In mathematics, an almost periodic function is, loosely speaking, a function of a real number that is periodic to within any desired level of accuracy, given suitably long, well-distributed "almost-periods". The concept was first studied by Harald Bohr and later generalized by Vyacheslav Stepanov, Hermann Weyl and Abram Samoilovitch Besicovitch, amongst others. There is also a notion of almost periodic functions on locally compact abelian groups, first studied by John von Neumann.
Almost periodicity is a property of dynamical systems that appear to retrace their paths through phase space, but not exactly. An example would be a planetary system, with planets in orbits moving with periods that are not commensurable (i.e., with a period vector that is not proportional to a vector of integers). A theorem of Kronecker from diophantine approximation can be used to show that any particular configuration that occurs once, will recur to within any specified accuracy: if we wait long enough we can observe the planets all return to within a second of arc to the positions they once were in.
There are several inequivalent definitions of almost periodic functions. The first was given by Harald Bohr. His interest was initially in finite Dirichlet series. In fact by truncating the series for the Riemann zeta function ζ(s) to make it finite, one gets finite sums of terms of the type
eslog
with s written as (σ + it) - the sum of its real part σ and imaginary part it. Fixing σ, so restricting attention to a single vertical line in the complex plane, we can see this also as
n\sigmae(log.
Taking a finite sum of such terms avoids difficulties of analytic continuation to the region σ < 1. Here the 'frequencies' log n will not all be commensurable (they are as linearly independent over the rational numbers as the integers n are multiplicatively independent - which comes down to their prime factorizations).
With this initial motivation to consider types of trigonometric polynomial with independent frequencies, mathematical analysis was applied to discuss the closure of this set of basic functions, in various norms.
The theory was developed using other norms by Besicovitch, Stepanov, Weyl, von Neumann, Turing, Bochner and others in the 1920s and 1930s.
\|f\|infty=\supx|f(x)|
\left|f(t+T)-f(t)\right|<\varepsilon.
An alternative definition due to Bochner (1926) is equivalent to that of Bohr and is relatively simple to state:
A function f is almost periodic if every sequence of translations of f has a subsequence that converges uniformly for t in (-∞, +∞).
The Bohr almost periodic functions are essentially the same as continuous functions on the Bohr compactification of the reals.
The space Sp of Stepanov almost periodic functions (for p ≥ 1) was introduced by V.V. Stepanov (1925).[2] It contains the space of Bohr almost periodic functions. It is the closure of the trigonometric polynomials under the norm
\|f\|S,r,p=\supx\left({1\over
| x+r | |
| r}\int | |
| x |
|f(s)|pds\right)1/p
for any fixed positive value of r; for different values of r these norms give the same topology and so the same space of almost periodic functions (though the norm on this space depends on the choice of r).
The space Wp of Weyl almost periodic functions (for p ≥ 1) was introduced by Weyl (1927).[3] It contains the space Sp of Stepanov almost periodic functions. It is the closure of the trigonometric polynomials under the seminorm
\|f\|W,p=\limr\toinfty\|f\|S,r,p
Warning: there are nonzero functions ƒ with ||ƒ||W,p = 0, such as any bounded function of compact support, so to get a Banach space one has to quotient out by these functions.
The space Bp of Besicovitch almost periodic functions was introduced by Besicovitch (1926).[4] It is the closure of the trigonometric polynomials under the seminorm
\|f\|B,p=\limsupx\left({1\over2x}
| x | |
| \int | |
| -x |
|f(s)|pds\right)1/p
Warning: there are nonzero functions ƒ with ||ƒ||B,p = 0, such as any bounded function of compact support, so to get a Banach space one has to quotient out by these functions.
The Besicovitch almost periodic functions in B2 have an expansion (not necessarily convergent) as
\sum
| iλnt | |
| a | |
| ne |
with Σa finite and λn real. Conversely every such series is the expansion of some Besicovitch periodic function (which is not unique).
The space Bp of Besicovitch almost periodic functions (for p ≥ 1) contains the space Wp of Weyl almost periodic functions. If one quotients out a subspace of "null" functions, it can be identified with the space of Lp functions on the Bohr compactification of the reals.
With these theoretical developments and the advent of abstract methods (the Peter - Weyl theorem, Pontryagin duality and Banach algebras) a general theory became possible. The general idea of almost-periodicity in relation to a locally compact abelian group G becomes that of a function F in L∞(G), such that its translates by G form a relatively compact set.Equivalently, the space of almost periodic functions is the norm closure of the finite linear combinations of characters of G. If G is compact the almost periodic functions are the same as the continuous functions.
The Bohr compactification of G is the compact abelian group of all possibly discontinuous characters of the dual group of G, and is a compact group containing G as a dense subgroup. The space of uniform almost periodic functions on G can be identified with the space of all continuous functions on the Bohr compactification of G. More generally the Bohr compactification can be defined for any topological group G, and the spaces of continuous or Lp functions on the Bohr compactification can be considered as almost periodic functions on G.For locally compact connected groups G the map from G to its Bohr compactification is injective if and only if G is a central extension of a compact group, or equivalently the product of a compact group and a finite-dimensional vector space.
A function on a locally compact group is called weakly almost periodic if its orbit is weakly relatively compact in
Linfty
Given a topological dynamical system
(X,G)
C(X)
In speech processing, audio signal processing, and music synthesis, a quasiperiodic signal, sometimes called a quasiharmonic signal, is a waveform that is virtually periodic microscopically, but not necessarily periodic macroscopically. This does not give a quasiperiodic function, but something more akin to an almost periodic function, being a nearly periodic function where any one period is virtually identical to its adjacent periods but not necessarily similar to periods much farther away in time. This is the case for musical tones (after the initial attack transient) where all partials or overtones are harmonic (that is all overtones are at frequencies that are an integer multiple of a fundamental frequency of the tone).
When a signal
x(t)
P
x(t)=x(t+P) \forallt\inR
or
|x(t)-x(t+P)|=0 \forallt\inR.
The Fourier series representation would be
x(t)=a0+
| infty | |
| \sum | |
| n=1 |
[an\cos(2\pinf0t)-bn\sin(2\pinf0t)]
or
x(t)=a0+
| infty | |
| \sum | |
| n=1 |
rn\cos(2\pinf0t+\varphin)
where
f0=
| 1 | |
| P |
a0=
| 1 | |
| P |
| t0+P | |
| \int | |
| t0 |
x(t)dt
an=rn\cos\left(\varphin\right)=
| 2 | |
| P |
| t0+P | |
| \int | |
| t0 |
x(t)\cos(2\pinf0t)dt n\ge1
bn=rn\sin\left(\varphin\right)=-
| 2 | |
| P |
| t0+P | |
| \int | |
| t0 |
x(t)\sin(2\pinf0t)dt
where
t0
-infty<t0<+infty
f0
an
bn
rn
\varphin
When
x(t)
x(t) ≈ x(t+P(t))
or
|x(t)-x(t+P(t))|<\varepsilon
where
0<\epsilon\ll \Vertx \Vert=\sqrt{\overline{x2}}=\sqrt{\lim\tau
| 1 | |
| \tau |
| \tau/2 | |
| \int | |
| -\tau/2 |
x2(t)dt}.
Now the Fourier series representation would be
x(t)=a0(t) +
| infty | |
| \sum | |
| n=1 |
\left[an(t)\cos\left(2\pin
| t | |
| \int | |
| 0 |
f0(\tau)d\tau\right)-bn(t)\sin\left(2\pin
| t | |
| \int | |
| 0 |
f0(\tau)d\tau\right)\right]
or
x(t)=a0(t) +
| infty | |
| \sum | |
| n=1 |
rn(t)\cos\left(2\pin
| t | |
| \int | |
| 0 |
f0(\tau)d\tau+\varphin(t)\right)
or
x(t)=a0(t)+
| infty | |
| \sum | |
| n=1 |
rn(t)\cos\left(2\pi
| t | |
| \int | |
| 0 |
fn(\tau)d\tau+\varphin(0)\right)
where
f0(t)=
| 1 | |
| P(t) |
a0(t)=
| 1 | |
| P(t) |
| t+P(t)/2 | |
| \int | |
| t-P(t)/2 |
x(\tau)d\tau
an(t)=rn(t)\cos(\varphin(t))=
| 2 | |
| P(t) |
| t+P(t)/2 | |
| \int | |
| t-P(t)/2 |
x(\tau)\cos(2\pinf0(t)\tau)d\tau n\ge1
bn(t)=rn(t)\sin(\varphin(t))=-
| 2 | |
| P(t) |
| t+P(t)/2 | |
| \int | |
| t-P(t)/2 |
x(\tau)\sin(2\pinf0(t)\tau)d\tau
and the instantaneous frequency for each partial is
fn(t)=nf0(t)+
| 1 | |
| 2\pi |
| \prime(t). | |
| \varphi | |
| n |
Whereas in this quasiperiodic case, the fundamental frequency
f0(t)
fn(t)
an(t)
bn(t)
rn(t)
\varphin(t)
x(t)
The partial frequencies
fn(t)
\varphin(t)
| \prime(t) | |
| \varphi | |
| n |
nf0(t)
\varphin(t)
x(t)