Difference between revisions of "Derivative"
(Importing text file)
m (MR/ZBL numbers added)
|Line 33:||Line 33:|
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> G. Choquet, "Outils topologiques et métriques de l'analyse mathématique" , Centre Docum. Univ. Paris (1969) (Rédigé par C. Mayer)</TD></TR></table>
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> G. Choquet, "Outils topologiques et métriques de l'analyse mathématique" , Centre Docum. Univ. Paris (1969) (Rédigé par C. Mayer) </TD></TR></table>
Revision as of 11:58, 27 September 2012
One of the basic concepts in mathematical analysis. Suppose that a real-valued function of a real variable is defined in a neighbourhood of a point and that there exists a finite or infinite limit
This limit is called the derivative of the function at the point . If one sets ,
then the limit (*) can be written as:
Also the notations , , , , and some others are used to denote this limit.
The operation of computing the derivative is called differentiation. If the derivative is finite, is said to be differentiable at the point . A function differentiable at every point of a set is said to be differentiable on that set. A differentiable function is always continuous. However, there are continuous functions that have no derivative at any point of a given interval (see Non-differentiable function).
Let a function be differentiable in an interval. Its derivative may turn out to be a discontinuous function. However, according to Baire's classification (see Baire classes) it is always a function of the first class and has the Darboux property: If it takes two values, it takes every intermediate value as well.
A generalization of the concept of the derivative is the concept of a derivative over a set. Suppose that a real-valued function is defined on a set of real numbers, that is a limit point of , that , and that there exists a finite or infinite limit
This limit is called the derivative of over the set at the point and is denoted by the symbol . The derivative of a function over a set is a generalization of the concept of a derivative. Variations of the generalization are the concept of a one-sided derivative, a Dini derivative, and an approximate derivative.
The above definition of the derivative (and its generalizations), as well as simple properties of it, extend almost without change to complex-valued and vector-valued functions of a real or complex variable. Moreover, there exists a concept of a derivative of a scalar-valued point function in a Euclidean space (see Gradient), and of a derivative of a set function with respect to a measure (in particular, with respect to area, volume, etc.). The concept of a derivative is extended to vector-valued point functions in an abstract space (see Differentiation of a mapping).
For a geometric and mechanical interpretation of the derivative, the simplest rules of differentiation, higher derivatives, partial derivatives, and also for references see Differential calculus.
G. Choquet has proved that a function on is of the first Baire class and has the Darboux property (if and) only if there exists a differentiable function on and a homeomorphism of such that . See [a1] for details and references.
|[a1]||G. Choquet, "Outils topologiques et métriques de l'analyse mathématique" , Centre Docum. Univ. Paris (1969) (Rédigé par C. Mayer) MR0262426|
Derivative. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Derivative&oldid=13836