Difference between revisions of "Vector axiomatics"
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''vector point axiomatics'' | ''vector point axiomatics'' | ||
− | The axiomatics of an $ n $- | + | The axiomatics of an $ n $-dimensional affine space $ R ^ {n} $, |
− | dimensional affine space $ R ^ {n} $, | ||
the basic concepts of which are "point" and "vector" ; the connection between them is realized by establishing a correspondence between a pair of points and a uniquely defined vector. The following axioms are valid. | the basic concepts of which are "point" and "vector" ; the connection between them is realized by establishing a correspondence between a pair of points and a uniquely defined vector. The following axioms are valid. | ||
I) The set of all vectors of $ R ^ {n} $ | I) The set of all vectors of $ R ^ {n} $ | ||
− | is an $ n $- | + | is an $ n $-dimensional vector space $ V ^ {n} $. |
− | dimensional vector space $ V ^ {n} $. | ||
II) Any two points $ A $ | II) Any two points $ A $ | ||
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applied at it, while the point $ B $ | applied at it, while the point $ B $ | ||
which is uniquely defined by the pair $ A, \mathbf u $ | which is uniquely defined by the pair $ A, \mathbf u $ | ||
− | is said to be the end of the vector $ \mathbf u $( | + | is said to be the end of the vector $ \mathbf u $ (applied at $ A $). |
− | applied at $ A $). | ||
An arbitrarily given vector $ \mathbf u $ | An arbitrarily given vector $ \mathbf u $ |
Latest revision as of 06:40, 9 May 2022
vector point axiomatics
The axiomatics of an $ n $-dimensional affine space $ R ^ {n} $, the basic concepts of which are "point" and "vector" ; the connection between them is realized by establishing a correspondence between a pair of points and a uniquely defined vector. The following axioms are valid.
I) The set of all vectors of $ R ^ {n} $ is an $ n $-dimensional vector space $ V ^ {n} $.
II) Any two points $ A $ and $ B $, given in a definite order, define a unique vector $ \mathbf u $.
III) If a vector $ \mathbf u $ and a point $ A $ are arbitrary given, there exists only one point $ B $ such that $ \mathbf u = \vec{AB} $.
IV) If $ \mathbf u _ {1} = \vec{AB} $ and $ \mathbf u _ {2} = \vec{BC} $, then $ \mathbf u _ {1} + \mathbf u _ {2} = \vec{AC} $.
The pair "point A and vector u" is called "the vector u applied at the point A" (or "fixed at that point" ); the point $ A $ itself is said to be the origin of the vector $ \mathbf u $ applied at it, while the point $ B $ which is uniquely defined by the pair $ A, \mathbf u $ is said to be the end of the vector $ \mathbf u $ (applied at $ A $).
An arbitrarily given vector $ \mathbf u $ generates a completely defined one-to-one mapping of the set of all points of $ R ^ {n} $ onto itself. This mapping, which is known as the translation of $ R ^ {n} $ over the vector $ \mathbf u $, relates each point $ A \in R ^ {n} $ to the end $ B $ of the vector $ \mathbf u = \vec{AB} $.
References
[1] | P.S. Aleksandrov, "Lectures on analytical geometry" , Moscow (1968) (In Russian) |
[2] | P.S. Alexandroff [P.S. Aleksandrov] (ed.) et al. (ed.) , Enzyklopaedie der Elementarmathematik , 4. Geometrie , Deutsch. Verlag Wissenschaft. (1967) (Translated from Russian) |
Comments
Cf. also (the editorial comments to) Vector or [a1].
References
[a1] | M. Berger, "Geometry" , I , Springer (1987) pp. Chapt. 2 |
Vector axiomatics. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Vector_axiomatics&oldid=49134