Power series
In mathematics, a power series (in one variable) is an infinite series of the form
| Table of contents |
|
2 Differentiating and integrating power series 3 Analytic functions 4 Formal power series 5 Power series in several variables |
A power series will converge for some values of the variable x (at least for x = a) and may diverge for others. It turns out that there is always a number r with 0 ≤ r ≤ ∞ such that the series converges whenever |x − a| < r and diverges whenever |x − a| > r. (For |x - a| = r we cannot make any general statement.) The number r is called the radius of convergence of the power series; in general it is given as
Radius of convergence
(see lim inf) but a fast way to compute it is
The series converges absolutely for |x - a| < r and converges uniformly on every compact subset of {x : |x − a| < r}.
Once a function is given as a power series, it is continuous wherever it converges and is differentiable on the interior of this set. It can be differentiated and integrated quite easily, by treating every term separately:
A function f defined on some open subset U of R or C is called analytic if it is locally given by power series. This means that every a ∈ U has an open neighborhood V ⊆ U, such that there exists a power series with center a which converges to f(x) for every x ∈ V.
Every power series with a positive radius of convergence is analytic on the interior of its region of convergence. All holomorphic functions are complex-analytic. Sums and products of analytic functions are analytic, as are quotients as long as the denominator is non-zero.
If a function is analytic, then it is infinitely often differentiable, but in the real case the converse is not generally true. For an analytic function, the coefficients an can be computed as
The global form of an analytic function is completely determined by its local behavior in the following sense: if f and g are two analytic functions defined on the same connected open set U, and if there exists an element a∈U such that f (n)(a) = g (n)(a) for all n ≥ 0, then f(x) = g(x) for all x ∈ U.
If a power series with radius of convergence r is given, one can consider analytic continuations of the series, i.e. analytic functions f which are defined on larger sets than { x : |x - a| < r } and agree with the given power series on this set. The number r is maximal in the following sense: there always exists a complex number x with |x - a| = r such that no analytic continuation of the series can be defined at x.
The power series expansion of the inverse function of an analytic function can be determined using the Lagrange inversion theorem.
In abstract algebra, one attempts to capture the essence of power series without being restricted to the fieldss of real and complex numbers, and without the need to talk about convergence. This leads to the concept of formal power series, a concept of great utility in combinatorics.
An extension of the theory is necessary for the purposes of multivariate calculus. A power series is here defined to be an infinite series of the form
Differentiating and integrating power series
Both of these series have the same radius of convergence as the original one.Analytic functions
where f (n)(a) denotes the n-th derivative of f at a. This means that every analytic function is locally represented by its Taylor series.Formal power series
Power series in several variables
where j = (j1,...,jn) is a vector of natural numbers, the coefficients
a(j1,...,jn) are usually real or complex numbers, and the center c = (c1,...,cn) and argument x = (x1,...,xn) are usually real or complex vectors. In the more convenient multi-index notation this can be written