Analysis Definition for a Funciton is Continuous
A basic concept in mathematical analysis.
Let 
be a real-valued function defined on a subset 
of the real numbers 
, that is, 
. Then 
is said to be continuous at a point 
(or, in more detail, continuous at 
with respect to 
) if for any 
there exists a 
such that for all 
with 
the inequality
is valid. If one denotes by
and
the 
- and 
-neighbourhoods of 
and 
, respectively, then the definition above can be rephrased as follows: 
is called continuous at a point 
if for each 
-neighbourhood 
of 
there is a 
-neighbourhood 
of 
such that 
.
By using the concept of a limit one can say that 
is continuous at a point 
if its limit with respect to the set 
exists at that point and if this limit is equal to 
:
This is equivalent to
where 
, 
, and 
; that is, to an infinitely small increment of the argument at 
corresponds an infinitely small increment of the function.
In terms of the limit of a sequence, the definition of continuity of a function at 
is: 
is continuous at 
if for every sequence of points 
, 
for which 
, one has
All these definitions of a function being continuous at a point are equivalent.
If 
is continuous at 
with respect to the set 
(or 
), then 
is said to be continuous on the right (or left) at 
.
All basic elementary functions are continuous at all points of their domains of definition. An important property of continuous functions is that their class is closed under the arithmetic operations and under composition of functions. More accurately, if two real-valued functions 
and 
, 
, are continuous at 
, then so is their sum 
, difference 
and product 
, and when 
, also their quotient 
(which is necessarily defined in the intersection of 
with a certain neighbourhood of 
). If, as before, 
is continuous at 
and 
, 
, is such that 
, so that the composite 
makes sense, if there is a 
such that 
and if 
is continuous at 
, then 
is also continuous at 
. Thus, in this case
that is, in this sense the operation of limit transition commutes with the operation of applying a continuous function. From these properties of continuous functions it follows that not only the basic, but also arbitrary elementary functions are continuous in their domains of definition. The property of continuity is also preserved under a uniform limit transition: If a sequence of functions 
converges uniformly on a set 
and if every 
is continuous at 
, 
then
is continuous at 
.
If a function 
is continuous at every point of 
, then 
is said to be continuous on the set 
. If 
and 
is continuous at 
, then the restriction of 
to 
is also continuous at 
. The converse is not true, in general. For example, the restriction of the Dirichlet function either to the set of rational numbers or to the set of irrational numbers is continuous, but the Dirichlet function itself is discontinuous at all points.
An important class of real-valued continuous functions of a single variable consists of those functions that are continuous on intervals. They have the following properties.
Weierstrass' first theorem: A function that is continuous on a closed interval is bounded on that interval.
Weierstrass' second theorem: A function that is continuous on a closed interval assumes on that interval a largest and a smallest value.
Cauchy's intermediate value theorem: A function that is continuous on a closed interval assumes on it any value between those at the end points.
The inverse function theorem: If a function is continuous and strictly monotone on an interval, then it has a single-valued inverse function, which is also defined on an interval and is strictly monotone and continuous on it.
Cantor's theorem on uniform continuity: A function that is continuous on a closed interval is uniformly continuous on it.
Every function that is continuous on a closed interval can be uniformly approximated on it with arbitrary accuracy by an algebraic polynomial, and every function 
that is continuous on 
and is such that 
can be uniformly approximated on 
with arbitrary accuracy by trigonometric polynomials (see Weierstrass theorem on the approximation of functions).
The concept of a continuous function can be generalized to wider forms of functions, above all, to functions of several variables. The definition above is preserved formally if one understands by 
a subset of an 
-dimensional Euclidean space 
, by 
the distance between two points 
and 
, by 
the 
-neighbourhood of 
in 
, and by
the limit of a sequence of points in 
. A function 
, 
, of several variables 
that is continuous at a point 
is also called continuous at this point 
jointly in the variables 
, in contrast to functions of several variables that are continuous in the variables individually. A function 
, 
, is called continuous at a point 
in, say, the variable 
if the restriction of 
to the set
is continuous at 
, that is, if the function 
of the single variable 
is continuous at 
. A function 
, 
, 
, can be continuous at 
in every variable 
, but need not be continuous at this point jointly in the variables.
The definition of a continuous function goes over directly to complex-valued functions. Only one has to interpret 
in the definition above as the norm of the complex number 
and
as the limit in the complex plane.
All these definitions are special cases of the more general concept of a continuous function 
with as domain of definition a certain topological space 
and with values in a certain topological space 
(see Continuous mapping).
Many properties of real-valued continuous functions of a single variable carry over to continuous mappings between topological spaces. A generalization of Weierstrass' theorem mentioned above: The continuous image of a compact topological space in a Hausdorff space is compact. A generalization of Cauchy's intermediate value theorem for a continuous function on a closed interval: A continuous image of a connected topological space in a topological space is also connected. A generalization of the theorem on the inverse function of a strictly monotone continuous function: A continuous one-to-one mapping of a compactum onto a Hausdorff space is a homeomorphism. A generalization of the theorem on the limit of a uniformly-convergent sequence of continuous functions: If 
is a uniformly-convergent sequence of mappings of a topological space 
into a metric space 
that are continuous (at a point 
) then the limit mapping 
is also continuous (at 
). A generalization of Weierstrass' theorem on the approximation of functions that are continuous on a closed interval is the Stone–Weierstrass theorem.
References
| [1] | P.S. Aleksandrov, "Einführung in die Mengenlehre und die allgemeine Topologie" , Deutsch. Verlag Wissenschaft. (1984) (Translated from Russian) |
| [2] | A.N. Kolmogorov, S.V. Fomin, "Elements of the theory of functions and functional analysis" , 1–2 , Graylock (1957–1961) (Translated from Russian) |
| [3] | S.M. Nikol'skii, "A course of mathematical analysis" , 1–2 , MIR (1977) (Translated from Russian) |
| [4] | V.A. Il'in, E.G. Poznyak, "Fundamentals of mathematical analysis" , 1–2 , MIR (1982) (Translated from Russian) |
The topics discussed above can be found in almost any introductory book on real analysis. Proofs of all statements can be found in, e.g., [a5], Chapt. 3.
References
| [a1] | T.M. Apostol, "Mathematical analysis" , Addison-Wesley (1957) |
| [a2] | R.G. Bartle, "The elements of real analysis" , Wiley (1976) |
| [a3] | G.H. Hardy, "A course of pure mathematics" , Cambridge Univ. Press (1975) |
| [a4] | W. Rudin, "Principles of mathematical analysis" , McGraw-Hill (1976) pp. 75–78 |
| [a5] | K.R. Stromberg, "Introduction to classical real analysis" , Wadsworth (1981) |
| [a6] | R.P Boas jr., "A primer of real functions" , Math. Assoc. Amer. (1960) |
How to Cite This Entry:
Continuous function. L.D. Kudryavtsev (originator), Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Continuous_function&oldid=15327
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