There are two ways to introduce wavelets: one is through the continuous wavelet transform, and the other is through multiresolution analysis (MRA), which is the presentation adopted here. Here we start by defining multiresolution analysis and thereafter we give one example of such MRA.
Definition
( Multiresolution analysis)
A multiresolution analysis of
${L}_{2}\left(\mathrm{I}\phantom{\rule{-0.166667em}{0ex}}\mathrm{R}\right)$ is defined as a sequence of closed subspaces
${V}_{j}\subset {L}_{2}\left(\mathrm{I}\phantom{\rule{-0.166667em}{0ex}}\mathrm{R}\right),j\in \mathrm{Z}\phantom{\rule{-0.166667em}{0ex}}\phantom{\rule{-0.166667em}{0ex}}\mathrm{Z}$ with the following properties:
If
$f\left(x\right)\in {V}_{0},f\left({2}^{j}x\right)\in {V}_{j}.$ This property means that all the spaces
${V}_{j}$ are scaled versions of the central space
${V}_{0}.$
If
$f\in {V}_{0},f(.-k)\in {V}_{0},k\in \mathrm{Z}\phantom{\rule{-0.166667em}{0ex}}\phantom{\rule{-0.166667em}{0ex}}\mathrm{Z}.$ That is,
${V}_{0}$ (and hence all the
${V}_{j}$ ) is invariant under translation.
There exists
$\varphi \in {V}_{0}$ such that
$\{{\varphi}_{0,n};n\in \mathrm{Z}\phantom{\rule{-0.166667em}{0ex}}\phantom{\rule{-0.166667em}{0ex}}\mathrm{Z}\}$ is an orthonormal basis in
${V}_{0}.$
Condition 5 in
[link] seems to be quite contrived, but it can be relaxed (i.e.,instead of taking orthonormal basis, we can take Riesz basis). We will use the following terminology: a
level of a multiresolution analysis is one of the
${V}_{j}$ subspaces and one level is
coarser (respectively
finer ) with respect to another whenever the index of the corresponding subspace is smaller (respectively bigger).
Consequence of the definition
Let us make a couple of simple observations concerning this definition. Combining the facts that
$\varphi \left(x\right)\in {V}_{0}$
$\left\{\varphi \right(.-k),k\in \mathrm{Z}\phantom{\rule{-0.166667em}{0ex}}\phantom{\rule{-0.166667em}{0ex}}\mathrm{Z}\}$ is an orthonormal basis for
${V}_{0}$
$\varphi \left({2}^{j}x\right)\in {V}_{j}$ ,
we obtain that, for fixed
$j$ ,
$\{{\varphi}_{j,k}\left(x\right)={2}^{j/2}\varphi ({2}^{j}x-k),k\in \mathrm{Z}\phantom{\rule{-0.166667em}{0ex}}\phantom{\rule{-0.166667em}{0ex}}\mathrm{Z}\}$ is an orthonormal basis for
${V}_{j}$ .
Since
$\varphi \in {V}_{0}\subset {V}_{1},$ we can express
$\varphi $ as a linear combination of
$\left\{{\varphi}_{1,k}\right\}:$
[link] is called the
refinement equation , or the
two scales difference equation. The function
$\varphi \left(x\right)$ is called the
scaling function .
Under very general condition,
$\varphi $ is uniquely defined by its refinement equation and the normalisation
The spaces
${V}_{j}$ will be used to approximate general functions (see an example below). This will be done by defining appropriate projections onto these spaces. Since the union of all the
${V}_{j}$ is dense in
${L}_{2}\left(\mathrm{I}\phantom{\rule{-0.166667em}{0ex}}\mathrm{R}\right),$ we are guaranteed that any given function of
${L}_{2}$ can be approximated arbitrarily close by such projections, i.e.:
Rather than considering all our nested spaces
${V}_{j},$ we would like to code only the information needed to go from
${V}_{j}$ to
${V}_{j+1}.$ Hence we define by
${W}_{j}$ the space complementing
${V}_{j}$ in
${V}_{j+1}$ :
$${V}_{j+1}={V}_{j}\oplus {W}_{j}$$
This space
${W}_{j}$ answers our question: it contains the “detail” information needed to go from an approximation at resolution
$j$ to an approximation at resolution
$j+1.$ Consequently, by using recursively the
[link] , we have:
Do u think that Graphene and Fullrene fiber can be used to make Air Plane body structure the lightest and strongest.
Rafiq
Rafiq
what is differents between GO and RGO?
Mahi
what is simplest way to understand the applications of nano robots used to detect the cancer affected cell of human body.?
How this robot is carried to required site of body cell.?
what will be the carrier material and how can be detected that correct delivery of drug is done
Rafiq
The nanotechnology is as new science, to scale nanometric
brayan
nanotechnology is the study, desing, synthesis, manipulation and application of materials and functional systems through control of matter at nanoscale
Damian
Is there any normative that regulates the use of silver nanoparticles?
fullerene is a bucky ball aka Carbon 60 molecule. It was name by the architect Fuller. He design the geodesic dome. it resembles a soccer ball.
Tarell
what is the actual application of fullerenes nowadays?
Damian
That is a great question Damian. best way to answer that question is to Google it. there are hundreds of applications for buck minister fullerenes, from medical to aerospace. you can also find plenty of research papers that will give you great detail on the potential applications of fullerenes.
Tarell
how did you get the value of 2000N.What calculations are needed to arrive at it
Source:
OpenStax, Multiresolution analysis, filterbank implementation, and function approximation using wavelets. OpenStax CNX. Sep 14, 2009 Download for free at http://cnx.org/content/col10568/1.2
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