Abstract
Generally, the linear topological spaces successfully generate Tychonoff product topology in lower dimensions. This paper proposes the construction and analysis of a multidimensional topological space based on the Cartesian product of complex and real spaces in continua. The geometry of the resulting space includes a real plane with planar rotational symmetry. The basis of topological space contains cylindrical open sets. The projection of a cylindrically symmetric continuous function in the topological space onto a complex planar subspace maintains surjectivity. The proposed construction shows that there are two projective topological subspaces admitting non-uniform scaling, where the complex subspace scales at a higher order than the real subspace generating a quasinormed space. Furthermore, the space can be equipped with commutative and finite translations on complex and real subspaces. The complex subspace containing the origin of real subspace supports associativity under finite translation and multiplication operations in a combination. The analysis of the formation of a multidimensional topological group in the space requires first-order translation in complex subspace, where the identity element is located on real plane in the space. Moreover, the complex translation of identity element is restricted within the corresponding real plane. The topological projections support additive group structures in real one-dimensional as well as two-dimensional complex subspaces. Furthermore, a multiplicative group is formed in the real projective space. The topological properties, such as the compactness and homeomorphism of subspaces under various combinations of projections and translations, are analyzed. It is considered that the complex subspace is holomorphic in nature.
Highlights
The topological spaces have a wide variety of structures and associated properties
The conditions for the existence of a group in a topological space are determined by the nature of algebraic operations in the space along with geometry
This paper proposes the construction and analysis of a non-uniformly scalable multidimensional topological space, which is hybrid in nature
Summary
The topological spaces have a wide variety of structures and associated properties. In view of category theory, a finite number of elementary axioms is sufficient to formulate the category of topological spaces as well as continuous mappings [1]. The topological spaces can be classified based on a set of properties, such as separability and path-connectedness. The concept of separable connectedness generalizes the path-connectedness property of topological spaces [2]. The two interesting varieties of spaces are complex spaces and normed linear spaces, which admit topological as well as algebraic structures. In the following subsections (Sections 1.1 and 1.2), brief descriptions about the topology of complex analytic spaces and normed linear spaces are presented.
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.