K-cell (mathematics)

Last updated September 23, 2023

A $k$ -cell is a higher-dimensional version of a rectangle or rectangular solid. It is the Cartesian product of $k$ closed intervals on the real line.^[1] This means that a $k$ -dimensional rectangular solid has each of its edges equal to one of the closed intervals used in the definition. The $k$ intervals need not be identical. For example, a 2-cell is a rectangle in $\mathbb {R} ^{2}$ such that the sides of the rectangles are parallel to the coordinate axes. Every $k$ -cell is compact.^[2]^[3]

Formal definition

For every integer $i$ from $1$ to $k$ , let $a_{i}$ and $b_{i}$ be real numbers such that for all $a_{i}<b_{i}$ . The set of all points $x=(x_{1},\dots ,x_{k})$ in $\mathbb {R} ^{k}$ whose coordinates satisfy the inequalities $a_{i}\leq x_{i}\leq b_{i}$ is a $k$ -cell.^[4]

Intuition

A $k$ -cell of dimension $k\leq 3$ is especially simple. For example, a 1-cell is simply the interval $[a,b]$ with $a<b$ . A 2-cell is the rectangle formed by the Cartesian product of two closed intervals, and a 3-cell is a rectangular solid.

The sides and edges of a $k$ -cell need not be equal in (Euclidean) length; although the unit cube (which has boundaries of equal Euclidean length) is a 3-cell, the set of all 3-cells with equal-length edges is a strict subset of the set of all 3-cells.

Notes

Related Research Articles

Euclidean space is the fundamental space of geometry, intended to represent physical space. Originally, that is, in Euclid's Elements, it was the three-dimensional space of Euclidean geometry, but in modern mathematics there are Euclidean spaces of any positive integer dimension n, which are called Euclidean n-spaces when one wants to specify their dimension. For n equal to one or two, they are commonly called respectively Euclidean lines and Euclidean planes. The qualifier "Euclidean" is used to distinguish Euclidean spaces from other spaces that were later considered in physics and modern mathematics.

In measure theory, a branch of mathematics, the Lebesgue measure, named after French mathematician Henri Lebesgue, is the standard way of assigning a measure to subsets of n-dimensional Euclidean space. For n = 1, 2, or 3, it coincides with the standard measure of length, area, or volume. In general, it is also called n-dimensional volume, n-volume, or simply volume. It is used throughout real analysis, in particular to define Lebesgue integration. Sets that can be assigned a Lebesgue measure are called Lebesgue-measurable; the measure of the Lebesgue-measurable set A is here denoted by λ(A).

Length is a measure of distance. In the International System of Quantities, length is a quantity with dimension distance. In most systems of measurement a base unit for length is chosen, from which all other units are derived. In the International System of Units (SI) system the base unit for length is the metre.

In mathematics, the branch of real analysis studies the behavior of real numbers, sequences and series of real numbers, and real functions. Some particular properties of real-valued sequences and functions that real analysis studies include convergence, limits, continuity, smoothness, differentiability and integrability.

In mathematics, a topological vector space is one of the basic structures investigated in functional analysis. A topological vector space is a vector space that is also a topological space with the property that the vector space operations are also continuous functions. Such a topology is called a vector topology and every topological vector space has a uniform topological structure, allowing a notion of uniform convergence and completeness. Some authors also require that the space is a Hausdorff space. One of the most widely studied categories of TVSs are locally convex topological vector spaces. This article focuses on TVSs that are not necessarily locally convex. Banach spaces, Hilbert spaces and Sobolev spaces are other well-known examples of TVSs.

In mathematics, a (real) interval is the set of all real numbers lying between two fixed endpoints with no "gaps". Each endpoint is either a real number or positive or negative infinity, indicating the interval extends without a bound. An interval can contain neither endpoint, either endpoint, or both endpoints.

<span class="mw-page-title-main">Ball (mathematics)</span> Volume space bounded by a sphere

In mathematics, a ball is the solid figure bounded by a sphere; it is also called a solid sphere. It may be a closed ball or an open ball.

In mathematics, particularly linear algebra, an orthonormal basis for an inner product space V with finite dimension is a basis for $whose vectors are orthonormal, that is, they are all unit vectors and orthogonal to each other. For example, the standard basis for a Euclidean space is an orthonormal basis, where the relevant inner product is the dot product of vectors. The image of the standard basis under a rotation or reflection is also orthonormal, and every orthonormal basis for arises in this fashion.$

<span class="mw-page-title-main">Packing problems</span> Problems which attempt to find the most efficient way to pack objects into containers

Packing problems are a class of optimization problems in mathematics that involve attempting to pack objects together into containers. The goal is to either pack a single container as densely as possible or pack all objects using as few containers as possible. Many of these problems can be related to real-life packaging, storage and transportation issues. Each packing problem has a dual covering problem, which asks how many of the same objects are required to completely cover every region of the container, where objects are allowed to overlap.

In mathematics, an extreme point of a convex set $in a real or complex vector space is a point in which does not lie in any open line segment joining two points of In linear programming problems, an extreme point is also called vertex or corner point of$

In mathematics, a norm is a function from a real or complex vector space to the non-negative real numbers that behaves in certain ways like the distance from the origin: it commutes with scaling, obeys a form of the triangle inequality, and is zero only at the origin. In particular, the Euclidean distance in a Euclidean space is defined by a norm on the associated Euclidean vector space, called the Euclidean norm, the 2-norm, or, sometimes, the magnitude of the vector. This norm can be defined as the square root of the inner product of a vector with itself.

In mathematics, the real coordinate space of dimension $n$ , denoted $R n$ or $,$ is the set of the $n$ -tuples of real numbers, that is the set of all sequences of $n$ real numbers. Special cases are called the real line $R 1$ and the real coordinate plane $R 2$ . With component-wise addition and scalar multiplication, it is a real vector space, and its elements are called coordinate vectors.

In functional analysis and related areas of mathematics an absorbing set in a vector space is a set $which can be "inflated" or "scaled up" to eventually always include any given point of the vector space. Alternative terms are radial or absorbent set . Every neighborhood of the origin in every topological vector space is an absorbing subset.$

In linear algebra and related areas of mathematics a balanced set, circled set or disk in a vector space is a set $such that for all scalars satisfying$

<span class="mw-page-title-main">Multiple integral</span> Generalization of definite integrals to functions of multiple variables

In mathematics (specifically multivariable calculus), a multiple integral is a definite integral of a function of several real variables, for instance, $f (x, y)$ or $f (x, y, z)$ . Integrals of a function of two variables over a region in $(the real-number plane) are called double integrals, and integrals of a function of three variables over a region in (real-number 3D space) are called triple integrals . For multiple integrals of a single-variable function, see the Cauchy formula for repeated integration.$

In geometry, a three-dimensional space is a mathematical space in which three values (coordinates) are required to determine the position of a point. Most commonly, it is the three-dimensional Euclidean space, the Euclidean n-space of dimension n=3 that models physical space. More general three-dimensional spaces are called 3-manifolds. The term may also refer colloquially to a subset of space, a three-dimensional region, a solid figure.

In mathematics, the Peano–Jordan measure is an extension of the notion of size to shapes more complicated than, for example, a triangle, disk, or parallelepiped.

A regular grid is a tessellation of n-dimensional Euclidean space by congruent parallelotopes. Its opposite is irregular grid.

<span class="mw-page-title-main">Euclidean plane</span> Geometric model of the planar projection of the physical universe

In mathematics, a Euclidean plane is a Euclidean space of dimension two, denoted $E 2$ . It is a geometric space in which two real numbers are required to determine the position of each point. It is an affine space, which includes in particular the concept of parallel lines. It has also metrical properties induced by a distance, which allows to define circles, and angle measurement.

<span class="mw-page-title-main">Lebesgue integration</span> Method of integration

In mathematics, the integral of a non-negative function of a single variable can be regarded, in the simplest case, as the area between the graph of that function and the $X$ axis. The Lebesgue integral, named after French mathematician Henri Lebesgue, extends the integral to a larger class of functions. It also extends the domains on which these functions can be defined.

References

Foran, James (1991-01-07). Fundamentals of Real Analysis. CRC Press. ISBN 9780824784539 . Retrieved 23 May 2014.
Rudin, Walter (1976). Principles of Mathematical Analysis . McGraw-Hill.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Foran (1991)

[2] Rudin (1976 :39)

[3] Foran (1991 :24)

[4] Rudin (1976 :31)

[1]

[2]

[3]

[4]