Function of several real variables

In mathematical analysis and its applications, a function of several real variables or real multivariate function is a function with more than one argument, with all arguments being real variables. This concept extends the idea of a function of a real variable to several variables. The "input" variables take real values, while the "output", also called the "value of the function", may be real or complex. However, the study of the complex-valued functions may be easily reduced to the study of the real-valued functions, by considering the real and imaginary parts of the complex function; therefore, unless explicitly specified, only real-valued functions will be considered in this article.
The domain of a function of variables is the subset of for which the function is defined. As usual, the domain of a function of several real variables is supposed to contain a nonempty open subset of.

General definition

A real-valued function of real variables is a function that takes as input real numbers, commonly represented by the variables, for producing another real number, the value of the function, commonly denoted. For simplicity, in this article a real-valued function of several real variables will be simply called a function. To avoid any ambiguity, the other types of functions that may occur will be explicitly specified.
Some functions are defined for all real values of the variables, but some other functions are defined only if the value of the variable are taken in a subset of, the domain of the function, which is always supposed to contain an open subset of. In other words, a real-valued function of real variables is a function
such that its domain is a subset of that contains a nonempty open set.
An element of being an -tuple , the general notation for denoting functions would be. The common usage, much older than the general definition of functions between sets, is to not use double parentheses and to simply write.
It is also common to abbreviate the -tuple by using a notation similar to that for vectors, like boldface, underline, or overarrow. This article will use bold.
A simple example of a function in two variables could be:
which is the volume of a cone with base area and height measured perpendicularly from the base. The domain restricts all variables to be positive since lengths and areas must be positive.
For an example of a function in two variables:
where and are real non-zero constants. Using the three-dimensional Cartesian coordinate system, where the xy plane is the domain and the z axis is the codomain, one can visualize the image to be a two-dimensional plane, with a slope of in the positive x direction and a slope of in the positive y direction. The function is well-defined at all points in. The previous example can be extended easily to higher dimensions:
for non-zero real constants, which describes a -dimensional hyperplane.
The Euclidean norm:
is also a function of n variables which is everywhere defined, while
is defined only for.
For a non-linear example function in two variables:
which takes in all points in, a disk of radius "punctured" at the origin in the plane, and returns a point in. The function does not include the origin, if it did then would be ill-defined at that point. Using a 3d Cartesian coordinate system with the xy-plane as the domain, and the z axis the codomain, the image can be visualized as a curved surface.
The function can be evaluated at the point in :
However, the function couldn't be evaluated at, say
since these values of and do not satisfy the domain's rule.

Image

The image of a function is the set of all values of when the -tuple runs in the whole domain of. For a continuous real-valued function which has a connected domain, the image is either an interval or a single value. In the latter case, the function is a constant function.
The preimage of a given real number is called a level set. It is the set of the solutions of the equation.

Domain

The domain of a function of several real variables is a subset of that is sometimes, but not always, explicitly defined. In fact, if one restricts the domain of a function to a subset, one gets formally a different function, the restriction of to, which is denoted. In practice, it is often not harmful to identify and, and to omit the restrictor.
Conversely, it is sometimes possible to enlarge naturally the domain of a given function, for example by continuity or by analytic continuation.
Moreover, many functions are defined in such a way that it is difficult to specify explicitly their domain. For example, given a function, it may be difficult to specify the domain of the function If is a multivariate polynomial,, it is even difficult to test whether the domain of is also. This is equivalent to test whether a polynomial is always positive, and is the object of an active research area.

Algebraic structure

The usual operations of arithmetic on the reals may be extended to real-valued functions of several real variables in the following way:

For every real number, the constant function is everywhere defined.
For every real number and every function, the function: has the same domain as .
If and are two functions of respective domains and such that contains a nonempty open subset of, then and are functions that have a domain containing.

It follows that the functions of variables that are everywhere defined and the functions of variables that are defined in some neighbourhood of a given point both form commutative algebras over the reals. This is a prototypical example of a function space.
One may similarly define
which is a function only if the set of the points in the domain of such that contains an open subset of. This constraint implies that the above two algebras are not fields.

Univariable functions associated with a multivariable function

A function in one real variable can easily be obtained by giving a constant value to all but one of the variables. For example, if is a point of the interior of the domain of the function, the values of can be fixed to respectively, to get a univariable function
whose domain contains an interval centered at. This function may also be viewed as the restriction of the function to the line defined by the equations for.
Other univariable functions may be defined by restricting to any line passing through. These are the functions
where the are real numbers that are not all zero.
In next section, we will show that, if the multivariable function is continuous, so are all these univariable functions, but the converse is not necessarily true.

Continuity and limit

Until the second part of 19th century, only continuous functions were considered by mathematicians. At that time, the notion of continuity was elaborated for the functions of one or several real variables a rather long time before the formal definition of a topological space and a continuous map between topological spaces. As continuous functions of several real variables are ubiquitous in mathematics, it is worth to define this notion without reference to the general notion of continuous maps between topological space.
For defining the continuity, it is useful to consider the distance function of, which is an everywhere defined function of real variables:
A function is continuous at a point which is interior to its domain, if, for every positive real number, there is a positive real number such that for all such that. In other words, may be chosen small enough for having the image by of the ball of radius centered at contained in the interval of length centered at. A function is continuous if it is continuous at every point of its domain.
If a function is continuous at, then all the univariate functions that are obtained by fixing all the variables except one at the value, are continuous at. The converse is false; this means that all these univariate functions may be continuous for a function that is not continuous at. For an example, consider the function such that, and is otherwise defined by
The functions and are both constant and equal to zero, and are therefore continuous. The function is not continuous at, because, if and, we have, even if is very small. Although not continuous, this function has the further property that all the univariate functions obtained by restricting it to a line passing through are also continuous. In fact, we have
for.
The limit at a point of a real-valued function of several real variables is defined as follows. Let be a point in topological closure of the domain of the function. The function, has a limit when tends toward, denoted
if the following condition is satisfied:
For every positive real number, there is a positive real number such that
for all in the domain such that
If the limit exists, it is unique. If is in the interior of the domain, the limit exists if and only if the function is continuous at. In this case, we have
When is in the boundary of the domain of, and if has a limit at, the latter formula allows to "extend by continuity" the domain of to.

Symmetry

A symmetric function is a function that is unchanged when two variables and are interchanged:
where and are each one of. For example:
is symmetric in since interchanging any pair of leaves unchanged, but is not symmetric in all of, since interchanging with or or gives a different function.

Function composition

Suppose the functions
or more compactly, are all defined on a domain. As the -tuple varies in, a subset of, the -tuple varies in another region a subset of. To restate this:
Then, a function of the functions defined on,
is a function composition defined on, in other terms the mapping
Note the numbers and do not need to be equal.
For example, the function
defined everywhere on can be rewritten by introducing
which is also everywhere defined in to obtain
Function composition can be used to simplify functions, which is useful for carrying out multiple integrals and solving partial differential equations.