1}{x} in left [frac{1}{b}, frac{1}{a} ight ] which is true even when the intervals involved include 0.

Calculus

The tools of calculus can be used to analyze functions of widehat{mathbb{R. The definitions are motivated by the topology of this space.

Neighbourhoods

Let x in widehat{mathbb{R, A subseteq widehat{mathbb{R.
*A is a neighbourhood of "x", if and only if "A" contains an open interval "B" and x in B.
*A is a right-sided neighbourhood of x, if and only if there is y in widehat{mathbb{R, y > x such that "A" contains [x, y).
*A is a left-sided neighbourhood of x, if and only if there is y in widehat{mathbb{R, y < x such that "A" contains (y, x] .
*A is a (right-sided, left-sided) ml|Neighbourhood_(mathematics)|Punctured_neighbourhood|punctured neighbourhood of "x", if and only if there is B subseteq widehat{mathbb{R such that "B" is a (right-sided, left-sided) neighbourhood of x, and A = B setminus {x}.

Limits

Basic definitions of limits

Let f : widehat{mathbb{R o widehat{mathbb{R, p in widehat{mathbb{R, L in widehat{mathbb{R.

The limit of "f(x)" as "x" approaches "p" is "L", denoted:lim_{x o p}{f(x)} = Lif and only if for every neighbourhood "A" of "L", there is a punctured neighbourhood "B" of "p", such that x in B implies f(x) in A.

The one-sided limit of "f(x)" as "x" approaches "p" from the right (left) is "L", denoted:lim_{x o p^{+{f(x)} = L left (lim_{x o p^{-{f(x)} = L ight )if and only if for every neighbourhood "A" of "L", there is a right-sided (left-sided) punctured neighbourhood "B" of "p", such that x in B implies f(x) in A.

It can be shown that lim_{x o p}{f(x)} = L if and only if both lim_{x o p^{+{f(x)} = L and lim_{x o p^{-{f(x)} = L.

Comparison with limits in mathbb{R}

The definitions given above can be compared with the usual definitions of limits of real functions. In the following statements, p, L in mathbb{R}, the first limit is as defined above, and the second limit is in the usual sense:
*lim_{x o p}{f(x)} = L is equivalent to lim_{x o p}{f(x)} = L.
*lim_{x o infty^{+{f(x)} = L is equivalent to lim_{x o -infty}{f(x)} = L.
*lim_{x o infty^{-{f(x)} = L is equivalent to lim_{x o +infty}{f(x)} = L.
*lim_{x o p}{f(x)} = infty is equivalent to lim_{x o p} = +infty.

Extended definition of limits

Let A subseteq widehat{mathbb{R. Then "p" is a limit point of "A" if and only if every neighbourhood of "p" includes a point y in A such that y eq x.

Let f : widehat{mathbb{R o widehat{mathbb{R, A subseteq widehat{mathbb{R, L in widehat{mathbb{R, p in widehat{mathbb{R, "p" a limit point of "A". The limit of "f(x)" as "x" approaches "p" through "A" is "L", if and only if for every neighbourhood "B" of "L", there is a punctured neighbourhood "C" of "p", such that x in A cap C implies f(x) in B.

This corresponds to the regular topological definition of continuity, applied to the subspace topology on Acup lbrace p brace, and the restriction of "f" to Acup lbrace p brace.

Continuity

Let

: f : widehat{mathbb{R o widehat{mathbb{R,quad p in widehat{mathbb{R.

"f" is continuous at "p" if and only if "f" is defined at "p" and:

:lim_{x o p}{f(x)} = f(p).

Let

: f : widehat{mathbb{R o widehat{mathbb{R,quad A subseteq widehat{mathbb{R.

"f" is continuous in "A" if and only if for every p in A, "f" is defined at "p" and the limit of "f"("x") as "x" approaches "p" through "A" is "f"("p").

An interesting feature is that every rational function "P"("x")/"Q"("x"), where "P"("x") and "Q"("x") have no common factor, is continuous in widehat{mathbb{R. Also, If tan is extended so that

: anleft(frac{pi}{2} + npi ight) = infty ext{ for }n in mathbb{Z},

then tan is continuous in widehat{mathbb{R. However, many elementary functions, such as trigonometric and exponential functions, are discontinuous at infty. For example, sin is continuous in mathbb{R} but discontinuous at infty.

Thus 1/"x" is continuous on widehat{mathbb{R but not on the affinely extended real number system R. Conversely, the function arctan can be extended continuously on R, but not on widehat{mathbb{R.

See also

* Real projective plane
* Complex projective plane

External links

* [http://mathworld.wolfram.com/ProjectivelyExtendedRealNumbers.html Projectively Extended Real Numbers -- From Mathworld]


Wikimedia Foundation. 2010.

Игры ⚽ Поможем написать курсовую

Look at other dictionaries:

  • Projective line — In mathematics, a projective line is a one dimensional projective space. The projective line over a field K , denoted P1( K ), may be defined as the set of one dimensional subspaces of the two dimensional vector space K 2 (it does carry other… …   Wikipedia

  • Real projective space — In mathematics, real projective space, or RP n is the projective space of lines in R n +1. It is a compact, smooth manifold of dimension n , and a special case of a Grassmannian.ConstructionAs with all projective spaces, RP n is formed by taking… …   Wikipedia

  • Real projective plane — In mathematics, the real projective plane is the space of lines in R3 passing through the origin. It is a non orientable two dimensional manifold, that is, a surface, that has basic applications to geometry, but which cannot be embedded in our… …   Wikipedia

  • Extended real number line — Positive infinity redirects here. For the band, see Positive Infinity. In mathematics, the affinely extended real number system is obtained from the real number system R by adding two elements: +∞ and −∞ (read as positive infinity and negative… …   Wikipedia

  • Projective space — In mathematics a projective space is a set of elements constructed from a vector space such that a distinct element of the projective space consists of all non zero vectors which are equal up to a multiplication by a non zero scalar. A formal… …   Wikipedia

  • Projective harmonic conjugates — is defined by the following harmonic construction::“Given three collinear points A, B, C, let L be a point not lying on their join and let any line through C met LA, LB at M, N respectively. If AN and BM met at K , and LK meets AB at D , then D… …   Wikipedia

  • Real number — For the real numbers used in descriptive set theory, see Baire space (set theory). For the computing datatype, see Floating point number. A symbol of the set of real numbers …   Wikipedia

  • Projective geometry — is a non metrical form of geometry, notable for its principle of duality. Projective geometry grew out of the principles of perspective art established during the Renaissance period, and was first systematically developed by Desargues in the 17th …   Wikipedia

  • Projective plane — See real projective plane and complex projective plane, for the cases met as manifolds of respective dimension 2 and 4 In mathematics, a projective plane has two possible definitions, one of them coming from linear algebra, and another (which is… …   Wikipedia

  • Line bundle — In mathematics, a line bundle expresses the concept of a line that varies from point to point of a space. For example a curve in the plane having a tangent line at each point determines a varying line: the tangent bundle is a way of organising… …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”